package apiv1 import ( "context" "errors" "fmt" "math/big" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/hexutil" "github.com/ethereum/go-ethereum/common/math" "github.com/ethereum/go-ethereum/rpc" "github.com/harmony-one/bls/ffi/go/bls" "github.com/harmony-one/harmony/common/denominations" "github.com/harmony-one/harmony/consensus/quorum" "github.com/harmony-one/harmony/core" "github.com/harmony-one/harmony/core/types" "github.com/harmony-one/harmony/core/vm" internal_bls "github.com/harmony-one/harmony/crypto/bls" internal_common "github.com/harmony-one/harmony/internal/common" "github.com/harmony-one/harmony/internal/params" "github.com/harmony-one/harmony/internal/utils" "github.com/harmony-one/harmony/shard" "github.com/harmony-one/harmony/staking/network" staking "github.com/harmony-one/harmony/staking/types" ) const ( defaultGasPrice = denominations.Nano defaultFromAddress = "0x0000000000000000000000000000000000000000" defaultBlocksPeriod = 15000 validatorsPageSize = 100 ) // PublicBlockChainAPI provides an API to access the Harmony blockchain. // It offers only methods that operate on public data that is freely available to anyone. type PublicBlockChainAPI struct { b Backend } // NewPublicBlockChainAPI creates a new Harmony blockchain API. func NewPublicBlockChainAPI(b Backend) *PublicBlockChainAPI { return &PublicBlockChainAPI{b} } // BlockArgs is struct to include optional block formatting params. type BlockArgs struct { WithSigners bool `json:"withSigners"` InclTx bool `json:"inclTx"` FullTx bool `json:"fullTx"` Signers []string `json:"signers"` InclStaking bool `json:"inclStaking"` } // GetBlockByNumber returns the requested block. When blockNr is -1 the chain head is returned. When fullTx is true all // transactions in the block are returned in full detail, otherwise only the transaction hash is returned. func (s *PublicBlockChainAPI) GetBlockByNumber(ctx context.Context, blockNr rpc.BlockNumber, fullTx bool) (map[string]interface{}, error) { block, err := s.b.BlockByNumber(ctx, blockNr) if block != nil { blockArgs := BlockArgs{WithSigners: false, InclTx: true, FullTx: fullTx, InclStaking: true} response, err := RPCMarshalBlock(block, blockArgs) if err == nil && blockNr == rpc.PendingBlockNumber { // Pending blocks need to nil out a few fields for _, field := range []string{"hash", "nonce", "miner"} { response[field] = nil } } return response, err } return nil, err } // GetBlockByHash returns the requested block. When fullTx is true all transactions in the block are returned in full // detail, otherwise only the transaction hash is returned. func (s *PublicBlockChainAPI) GetBlockByHash(ctx context.Context, blockHash common.Hash, fullTx bool) (map[string]interface{}, error) { block, err := s.b.GetBlock(ctx, blockHash) if block != nil { blockArgs := BlockArgs{WithSigners: false, InclTx: true, FullTx: fullTx, InclStaking: true} return RPCMarshalBlock(block, blockArgs) } return nil, err } // GetBlockByNumberNew returns the requested block. When blockNr is -1 the chain head is returned. When fullTx in blockArgs is true all // transactions in the block are returned in full detail, otherwise only the transaction hash is returned. When withSigners in BlocksArgs is true // it shows block signers for this block in list of one addresses. func (s *PublicBlockChainAPI) GetBlockByNumberNew(ctx context.Context, blockNr rpc.BlockNumber, blockArgs BlockArgs) (map[string]interface{}, error) { block, err := s.b.BlockByNumber(ctx, blockNr) blockArgs.InclTx = true if blockArgs.WithSigners { blockArgs.Signers, err = s.GetBlockSigners(ctx, blockNr) if err != nil { return nil, err } } if block != nil { response, err := RPCMarshalBlock(block, blockArgs) if err == nil && blockNr == rpc.PendingBlockNumber { // Pending blocks need to nil out a few fields for _, field := range []string{"hash", "nonce", "miner"} { response[field] = nil } } return response, err } return nil, err } // GetBlockByHashNew returns the requested block. When fullTx in blockArgs is true all transactions in the block are returned in full // detail, otherwise only the transaction hash is returned. When withSigners in BlocksArgs is true // it shows block signers for this block in list of one addresses. func (s *PublicBlockChainAPI) GetBlockByHashNew(ctx context.Context, blockHash common.Hash, blockArgs BlockArgs) (map[string]interface{}, error) { block, err := s.b.GetBlock(ctx, blockHash) blockArgs.InclTx = true if blockArgs.WithSigners { blockArgs.Signers, err = s.GetBlockSigners(ctx, rpc.BlockNumber(block.NumberU64())) if err != nil { return nil, err } } if block != nil { return RPCMarshalBlock(block, blockArgs) } return nil, err } // GetBlocks method returns blocks in range blockStart, blockEnd just like GetBlockByNumber but all at once. func (s *PublicBlockChainAPI) GetBlocks(ctx context.Context, blockStart rpc.BlockNumber, blockEnd rpc.BlockNumber, blockArgs BlockArgs) ([]map[string]interface{}, error) { result := make([]map[string]interface{}, 0) for i := blockStart; i <= blockEnd; i++ { block, err := s.b.BlockByNumber(ctx, i) blockArgs.InclTx = true if blockArgs.WithSigners { blockArgs.Signers, err = s.GetBlockSigners(ctx, rpc.BlockNumber(i)) if err != nil { return nil, err } } if block != nil { rpcBlock, err := RPCMarshalBlock(block, blockArgs) if err == nil && i == rpc.PendingBlockNumber { // Pending blocks need to nil out a few fields for _, field := range []string{"hash", "nonce", "miner"} { rpcBlock[field] = nil } } result = append(result, rpcBlock) } } return result, nil } // GetValidators returns validators list for a particular epoch. func (s *PublicBlockChainAPI) GetValidators(ctx context.Context, epoch int64) (map[string]interface{}, error) { committee, err := s.b.GetValidators(big.NewInt(epoch)) if err != nil { return nil, err } validators := make([]map[string]interface{}, 0) for _, validator := range committee.Slots { oneAddress, err := internal_common.AddressToBech32(validator.EcdsaAddress) if err != nil { return nil, err } validatorBalance, err := s.GetBalance(ctx, oneAddress, rpc.LatestBlockNumber) if err != nil { return nil, err } validatorsFields := map[string]interface{}{ "address": oneAddress, "balance": (*hexutil.Big)(validatorBalance), } validators = append(validators, validatorsFields) } result := map[string]interface{}{ "shardID": committee.ShardID, "validators": validators, } return result, nil } // GetBlockSigners returns signers for a particular block. func (s *PublicBlockChainAPI) GetBlockSigners(ctx context.Context, blockNr rpc.BlockNumber) ([]string, error) { if uint64(blockNr) == 0 || uint64(blockNr) >= uint64(s.BlockNumber()) { return make([]string, 0), nil } block, err := s.b.BlockByNumber(ctx, blockNr) if err != nil { return nil, err } blockWithSigners, err := s.b.BlockByNumber(ctx, blockNr+1) if err != nil { return nil, err } committee, err := s.b.GetValidators(block.Epoch()) if err != nil { return nil, err } pubkeys := make([]*bls.PublicKey, len(committee.Slots)) for i, validator := range committee.Slots { pubkeys[i] = new(bls.PublicKey) validator.BlsPublicKey.ToLibBLSPublicKey(pubkeys[i]) } result := make([]string, 0) mask, err := internal_bls.NewMask(pubkeys, nil) if err != nil { return result, err } if err != nil { return result, err } err = mask.SetMask(blockWithSigners.Header().LastCommitBitmap()) if err != nil { return result, err } for _, validator := range committee.Slots { oneAddress, err := internal_common.AddressToBech32(validator.EcdsaAddress) if err != nil { return result, err } blsPublicKey := new(bls.PublicKey) validator.BlsPublicKey.ToLibBLSPublicKey(blsPublicKey) if ok, err := mask.KeyEnabled(blsPublicKey); err == nil && ok { result = append(result, oneAddress) } } return result, nil } // IsBlockSigner returns true if validator with address signed blockNr block. func (s *PublicBlockChainAPI) IsBlockSigner(ctx context.Context, blockNr rpc.BlockNumber, address string) (bool, error) { if uint64(blockNr) == 0 || uint64(blockNr) >= uint64(s.BlockNumber()) { return false, nil } block, err := s.b.BlockByNumber(ctx, blockNr) if err != nil { return false, err } blockWithSigners, err := s.b.BlockByNumber(ctx, blockNr+1) if err != nil { return false, err } committee, err := s.b.GetValidators(block.Epoch()) if err != nil { return false, err } pubkeys := make([]*bls.PublicKey, len(committee.Slots)) for i, validator := range committee.Slots { pubkeys[i] = new(bls.PublicKey) validator.BlsPublicKey.ToLibBLSPublicKey(pubkeys[i]) } mask, err := internal_bls.NewMask(pubkeys, nil) if err != nil { return false, err } err = mask.SetMask(blockWithSigners.Header().LastCommitBitmap()) if err != nil { return false, err } for _, validator := range committee.Slots { oneAddress, err := internal_common.AddressToBech32(validator.EcdsaAddress) if err != nil { return false, err } if oneAddress != address { continue } blsPublicKey := new(bls.PublicKey) validator.BlsPublicKey.ToLibBLSPublicKey(blsPublicKey) if ok, err := mask.KeyEnabled(blsPublicKey); err == nil && ok { return true, nil } } return false, nil } // GetSignedBlocks returns how many blocks a particular validator signed for last defaultBlocksPeriod (3 hours ~ 1500 blocks). func (s *PublicBlockChainAPI) GetSignedBlocks(ctx context.Context, address string) hexutil.Uint64 { totalSigned := uint64(0) lastBlock := uint64(0) blockHeight := uint64(s.BlockNumber()) if blockHeight >= defaultBlocksPeriod { lastBlock = blockHeight - defaultBlocksPeriod + 1 } for i := lastBlock; i <= blockHeight; i++ { signed, err := s.IsBlockSigner(ctx, rpc.BlockNumber(i), address) if err == nil && signed { totalSigned++ } } return hexutil.Uint64(totalSigned) } // GetEpoch returns current epoch. func (s *PublicBlockChainAPI) GetEpoch(ctx context.Context) hexutil.Uint64 { return hexutil.Uint64(s.LatestHeader(ctx).Epoch) } // GetLeader returns current shard leader. func (s *PublicBlockChainAPI) GetLeader(ctx context.Context) string { return s.LatestHeader(ctx).Leader } // GetValidatorSelfDelegation returns validator stake. func (s *PublicBlockChainAPI) GetValidatorSelfDelegation(ctx context.Context, address string) hexutil.Uint64 { return hexutil.Uint64(s.b.GetValidatorSelfDelegation(internal_common.ParseAddr(address)).Uint64()) } // GetValidatorTotalDelegation returns total balace stacking for validator with delegation. func (s *PublicBlockChainAPI) GetValidatorTotalDelegation(ctx context.Context, address string) hexutil.Uint64 { delegations := s.b.GetDelegationsByValidator(internal_common.ParseAddr(address)) totalStake := big.NewInt(0) for _, delegation := range delegations { totalStake.Add(totalStake, delegation.Amount) } // TODO: return more than uint64 return hexutil.Uint64(totalStake.Uint64()) } // GetShardingStructure returns an array of sharding structures. func (s *PublicBlockChainAPI) GetShardingStructure(ctx context.Context) ([]map[string]interface{}, error) { // Get header and number of shards. epoch := s.GetEpoch(ctx) numShard := shard.Schedule.InstanceForEpoch(big.NewInt(int64(epoch))).NumShards() // Return shareding structure for each case. return shard.Schedule.GetShardingStructure(int(numShard), int(s.b.GetShardID())), nil } // GetShardID returns shard ID of the requested node. func (s *PublicBlockChainAPI) GetShardID(ctx context.Context) (int, error) { return int(s.b.GetShardID()), nil } // GetCode returns the code stored at the given address in the state for the given block number. func (s *PublicBlockChainAPI) GetCode(ctx context.Context, addr string, blockNr rpc.BlockNumber) (hexutil.Bytes, error) { address := internal_common.ParseAddr(addr) state, _, err := s.b.StateAndHeaderByNumber(ctx, blockNr) if state == nil || err != nil { return nil, err } code := state.GetCode(address) return code, state.Error() } // GetStorageAt returns the storage from the state at the given address, key and // block number. The rpc.LatestBlockNumber and rpc.PendingBlockNumber meta block // numbers are also allowed. func (s *PublicBlockChainAPI) GetStorageAt(ctx context.Context, addr string, key string, blockNr rpc.BlockNumber) (hexutil.Bytes, error) { address := internal_common.ParseAddr(addr) state, _, err := s.b.StateAndHeaderByNumber(ctx, blockNr) if state == nil || err != nil { return nil, err } res := state.GetState(address, common.HexToHash(key)) return res[:], state.Error() } // GetBalanceByBlockNumber returns balance by block number. func (s *PublicBlockChainAPI) GetBalanceByBlockNumber(ctx context.Context, address string, blockNr rpc.BlockNumber) (*hexutil.Big, error) { addr := internal_common.ParseAddr(address) balance, err := s.b.GetBalance(ctx, addr, blockNr) if balance == nil { return nil, err } return (*hexutil.Big)(balance), err } // GetBalance returns the amount of Nano for the given address in the state of the // given block number. The rpc.LatestBlockNumber and rpc.PendingBlockNumber meta // block numbers are also allowed. func (s *PublicBlockChainAPI) GetBalance(ctx context.Context, address string, blockNr rpc.BlockNumber) (*hexutil.Big, error) { return s.GetBalanceByBlockNumber(ctx, address, rpc.LatestBlockNumber) } // BlockNumber returns the block number of the chain head. func (s *PublicBlockChainAPI) BlockNumber() hexutil.Uint64 { header, _ := s.b.HeaderByNumber(context.Background(), rpc.LatestBlockNumber) // latest header should always be available return hexutil.Uint64(header.Number().Uint64()) } // ResendCx requests that the egress receipt for the given cross-shard // transaction be sent to the destination shard for credit. This is used for // unblocking a half-complete cross-shard transaction whose fund has been // withdrawn already from the source shard but not credited yet in the // destination account due to transient failures. func (s *PublicBlockChainAPI) ResendCx(ctx context.Context, txID common.Hash) (bool, error) { _, success := s.b.ResendCx(ctx, txID) return success, nil } // Call executes the given transaction on the state for the given block number. // It doesn't make and changes in the state/blockchain and is useful to execute and retrieve values. func (s *PublicBlockChainAPI) Call(ctx context.Context, args CallArgs, blockNr rpc.BlockNumber) (hexutil.Bytes, error) { result, _, _, err := doCall(ctx, s.b, args, blockNr, vm.Config{}, 5*time.Second, s.b.RPCGasCap()) return (hexutil.Bytes)(result), err } func doCall(ctx context.Context, b Backend, args CallArgs, blockNr rpc.BlockNumber, vmCfg vm.Config, timeout time.Duration, globalGasCap *big.Int) ([]byte, uint64, bool, error) { defer func(start time.Time) { utils.Logger().Debug(). Dur("runtime", time.Since(start)). Msg("Executing EVM call finished") }(time.Now()) state, header, err := b.StateAndHeaderByNumber(ctx, blockNr) if state == nil || err != nil { return nil, 0, false, err } // Set sender address or use a default if none specified var addr common.Address if args.From == nil { // TODO(ricl): this logic was borrowed from [go-ethereum](https://github.com/ethereum/go-ethereum/blob/f578d41ee6b3087f8021fd561a0b5665aea3dba6/internal/ethapi/api.go#L738) // [question](https://ethereum.stackexchange.com/questions/72979/why-does-the-docall-function-use-the-first-account-by-default) // Might need to reconsider the logic // if wallets := b.AccountManager().Wallets(); len(wallets) > 0 { // if accounts := wallets[0].Accounts(); len(accounts) > 0 { // addr = accounts[0].Address // } // } // The logic in ethereum is to pick a random address managed under the account manager. // Currently Harmony no longers support the account manager. // Any address does not affect the logic of this call. addr = common.HexToAddress(defaultFromAddress) } else { addr = *args.From } // Set default gas & gas price if none were set gas := uint64(math.MaxUint64 / 2) if args.Gas != nil { gas = uint64(*args.Gas) } if globalGasCap != nil && globalGasCap.Uint64() < gas { utils.Logger().Warn(). Uint64("requested", gas). Uint64("cap", globalGasCap.Uint64()). Msg("Caller gas above allowance, capping") gas = globalGasCap.Uint64() } gasPrice := new(big.Int).SetUint64(defaultGasPrice) if args.GasPrice != nil { gasPrice = args.GasPrice.ToInt() } value := new(big.Int) if args.Value != nil { value = args.Value.ToInt() } var data []byte if args.Data != nil { data = []byte(*args.Data) } // Create new call message msg := types.NewMessage(addr, args.To, 0, value, gas, gasPrice, data, false) // Setup context so it may be cancelled the call has completed // or, in case of unmetered gas, setup a context with a timeout. var cancel context.CancelFunc if timeout > 0 { ctx, cancel = context.WithTimeout(ctx, timeout) } else { ctx, cancel = context.WithCancel(ctx) } // Make sure the context is cancelled when the call has completed // this makes sure resources are cleaned up. defer cancel() // Get a new instance of the EVM. evm, vmError, err := b.GetEVM(ctx, msg, state, header) if err != nil { return nil, 0, false, err } // Wait for the context to be done and cancel the evm. Even if the // EVM has finished, cancelling may be done (repeatedly) go func() { <-ctx.Done() evm.Cancel() }() // Setup the gas pool (also for unmetered requests) // and apply the message. gp := new(core.GasPool).AddGas(math.MaxUint64) res, gas, failed, err := core.ApplyMessage(evm, msg, gp) if err := vmError(); err != nil { return nil, 0, false, err } // If the timer caused an abort, return an appropriate error message if evm.Cancelled() { return nil, 0, false, fmt.Errorf("execution aborted (timeout = %v)", timeout) } return res, gas, failed, err } // LatestHeader returns the latest header information func (s *PublicBlockChainAPI) LatestHeader(ctx context.Context) *HeaderInformation { header, _ := s.b.HeaderByNumber(context.Background(), rpc.LatestBlockNumber) // latest header should always be available return newHeaderInformation(header) } var ( errNotBeaconChainShard = errors.New("cannot call this rpc on non beaconchain node") ) // GetMedianRawStakeSnapshot returns the raw median stake, only meant to be called on beaconchain // explorer node func (s *PublicBlockChainAPI) GetMedianRawStakeSnapshot() (*big.Int, error) { if s.b.GetShardID() == shard.BeaconChainShardID { return s.b.GetMedianRawStakeSnapshot(), nil } return nil, errNotBeaconChainShard } // GetAllValidatorAddresses returns all validator addresses. func (s *PublicBlockChainAPI) GetAllValidatorAddresses() ([]string, error) { addresses := []string{} for _, addr := range s.b.GetAllValidatorAddresses() { oneAddr, _ := internal_common.AddressToBech32(addr) addresses = append(addresses, oneAddr) } return addresses, nil } // GetActiveValidatorAddresses returns active validator addresses. func (s *PublicBlockChainAPI) GetActiveValidatorAddresses() ([]string, error) { addresses := []string{} for _, addr := range s.b.GetActiveValidatorAddresses() { oneAddr, _ := internal_common.AddressToBech32(addr) addresses = append(addresses, oneAddr) } return addresses, nil } // GetValidatorMetrics .. func (s *PublicBlockChainAPI) GetValidatorMetrics(ctx context.Context, address string) (*staking.ValidatorStats, error) { validatorAddress := internal_common.ParseAddr(address) stats := s.b.GetValidatorStats(validatorAddress) if stats == nil { addr, _ := internal_common.AddressToBech32(validatorAddress) return nil, fmt.Errorf("validator stats not found: %s", addr) } return stats, nil } // GetValidatorInformation returns information about a validator. func (s *PublicBlockChainAPI) GetValidatorInformation(ctx context.Context, address string) (*staking.Validator, error) { validatorAddress := internal_common.ParseAddr(address) validator := s.b.GetValidatorInformation(validatorAddress) if validator == nil { addr, _ := internal_common.AddressToBech32(validatorAddress) return nil, fmt.Errorf("validator not found: %s", addr) } return validator, nil } // GetAllValidatorInformation returns information about all validators. func (s *PublicBlockChainAPI) GetAllValidatorInformation(ctx context.Context, page int) []*staking.Validator { if page < -1 { return make([]*staking.Validator, 0) } addresses := s.b.GetAllValidatorAddresses() if page != -1 && len(addresses) <= page*validatorsPageSize { return make([]*staking.Validator, 0) } validatorsNum := len(addresses) start := 0 if page != -1 { validatorsNum = validatorsPageSize start = page * validatorsPageSize if len(addresses)-start < validatorsPageSize { validatorsNum = len(addresses) - start } else { validatorsNum = validatorsPageSize } } validators := make([]*staking.Validator, validatorsNum) for i := start; i < start+validatorsNum; i++ { validators[i] = s.b.GetValidatorInformation(addresses[i]) } return validators } // GetDelegationsByDelegator returns list of delegations for a delegator address. func (s *PublicBlockChainAPI) GetDelegationsByDelegator(ctx context.Context, address string) ([]*RPCDelegation, error) { delegatorAddress := internal_common.ParseAddr(address) validators, delegations := s.b.GetDelegationsByDelegator(delegatorAddress) result := []*RPCDelegation{} for i := range delegations { delegation := delegations[i] undelegations := []RPCUndelegation{} for j := range delegation.Undelegations { undelegations = append(undelegations, RPCUndelegation{ delegation.Undelegations[j].Amount, delegation.Undelegations[j].Epoch, }) } valAddr, _ := internal_common.AddressToBech32(validators[i]) delAddr, _ := internal_common.AddressToBech32(delegatorAddress) result = append(result, &RPCDelegation{ valAddr, delAddr, delegation.Amount, delegation.Reward, undelegations, }) } return result, nil } // GetDelegationsByValidator returns list of delegations for a validator address. func (s *PublicBlockChainAPI) GetDelegationsByValidator(ctx context.Context, address string) ([]*RPCDelegation, error) { validatorAddress := internal_common.ParseAddr(address) delegations := s.b.GetDelegationsByValidator(validatorAddress) result := make([]*RPCDelegation, 0) for _, delegation := range delegations { undelegations := []RPCUndelegation{} for j := range delegation.Undelegations { undelegations = append(undelegations, RPCUndelegation{ delegation.Undelegations[j].Amount, delegation.Undelegations[j].Epoch, }) } valAddr, _ := internal_common.AddressToBech32(validatorAddress) delAddr, _ := internal_common.AddressToBech32(delegation.DelegatorAddress) result = append(result, &RPCDelegation{ valAddr, delAddr, delegation.Amount, delegation.Reward, undelegations, }) } return result, nil } // GetDelegationByDelegatorAndValidator returns a delegation for delegator and validator. func (s *PublicBlockChainAPI) GetDelegationByDelegatorAndValidator(ctx context.Context, address string, validator string) (*RPCDelegation, error) { delegatorAddress := internal_common.ParseAddr(address) validatorAddress := internal_common.ParseAddr(validator) validators, delegations := s.b.GetDelegationsByDelegator(delegatorAddress) for i := range delegations { if validators[i] != validatorAddress { continue } delegation := delegations[i] undelegations := []RPCUndelegation{} for j := range delegation.Undelegations { undelegations = append(undelegations, RPCUndelegation{ delegation.Undelegations[j].Amount, delegation.Undelegations[j].Epoch, }) } valAddr, _ := internal_common.AddressToBech32(validatorAddress) delAddr, _ := internal_common.AddressToBech32(delegatorAddress) return &RPCDelegation{ valAddr, delAddr, delegation.Amount, delegation.Reward, undelegations, }, nil } return nil, nil } // doEstimateGas .. func doEstimateGas(ctx context.Context, b Backend, args CallArgs, gasCap *big.Int) (hexutil.Uint64, error) { // Binary search the gas requirement, as it may be higher than the amount used var ( lo uint64 = params.TxGas - 1 hi uint64 cap uint64 ) blockNum := rpc.LatestBlockNumber if args.Gas != nil && uint64(*args.Gas) >= params.TxGas { hi = uint64(*args.Gas) } else { // Retrieve the block to act as the gas ceiling block, err := b.BlockByNumber(ctx, blockNum) if err != nil { return 0, err } hi = block.GasLimit() } if gasCap != nil && hi > gasCap.Uint64() { // log.Warn("Caller gas above allowance, capping", "requested", hi, "cap", gasCap) hi = gasCap.Uint64() } cap = hi // Use zero-address if none other is available if args.From == nil { args.From = &common.Address{} } // Create a helper to check if a gas allowance results in an executable transaction executable := func(gas uint64) bool { args.Gas = (*hexutil.Uint64)(&gas) _, _, failed, err := doCall(ctx, b, args, blockNum, vm.Config{}, 0, big.NewInt(int64(cap))) if err != nil || failed { return false } return true } // Execute the binary search and hone in on an executable gas limit for lo+1 < hi { mid := (hi + lo) / 2 if !executable(mid) { lo = mid } else { hi = mid } } // Reject the transaction as invalid if it still fails at the highest allowance if hi == cap { if !executable(hi) { return 0, fmt.Errorf("gas required exceeds allowance (%d) or always failing transaction", cap) } } return hexutil.Uint64(hi), nil } // EstimateGas returns an estimate of the amount of gas needed to execute the // given transaction against the current pending block. func (s *PublicBlockChainAPI) EstimateGas(ctx context.Context, args CallArgs) (hexutil.Uint64, error) { return doEstimateGas(ctx, s.b, args, nil) } // GetCurrentUtilityMetrics .. func (s *PublicBlockChainAPI) GetCurrentUtilityMetrics() (*network.UtilityMetric, error) { if s.b.GetShardID() == shard.BeaconChainShardID { return s.b.GetCurrentUtilityMetrics() } return nil, errNotBeaconChainShard } // GetSuperCommittees .. func (s *PublicBlockChainAPI) GetSuperCommittees() (*quorum.Transition, error) { if s.b.GetShardID() == shard.BeaconChainShardID { return s.b.GetSuperCommittees() } return nil, errNotBeaconChainShard }