params

package
v1.9.0-rc.0 Latest Latest
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Published: Apr 16, 2022 License: LGPL-3.0 Imports: 6 Imported by: 0

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Index

Constants

View Source
const (
	// MinGasPrice is the number of nAVAX required per gas unit for a
	// transaction to be valid, measured in wei
	LaunchMinGasPrice        int64 = 470_000_000_000
	ApricotPhase1MinGasPrice int64 = 225_000_000_000

	AvalancheAtomicTxFee = units.MilliAvax

	ApricotPhase1GasLimit uint64 = 8_000_000

	ApricotPhase3ExtraDataSize                   = 80
	ApricotPhase3MinBaseFee               int64  = 75_000_000_000
	ApricotPhase3MaxBaseFee               int64  = 225_000_000_000
	ApricotPhase3InitialBaseFee           int64  = 225_000_000_000
	ApricotPhase3TargetGas                uint64 = 10_000_000
	ApricotPhase4MinBaseFee               int64  = 25_000_000_000
	ApricotPhase4MaxBaseFee               int64  = 1_000_000_000_000
	ApricotPhase4BaseFeeChangeDenominator uint64 = 12
	ApricotPhase5TargetGas                uint64 = 15_000_000
	ApricotPhase5BaseFeeChangeDenominator uint64 = 36

	// The base cost to charge per atomic transaction. Added in Apricot Phase 5.
	AtomicTxBaseCost uint64 = 10_000
)

Minimum Gas Price

View Source
const (
	Wei   = 1
	GWei  = 1e9
	Ether = 1e18
)

These are the multipliers for ether denominations. Example: To get the wei value of an amount in 'gwei', use

new(big.Int).Mul(value, big.NewInt(params.GWei))
View Source
const (
	// BloomBitsBlocks is the number of blocks a single bloom bit section vector
	// contains on the server side.
	BloomBitsBlocks uint64 = 4096

	// BloomBitsBlocksClient is the number of blocks a single bloom bit section vector
	// contains on the light client side
	BloomBitsBlocksClient uint64 = 32768

	// BloomConfirms is the number of confirmation blocks before a bloom section is
	// considered probably final and its rotated bits are calculated.
	BloomConfirms = 256

	// CHTFrequency is the block frequency for creating CHTs
	CHTFrequency = 32768

	// BloomTrieFrequency is the block frequency for creating BloomTrie on both
	// server/client sides.
	BloomTrieFrequency = 32768

	// HelperTrieConfirmations is the number of confirmations before a client is expected
	// to have the given HelperTrie available.
	HelperTrieConfirmations = 2048

	// HelperTrieProcessConfirmations is the number of confirmations before a HelperTrie
	// is generated
	HelperTrieProcessConfirmations = 256

	// CheckpointFrequency is the block frequency for creating checkpoint
	CheckpointFrequency = 32768

	// CheckpointProcessConfirmations is the number before a checkpoint is generated
	CheckpointProcessConfirmations = 256

	// FullImmutabilityThreshold is the number of blocks after which a chain segment is
	// considered immutable (i.e. soft finality). It is used by the downloader as a
	// hard limit against deep ancestors, by the blockchain against deep reorgs, by
	// the freezer as the cutoff threshold and by clique as the snapshot trust limit.
	FullImmutabilityThreshold = 90000

	// LightImmutabilityThreshold is the number of blocks after which a header chain
	// segment is considered immutable for light client(i.e. soft finality). It is used by
	// the downloader as a hard limit against deep ancestors, by the blockchain against deep
	// reorgs, by the light pruner as the pruning validity guarantee.
	LightImmutabilityThreshold = 30000
)
View Source
const (
	GasLimitBoundDivisor uint64 = 1024               // The bound divisor of the gas limit, used in update calculations.
	MinGasLimit          uint64 = 5000               // Minimum the gas limit may ever be.
	MaxGasLimit          uint64 = 0x7fffffffffffffff // Maximum the gas limit (2^63-1).
	GenesisGasLimit      uint64 = 4712388            // Gas limit of the Genesis block.

	// Note: MaximumExtraDataSize has been reduced to 32 in Geth, but is kept the same in Coreth for
	// backwards compatibility.
	MaximumExtraDataSize  uint64 = 64    // Maximum size extra data may be after Genesis.
	ExpByteGas            uint64 = 10    // Times ceil(log256(exponent)) for the EXP instruction.
	SloadGas              uint64 = 50    // Multiplied by the number of 32-byte words that are copied (round up) for any *COPY operation and added.
	CallValueTransferGas  uint64 = 9000  // Paid for CALL when the value transfer is non-zero.
	CallNewAccountGas     uint64 = 25000 // Paid for CALL when the destination address didn't exist prior.
	TxGas                 uint64 = 21000 // Per transaction not creating a contract. NOTE: Not payable on data of calls between transactions.
	TxGasContractCreation uint64 = 53000 // Per transaction that creates a contract. NOTE: Not payable on data of calls between transactions.
	TxDataZeroGas         uint64 = 4     // Per byte of data attached to a transaction that equals zero. NOTE: Not payable on data of calls between transactions.
	QuadCoeffDiv          uint64 = 512   // Divisor for the quadratic particle of the memory cost equation.
	LogDataGas            uint64 = 8     // Per byte in a LOG* operation's data.
	CallStipend           uint64 = 2300  // Free gas given at beginning of call.

	Keccak256Gas     uint64 = 30 // Once per KECCAK256 operation.
	Keccak256WordGas uint64 = 6  // Once per word of the KECCAK256 operation's data.

	SstoreSetGas    uint64 = 20000 // Once per SSTORE operation.
	SstoreResetGas  uint64 = 5000  // Once per SSTORE operation if the zeroness changes from zero.
	SstoreClearGas  uint64 = 5000  // Once per SSTORE operation if the zeroness doesn't change.
	SstoreRefundGas uint64 = 15000 // Once per SSTORE operation if the zeroness changes to zero.

	NetSstoreNoopGas  uint64 = 200   // Once per SSTORE operation if the value doesn't change.
	NetSstoreInitGas  uint64 = 20000 // Once per SSTORE operation from clean zero.
	NetSstoreCleanGas uint64 = 5000  // Once per SSTORE operation from clean non-zero.
	NetSstoreDirtyGas uint64 = 200   // Once per SSTORE operation from dirty.

	NetSstoreClearRefund      uint64 = 15000 // Once per SSTORE operation for clearing an originally existing storage slot
	NetSstoreResetRefund      uint64 = 4800  // Once per SSTORE operation for resetting to the original non-zero value
	NetSstoreResetClearRefund uint64 = 19800 // Once per SSTORE operation for resetting to the original zero value

	SstoreSentryGasEIP2200            uint64 = 2300  // Minimum gas required to be present for an SSTORE call, not consumed
	SstoreSetGasEIP2200               uint64 = 20000 // Once per SSTORE operation from clean zero to non-zero
	SstoreResetGasEIP2200             uint64 = 5000  // Once per SSTORE operation from clean non-zero to something else
	SstoreClearsScheduleRefundEIP2200 uint64 = 15000 // Once per SSTORE operation for clearing an originally existing storage slot

	ColdAccountAccessCostEIP2929 = uint64(2600) // COLD_ACCOUNT_ACCESS_COST
	ColdSloadCostEIP2929         = uint64(2100) // COLD_SLOAD_COST
	WarmStorageReadCostEIP2929   = uint64(100)  // WARM_STORAGE_READ_COST

	// In EIP-2200: SstoreResetGas was 5000.
	// In EIP-2929: SstoreResetGas was changed to '5000 - COLD_SLOAD_COST'.
	// In EIP-3529: SSTORE_CLEARS_SCHEDULE is defined as SSTORE_RESET_GAS + ACCESS_LIST_STORAGE_KEY_COST
	// Which becomes: 5000 - 2100 + 1900 = 4800
	SstoreClearsScheduleRefundEIP3529 uint64 = SstoreResetGasEIP2200 - ColdSloadCostEIP2929 + TxAccessListStorageKeyGas

	JumpdestGas   uint64 = 1     // Once per JUMPDEST operation.
	EpochDuration uint64 = 30000 // Duration between proof-of-work epochs.

	CreateDataGas         uint64 = 200   //
	CallCreateDepth       uint64 = 1024  // Maximum depth of call/create stack.
	ExpGas                uint64 = 10    // Once per EXP instruction
	LogGas                uint64 = 375   // Per LOG* operation.
	CopyGas               uint64 = 3     //
	StackLimit            uint64 = 1024  // Maximum size of VM stack allowed.
	TierStepGas           uint64 = 0     // Once per operation, for a selection of them.
	LogTopicGas           uint64 = 375   // Multiplied by the * of the LOG*, per LOG transaction. e.g. LOG0 incurs 0 * c_txLogTopicGas, LOG4 incurs 4 * c_txLogTopicGas.
	CreateGas             uint64 = 32000 // Once per CREATE operation & contract-creation transaction.
	Create2Gas            uint64 = 32000 // Once per CREATE2 operation
	SelfdestructRefundGas uint64 = 24000 // Refunded following a selfdestruct operation.
	MemoryGas             uint64 = 3     // Times the address of the (highest referenced byte in memory + 1). NOTE: referencing happens on read, write and in instructions such as RETURN and CALL.

	TxDataNonZeroGasFrontier  uint64 = 68   // Per byte of data attached to a transaction that is not equal to zero. NOTE: Not payable on data of calls between transactions.
	TxDataNonZeroGasEIP2028   uint64 = 16   // Per byte of non zero data attached to a transaction after EIP 2028 (part in Istanbul)
	TxAccessListAddressGas    uint64 = 2400 // Per address specified in EIP 2930 access list
	TxAccessListStorageKeyGas uint64 = 1900 // Per storage key specified in EIP 2930 access list

	// These have been changed during the course of the chain
	CallGasFrontier              uint64 = 40  // Once per CALL operation & message call transaction.
	CallGasEIP150                uint64 = 700 // Static portion of gas for CALL-derivates after EIP 150 (Tangerine)
	BalanceGasFrontier           uint64 = 20  // The cost of a BALANCE operation
	BalanceGasEIP150             uint64 = 400 // The cost of a BALANCE operation after Tangerine
	BalanceGasEIP1884            uint64 = 700 // The cost of a BALANCE operation after EIP 1884 (part of Istanbul)
	ExtcodeSizeGasFrontier       uint64 = 20  // Cost of EXTCODESIZE before EIP 150 (Tangerine)
	ExtcodeSizeGasEIP150         uint64 = 700 // Cost of EXTCODESIZE after EIP 150 (Tangerine)
	SloadGasFrontier             uint64 = 50
	SloadGasEIP150               uint64 = 200
	SloadGasEIP1884              uint64 = 800  // Cost of SLOAD after EIP 1884 (part of Istanbul)
	SloadGasEIP2200              uint64 = 800  // Cost of SLOAD after EIP 2200 (part of Istanbul)
	ExtcodeHashGasConstantinople uint64 = 400  // Cost of EXTCODEHASH (introduced in Constantinople)
	ExtcodeHashGasEIP1884        uint64 = 700  // Cost of EXTCODEHASH after EIP 1884 (part in Istanbul)
	SelfdestructGasEIP150        uint64 = 5000 // Cost of SELFDESTRUCT post EIP 150 (Tangerine)

	// EXP has a dynamic portion depending on the size of the exponent
	ExpByteFrontier uint64 = 10 // was set to 10 in Frontier
	ExpByteEIP158   uint64 = 50 // was raised to 50 during Eip158 (Spurious Dragon)

	// Extcodecopy has a dynamic AND a static cost. This represents only the
	// static portion of the gas. It was changed during EIP 150 (Tangerine)
	ExtcodeCopyBaseFrontier uint64 = 20
	ExtcodeCopyBaseEIP150   uint64 = 700

	// CreateBySelfdestructGas is used when the refunded account is one that does
	// not exist. This logic is similar to call.
	// Introduced in Tangerine Whistle (Eip 150)
	CreateBySelfdestructGas uint64 = 25000

	MaxCodeSize = 24576 // Maximum bytecode to permit for a contract

	EcrecoverGas        uint64 = 3000 // Elliptic curve sender recovery gas price
	Sha256BaseGas       uint64 = 60   // Base price for a SHA256 operation
	Sha256PerWordGas    uint64 = 12   // Per-word price for a SHA256 operation
	Ripemd160BaseGas    uint64 = 600  // Base price for a RIPEMD160 operation
	Ripemd160PerWordGas uint64 = 120  // Per-word price for a RIPEMD160 operation
	IdentityBaseGas     uint64 = 15   // Base price for a data copy operation
	IdentityPerWordGas  uint64 = 3    // Per-work price for a data copy operation

	Bn256AddGasByzantium             uint64 = 500    // Byzantium gas needed for an elliptic curve addition
	Bn256AddGasIstanbul              uint64 = 150    // Gas needed for an elliptic curve addition
	Bn256ScalarMulGasByzantium       uint64 = 40000  // Byzantium gas needed for an elliptic curve scalar multiplication
	Bn256ScalarMulGasIstanbul        uint64 = 6000   // Gas needed for an elliptic curve scalar multiplication
	Bn256PairingBaseGasByzantium     uint64 = 100000 // Byzantium base price for an elliptic curve pairing check
	Bn256PairingBaseGasIstanbul      uint64 = 45000  // Base price for an elliptic curve pairing check
	Bn256PairingPerPointGasByzantium uint64 = 80000  // Byzantium per-point price for an elliptic curve pairing check
	Bn256PairingPerPointGasIstanbul  uint64 = 34000  // Per-point price for an elliptic curve pairing check

	Bls12381G1AddGas          uint64 = 600    // Price for BLS12-381 elliptic curve G1 point addition
	Bls12381G1MulGas          uint64 = 12000  // Price for BLS12-381 elliptic curve G1 point scalar multiplication
	Bls12381G2AddGas          uint64 = 4500   // Price for BLS12-381 elliptic curve G2 point addition
	Bls12381G2MulGas          uint64 = 55000  // Price for BLS12-381 elliptic curve G2 point scalar multiplication
	Bls12381PairingBaseGas    uint64 = 115000 // Base gas price for BLS12-381 elliptic curve pairing check
	Bls12381PairingPerPairGas uint64 = 23000  // Per-point pair gas price for BLS12-381 elliptic curve pairing check
	Bls12381MapG1Gas          uint64 = 5500   // Gas price for BLS12-381 mapping field element to G1 operation
	Bls12381MapG2Gas          uint64 = 110000 // Gas price for BLS12-381 mapping field element to G2 operation

	// Avalanche Stateful Precompile Params
	// Gas price for native asset balance lookup. Based on the cost of an SLOAD operation since native
	// asset balances are kept in state storage.
	AssetBalanceApricot uint64 = 2100
	// Gas price for native asset call. This gas price reflects the additional work done for the native
	// asset transfer itself, which is a write to state storage. The cost of creating a new account and
	// normal value transfer is assessed separately from this cost.
	AssetCallApricot uint64 = 20000
)
View Source
const (
	VersionMajor = 1        // Major version component of the current release
	VersionMinor = 10       // Minor version component of the current release
	VersionPatch = 16       // Patch version component of the current release
	VersionMeta  = "stable" // Version metadata to append to the version string
)

Variables

View Source
var (
	// AvalancheMainnetChainID ...
	AvalancheMainnetChainID = big.NewInt(43114)
	// AvalancheFujiChainID ...
	AvalancheFujiChainID = big.NewInt(43113)
	// AvalancheLocalChainID ...
	AvalancheLocalChainID = big.NewInt(43112)
)

Avalanche ChainIDs

View Source
var (
	// AvalancheMainnetChainConfig is the configuration for Avalanche Main Network
	AvalancheMainnetChainConfig = &ChainConfig{
		ChainID:                     AvalancheMainnetChainID,
		HomesteadBlock:              big.NewInt(0),
		DAOForkBlock:                big.NewInt(0),
		DAOForkSupport:              true,
		EIP150Block:                 big.NewInt(0),
		EIP150Hash:                  common.HexToHash("0x2086799aeebeae135c246c65021c82b4e15a2c451340993aacfd2751886514f0"),
		EIP155Block:                 big.NewInt(0),
		EIP158Block:                 big.NewInt(0),
		ByzantiumBlock:              big.NewInt(0),
		ConstantinopleBlock:         big.NewInt(0),
		PetersburgBlock:             big.NewInt(0),
		IstanbulBlock:               big.NewInt(0),
		MuirGlacierBlock:            big.NewInt(0),
		ApricotPhase1BlockTimestamp: big.NewInt(time.Date(2021, time.March, 31, 14, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase2BlockTimestamp: big.NewInt(time.Date(2021, time.May, 10, 11, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase3BlockTimestamp: big.NewInt(time.Date(2021, time.August, 24, 14, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase4BlockTimestamp: big.NewInt(time.Date(2021, time.September, 22, 21, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase5BlockTimestamp: big.NewInt(time.Date(2021, time.December, 2, 18, 0, 0, 0, time.UTC).Unix()),
	}

	// AvalancheFujiChainConfig is the configuration for the Fuji Test Network
	AvalancheFujiChainConfig = &ChainConfig{
		ChainID:                     AvalancheFujiChainID,
		HomesteadBlock:              big.NewInt(0),
		DAOForkBlock:                big.NewInt(0),
		DAOForkSupport:              true,
		EIP150Block:                 big.NewInt(0),
		EIP150Hash:                  common.HexToHash("0x2086799aeebeae135c246c65021c82b4e15a2c451340993aacfd2751886514f0"),
		EIP155Block:                 big.NewInt(0),
		EIP158Block:                 big.NewInt(0),
		ByzantiumBlock:              big.NewInt(0),
		ConstantinopleBlock:         big.NewInt(0),
		PetersburgBlock:             big.NewInt(0),
		IstanbulBlock:               big.NewInt(0),
		MuirGlacierBlock:            big.NewInt(0),
		ApricotPhase1BlockTimestamp: big.NewInt(time.Date(2021, time.March, 26, 14, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase2BlockTimestamp: big.NewInt(time.Date(2021, time.May, 5, 14, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase3BlockTimestamp: big.NewInt(time.Date(2021, time.August, 16, 19, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase4BlockTimestamp: big.NewInt(time.Date(2021, time.September, 16, 21, 0, 0, 0, time.UTC).Unix()),
		ApricotPhase5BlockTimestamp: big.NewInt(time.Date(2021, time.November, 24, 15, 0, 0, 0, time.UTC).Unix()),
	}

	// AvalancheLocalChainConfig is the configuration for the Avalanche Local Network
	AvalancheLocalChainConfig = &ChainConfig{
		ChainID:                     AvalancheLocalChainID,
		HomesteadBlock:              big.NewInt(0),
		DAOForkBlock:                big.NewInt(0),
		DAOForkSupport:              true,
		EIP150Block:                 big.NewInt(0),
		EIP150Hash:                  common.HexToHash("0x2086799aeebeae135c246c65021c82b4e15a2c451340993aacfd2751886514f0"),
		EIP155Block:                 big.NewInt(0),
		EIP158Block:                 big.NewInt(0),
		ByzantiumBlock:              big.NewInt(0),
		ConstantinopleBlock:         big.NewInt(0),
		PetersburgBlock:             big.NewInt(0),
		IstanbulBlock:               big.NewInt(0),
		MuirGlacierBlock:            big.NewInt(0),
		ApricotPhase1BlockTimestamp: big.NewInt(0),
		ApricotPhase2BlockTimestamp: big.NewInt(0),
		ApricotPhase3BlockTimestamp: big.NewInt(0),
		ApricotPhase4BlockTimestamp: big.NewInt(0),
		ApricotPhase5BlockTimestamp: big.NewInt(0),
	}

	TestChainConfig         = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0)}
	TestLaunchConfig        = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), nil, nil, nil, nil, nil}
	TestApricotPhase1Config = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), nil, nil, nil, nil}
	TestApricotPhase2Config = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), nil, nil, nil}
	TestApricotPhase3Config = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), nil, nil}
	TestApricotPhase4Config = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), nil}
	TestApricotPhase5Config = &ChainConfig{big.NewInt(1), big.NewInt(0), nil, false, big.NewInt(0), common.Hash{}, big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0), big.NewInt(0)}
	TestRules               = TestChainConfig.AvalancheRules(new(big.Int), new(big.Int))
)
View Source
var (
	DifficultyBoundDivisor = big.NewInt(2048)   // The bound divisor of the difficulty, used in the update calculations.
	GenesisDifficulty      = big.NewInt(131072) // Difficulty of the Genesis block.
	MinimumDifficulty      = big.NewInt(131072) // The minimum that the difficulty may ever be.
	DurationLimit          = big.NewInt(13)     // The decision boundary on the blocktime duration used to determine whether difficulty should go up or not.
)
View Source
var (
	// The atomic gas limit specifies the maximum amount of gas that can be consumed by the atomic
	// transactions included in a block and is enforced as of ApricotPhase5. Prior to ApricotPhase5,
	// a block included a single atomic transaction. As of ApricotPhase5, each block can include a set
	// of atomic transactions where the cumulative atomic gas consumed is capped by the atomic gas limit,
	// similar to the block gas limit.
	//
	// This value must always remain <= MaxUint64.
	AtomicGasLimit *big.Int = big.NewInt(100_000)
)
View Source
var Bls12381MultiExpDiscountTable = [128]uint64{} /* 128 elements not displayed */

Gas discount table for BLS12-381 G1 and G2 multi exponentiation operations

View Source
var DAOForkBlockExtra = common.FromHex("0x64616f2d686172642d666f726b")

DAOForkBlockExtra is the block header extra-data field to set for the DAO fork point and a number of consecutive blocks to allow fast/light syncers to correctly pick the side they want ("dao-hard-fork").

View Source
var DAOForkExtraRange = big.NewInt(10)

DAOForkExtraRange is the number of consecutive blocks from the DAO fork point to override the extra-data in to prevent no-fork attacks.

View Source
var DAORefundContract = common.HexToAddress("0xbf4ed7b27f1d666546e30d74d50d173d20bca754")

DAORefundContract is the address of the refund contract to send DAO balances to.

View Source
var Version = func() string {
	return fmt.Sprintf("%d.%d.%d", VersionMajor, VersionMinor, VersionPatch)
}()

Version holds the textual version string.

View Source
var VersionWithMeta = func() string {
	v := Version
	if VersionMeta != "" {
		v += "-" + VersionMeta
	}
	return v
}()

VersionWithMeta holds the textual version string including the metadata.

Functions

func DAODrainList added in v0.9.0

func DAODrainList() []common.Address

DAODrainList is the list of accounts whose full balances will be moved into a refund contract at the beginning of the dao-fork block.

Types

type ChainConfig added in v0.9.0

type ChainConfig struct {
	ChainID *big.Int `json:"chainId"` // chainId identifies the current chain and is used for replay protection

	HomesteadBlock *big.Int `json:"homesteadBlock,omitempty"` // Homestead switch block (nil = no fork, 0 = already homestead)

	DAOForkBlock   *big.Int `json:"daoForkBlock,omitempty"`   // TheDAO hard-fork switch block (nil = no fork)
	DAOForkSupport bool     `json:"daoForkSupport,omitempty"` // Whether the nodes supports or opposes the DAO hard-fork

	// EIP150 implements the Gas price changes (https://github.com/ethereum/EIPs/issues/150)
	EIP150Block *big.Int    `json:"eip150Block,omitempty"` // EIP150 HF block (nil = no fork)
	EIP150Hash  common.Hash `json:"eip150Hash,omitempty"`  // EIP150 HF hash (needed for header only clients as only gas pricing changed)

	EIP155Block *big.Int `json:"eip155Block,omitempty"` // EIP155 HF block
	EIP158Block *big.Int `json:"eip158Block,omitempty"` // EIP158 HF block

	ByzantiumBlock      *big.Int `json:"byzantiumBlock,omitempty"`      // Byzantium switch block (nil = no fork, 0 = already on byzantium)
	ConstantinopleBlock *big.Int `json:"constantinopleBlock,omitempty"` // Constantinople switch block (nil = no fork, 0 = already activated)
	PetersburgBlock     *big.Int `json:"petersburgBlock,omitempty"`     // Petersburg switch block (nil = same as Constantinople)
	IstanbulBlock       *big.Int `json:"istanbulBlock,omitempty"`       // Istanbul switch block (nil = no fork, 0 = already on istanbul)
	MuirGlacierBlock    *big.Int `json:"muirGlacierBlock,omitempty"`    // Eip-2384 (bomb delay) switch block (nil = no fork, 0 = already activated)

	// Avalanche Network Upgrades
	ApricotPhase1BlockTimestamp *big.Int `json:"apricotPhase1BlockTimestamp,omitempty"` // Apricot Phase 1 Block Timestamp (nil = no fork, 0 = already activated)
	// Apricot Phase 2 Block Timestamp (nil = no fork, 0 = already activated)
	// Apricot Phase 2 includes a modified version of the Berlin Hard Fork from Ethereum
	ApricotPhase2BlockTimestamp *big.Int `json:"apricotPhase2BlockTimestamp,omitempty"`
	// Apricot Phase 3 introduces dynamic fees and a modified version of the London Hard Fork from Ethereum (nil = no fork, 0 = already activated)
	ApricotPhase3BlockTimestamp *big.Int `json:"apricotPhase3BlockTimestamp,omitempty"`
	// Apricot Phase 4 introduces the notion of a block fee to the dynamic fee algorithm (nil = no fork, 0 = already activated)
	ApricotPhase4BlockTimestamp *big.Int `json:"apricotPhase4BlockTimestamp,omitempty"`
	// Apricot Phase 5 introduces a batch of atomic transactions with a maximum atomic gas limit per block. (nil = no fork, 0 = already activated)
	ApricotPhase5BlockTimestamp *big.Int `json:"apricotPhase5BlockTimestamp,omitempty"`
}

ChainConfig is the core config which determines the blockchain settings.

ChainConfig is stored in the database on a per block basis. This means that any network, identified by its genesis block, can have its own set of configuration options.

func (*ChainConfig) AvalancheRules added in v0.9.0

func (c *ChainConfig) AvalancheRules(blockNum, blockTimestamp *big.Int) Rules

AvalancheRules returns the Avalanche modified rules to support Avalanche network upgrades

func (*ChainConfig) CheckCompatible added in v0.9.0

func (c *ChainConfig) CheckCompatible(newcfg *ChainConfig, height uint64, timestamp uint64) *ConfigCompatError

CheckCompatible checks whether scheduled fork transitions have been imported with a mismatching chain configuration.

func (*ChainConfig) CheckConfigForkOrder added in v0.9.0

func (c *ChainConfig) CheckConfigForkOrder() error

CheckConfigForkOrder checks that we don't "skip" any forks, geth isn't pluggable enough to guarantee that forks can be implemented in a different order than on official networks

func (*ChainConfig) IsApricotPhase1 added in v0.9.0

func (c *ChainConfig) IsApricotPhase1(blockTimestamp *big.Int) bool

IsApricotPhase1 returns whether [blockTimestamp] represents a block with a timestamp after the Apricot Phase 1 upgrade time.

func (*ChainConfig) IsApricotPhase2 added in v0.9.0

func (c *ChainConfig) IsApricotPhase2(blockTimestamp *big.Int) bool

IsApricotPhase2 returns whether [blockTimestamp] represents a block with a timestamp after the Apricot Phase 2 upgrade time.

func (*ChainConfig) IsApricotPhase3 added in v0.9.0

func (c *ChainConfig) IsApricotPhase3(blockTimestamp *big.Int) bool

IsApricotPhase3 returns whether [blockTimestamp] represents a block with a timestamp after the Apricot Phase 3 upgrade time.

func (*ChainConfig) IsApricotPhase4 added in v0.9.0

func (c *ChainConfig) IsApricotPhase4(blockTimestamp *big.Int) bool

IsApricotPhase4 returns whether [blockTimestamp] represents a block with a timestamp after the Apricot Phase 4 upgrade time.

func (*ChainConfig) IsApricotPhase5 added in v0.9.0

func (c *ChainConfig) IsApricotPhase5(blockTimestamp *big.Int) bool

IsApricotPhase5 returns whether [blockTimestamp] represents a block with a timestamp after the Apricot Phase 5 upgrade time.

func (*ChainConfig) IsByzantium added in v0.9.0

func (c *ChainConfig) IsByzantium(num *big.Int) bool

IsByzantium returns whether num is either equal to the Byzantium fork block or greater.

func (*ChainConfig) IsConstantinople added in v0.9.0

func (c *ChainConfig) IsConstantinople(num *big.Int) bool

IsConstantinople returns whether num is either equal to the Constantinople fork block or greater.

func (*ChainConfig) IsDAOFork added in v0.9.0

func (c *ChainConfig) IsDAOFork(num *big.Int) bool

IsDAOFork returns whether num is either equal to the DAO fork block or greater.

func (*ChainConfig) IsEIP150 added in v0.9.0

func (c *ChainConfig) IsEIP150(num *big.Int) bool

IsEIP150 returns whether num is either equal to the EIP150 fork block or greater.

func (*ChainConfig) IsEIP155 added in v0.9.0

func (c *ChainConfig) IsEIP155(num *big.Int) bool

IsEIP155 returns whether num is either equal to the EIP155 fork block or greater.

func (*ChainConfig) IsEIP158 added in v0.9.0

func (c *ChainConfig) IsEIP158(num *big.Int) bool

IsEIP158 returns whether num is either equal to the EIP158 fork block or greater.

func (*ChainConfig) IsHomestead added in v0.9.0

func (c *ChainConfig) IsHomestead(num *big.Int) bool

IsHomestead returns whether num is either equal to the homestead block or greater.

func (*ChainConfig) IsIstanbul added in v0.9.0

func (c *ChainConfig) IsIstanbul(num *big.Int) bool

IsIstanbul returns whether num is either equal to the Istanbul fork block or greater.

func (*ChainConfig) IsMuirGlacier added in v0.9.0

func (c *ChainConfig) IsMuirGlacier(num *big.Int) bool

IsMuirGlacier returns whether num is either equal to the Muir Glacier (EIP-2384) fork block or greater.

func (*ChainConfig) IsPetersburg added in v0.9.0

func (c *ChainConfig) IsPetersburg(num *big.Int) bool

IsPetersburg returns whether num is either - equal to or greater than the PetersburgBlock fork block, - OR is nil, and Constantinople is active

func (*ChainConfig) String added in v0.9.0

func (c *ChainConfig) String() string

String implements the fmt.Stringer interface.

type ConfigCompatError added in v0.9.0

type ConfigCompatError struct {
	What string
	// block numbers of the stored and new configurations
	StoredConfig, NewConfig *big.Int
	// the block number to which the local chain must be rewound to correct the error
	RewindTo uint64
}

ConfigCompatError is raised if the locally-stored blockchain is initialised with a ChainConfig that would alter the past.

func (*ConfigCompatError) Error added in v0.9.0

func (err *ConfigCompatError) Error() string

type Rules added in v0.9.0

type Rules struct {
	ChainID                                                 *big.Int
	IsHomestead, IsEIP150, IsEIP155, IsEIP158               bool
	IsByzantium, IsConstantinople, IsPetersburg, IsIstanbul bool

	// Rules for Avalanche releases
	IsApricotPhase1, IsApricotPhase2, IsApricotPhase3, IsApricotPhase4, IsApricotPhase5 bool
}

Rules wraps ChainConfig and is merely syntactic sugar or can be used for functions that do not have or require information about the block.

Rules is a one time interface meaning that it shouldn't be used in between transition phases.

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