package node import ( "crypto/ecdsa" "math/big" "os" "github.com/harmony-one/harmony/contracts/structs" "github.com/harmony-one/harmony/core" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/harmony-one/harmony/internal/utils" "github.com/ethereum/go-ethereum/common/hexutil" ) //constants related to staking //The first four bytes of the call data for a function call specifies the function to be called. //It is the first (left, high-order in big-endian) four bytes of the Keccak-256 (SHA-3) //Refer: https://solidity.readthedocs.io/en/develop/abi-spec.html const ( funcSingatureBytes = 4 lockPeriodInEpochs = 3 // This should be in sync with contracts/StakeLockContract.sol ) // UpdateStakingList updates staking information by querying the staking smart contract. func (node *Node) UpdateStakingList(stakeInfoReturnValue *structs.StakeInfoReturnValue) { node.CurrentStakes = make(map[common.Address]*structs.StakeInfo) if stakeInfoReturnValue != nil { for i, addr := range stakeInfoReturnValue.LockedAddresses { blockNum := stakeInfoReturnValue.BlockNums[i] lockPeriodCount := stakeInfoReturnValue.LockPeriodCounts[i] startEpoch := core.GetEpochFromBlockNumber(blockNum.Uint64()) curEpoch := core.GetEpochFromBlockNumber(node.blockchain.CurrentBlock().NumberU64()) if startEpoch == curEpoch { continue // The token are counted into stakes at the beginning of next epoch. } // True if the token is still staked within the locking period. if curEpoch-startEpoch <= lockPeriodCount.Uint64()*lockPeriodInEpochs { node.CurrentStakes[addr] = &structs.StakeInfo{ stakeInfoReturnValue.BlsAddresses[i], blockNum, lockPeriodCount, stakeInfoReturnValue.Amounts[i], } } } } } func (node *Node) printStakingList() { utils.GetLogInstance().Info("\n") utils.GetLogInstance().Info("CURRENT STAKING INFO [START] ------------------------------------") for addr, stakeInfo := range node.CurrentStakes { utils.GetLogInstance().Info("", "Address", addr, "StakeInfo", stakeInfo) } utils.GetLogInstance().Info("CURRENT STAKING INFO [END} ------------------------------------") utils.GetLogInstance().Info("\n") } //The first four bytes of the call data for a function call specifies the function to be called. //It is the first (left, high-order in big-endian) four bytes of the Keccak-256 (SHA-3) //Refer: https://solidity.readthedocs.io/en/develop/abi-spec.html func decodeStakeCall(getData []byte) int64 { value := new(big.Int) value.SetBytes(getData[funcSingatureBytes:]) //Escape the method call. return value.Int64() } //The first four bytes of the call data for a function call specifies the function to be called. //It is the first (left, high-order in big-endian) four bytes of the Keccak-256 (SHA-3) //Refer: https://solidity.readthedocs.io/en/develop/abi-spec.html //gets the function signature from data. func decodeFuncSign(data []byte) string { funcSign := hexutil.Encode(data[:funcSingatureBytes]) //The function signature is first 4 bytes of data in ethereum return funcSign } // StoreStakingKeyFromFile load the staking private key and store it in local keyfile func StoreStakingKeyFromFile(keyfile string, priKey string) *ecdsa.PrivateKey { // contract.FakeAccounts[0] gets minted tokens in genesis block of beacon chain. key, err := crypto.HexToECDSA(priKey) if err != nil { utils.GetLogInstance().Error("Unable to get staking key") os.Exit(1) } if err := crypto.SaveECDSA(keyfile, key); err != nil { utils.GetLogInstance().Error("Unable to save the private key", "error", err) os.Exit(1) } // TODO(minhdoan): Enable this back. // key, err := crypto.LoadECDSA(keyfile) // if err != nil { // GetLogInstance().Error("no key file. Let's create a staking private key") // key, err = crypto.GenerateKey() // if err != nil { // GetLogInstance().Error("Unable to generate the private key") // os.Exit(1) // } // if err = crypto.SaveECDSA(keyfile, key); err != nil { // GetLogInstance().Error("Unable to save the private key", "error", err) // os.Exit(1) // } // } return key }