lbcd/chaincfg/params.go
Roy Lee 261f9be12e [lbry] chaincfg: update chainparams for LBRY chain
Co-authored-by: Brannon King <countprimes@gmail.com>
Co-authored-by: Alex Grintsvayg <grin@lbry.com>
2021-12-04 22:41:00 -08:00

854 lines
31 KiB
Go

// Copyright (c) 2014-2016 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package chaincfg
import (
"encoding/binary"
"encoding/hex"
"errors"
"math"
"math/big"
"strings"
"time"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/wire"
)
// These variables are the chain proof-of-work limit parameters for each default
// network.
var (
// bigOne is 1 represented as a big.Int. It is defined here to avoid
// the overhead of creating it multiple times.
bigOne = big.NewInt(1)
// mainPowLimit is the highest proof of work value a Bitcoin block can
// have for the main network. It is the value 2^240 - 1.
mainPowLimit = new(big.Int).Sub(new(big.Int).Lsh(bigOne, 240), bigOne)
// regressionPowLimit is the highest proof of work value a Bitcoin block
// can have for the regression test network. It is the value 2^255 - 1.
regressionPowLimit = new(big.Int).Sub(new(big.Int).Lsh(bigOne, 255), bigOne)
// testNet3PowLimit is the highest proof of work value a Bitcoin block
// can have for the test network (version 3). It is the value
// 2^240 - 1.
testNet3PowLimit = new(big.Int).Sub(new(big.Int).Lsh(bigOne, 240), bigOne)
// simNetPowLimit is the highest proof of work value a Bitcoin block
// can have for the simulation test network. It is the value 2^255 - 1.
simNetPowLimit = new(big.Int).Sub(new(big.Int).Lsh(bigOne, 255), bigOne)
// sigNetPowLimit is the highest proof of work value a bitcoin block can
// have for the signet test network. It is the value 0x0377ae << 216.
sigNetPowLimit = new(big.Int).Lsh(new(big.Int).SetInt64(0x0377ae), 216)
// DefaultSignetChallenge is the byte representation of the signet
// challenge for the default (public, Taproot enabled) signet network.
// This is the binary equivalent of the bitcoin script
// 1 03ad5e0edad18cb1f0fc0d28a3d4f1f3e445640337489abb10404f2d1e086be430
// 0359ef5021964fe22d6f8e05b2463c9540ce96883fe3b278760f048f5189f2e6c4 2
// OP_CHECKMULTISIG
DefaultSignetChallenge, _ = hex.DecodeString(
"512103ad5e0edad18cb1f0fc0d28a3d4f1f3e445640337489abb10404f2d" +
"1e086be430210359ef5021964fe22d6f8e05b2463c9540ce9688" +
"3fe3b278760f048f5189f2e6c452ae",
)
// DefaultSignetDNSSeeds is the list of seed nodes for the default
// (public, Taproot enabled) signet network.
DefaultSignetDNSSeeds = []DNSSeed{
{"178.128.221.177", false},
{"2a01:7c8:d005:390::5", false},
{"v7ajjeirttkbnt32wpy3c6w3emwnfr3fkla7hpxcfokr3ysd3kqtzmqd.onion:38333", false},
}
)
// Checkpoint identifies a known good point in the block chain. Using
// checkpoints allows a few optimizations for old blocks during initial download
// and also prevents forks from old blocks.
//
// Each checkpoint is selected based upon several factors. See the
// documentation for blockchain.IsCheckpointCandidate for details on the
// selection criteria.
type Checkpoint struct {
Height int32
Hash *chainhash.Hash
}
// DNSSeed identifies a DNS seed.
type DNSSeed struct {
// Host defines the hostname of the seed.
Host string
// HasFiltering defines whether the seed supports filtering
// by service flags (wire.ServiceFlag).
HasFiltering bool
}
// ConsensusDeployment defines details related to a specific consensus rule
// change that is voted in. This is part of BIP0009.
type ConsensusDeployment struct {
// BitNumber defines the specific bit number within the block version
// this particular soft-fork deployment refers to.
BitNumber uint8
// StartTime is the median block time after which voting on the
// deployment starts.
StartTime uint64
// ExpireTime is the median block time after which the attempted
// deployment expires.
ExpireTime uint64
// ForceActiveAt is added by LBRY to bypass consensus. Features are activated via hard-fork instead.
ForceActiveAt int32
}
// Constants that define the deployment offset in the deployments field of the
// parameters for each deployment. This is useful to be able to get the details
// of a specific deployment by name.
const (
// DeploymentTestDummy defines the rule change deployment ID for testing
// purposes.
DeploymentTestDummy = iota
// DeploymentCSV defines the rule change deployment ID for the CSV
// soft-fork package. The CSV package includes the deployment of BIPS
// 68, 112, and 113.
DeploymentCSV
// DeploymentSegwit defines the rule change deployment ID for the
// Segregated Witness (segwit) soft-fork package. The segwit package
// includes the deployment of BIPS 141, 142, 144, 145, 147 and 173.
DeploymentSegwit
// DeploymentTaproot defines the rule change deployment ID for the
// Taproot (+Schnorr) soft-fork package. The taproot package includes
// the deployment of BIPS 340, 341 and 342.
DeploymentTaproot
// NOTE: DefinedDeployments must always come last since it is used to
// determine how many defined deployments there currently are.
// DefinedDeployments is the number of currently defined deployments.
DefinedDeployments
)
// Params defines a Bitcoin network by its parameters. These parameters may be
// used by Bitcoin applications to differentiate networks as well as addresses
// and keys for one network from those intended for use on another network.
type Params struct {
// Name defines a human-readable identifier for the network.
Name string
// Net defines the magic bytes used to identify the network.
Net wire.BitcoinNet
// DefaultPort defines the default peer-to-peer port for the network.
DefaultPort string
// DNSSeeds defines a list of DNS seeds for the network that are used
// as one method to discover peers.
DNSSeeds []DNSSeed
// GenesisBlock defines the first block of the chain.
GenesisBlock *wire.MsgBlock
// GenesisHash is the starting block hash.
GenesisHash *chainhash.Hash
// PowLimit defines the highest allowed proof of work value for a block
// as a uint256.
PowLimit *big.Int
// PowLimitBits defines the highest allowed proof of work value for a
// block in compact form.
PowLimitBits uint32
// These fields define the block heights at which the specified softfork
// BIP became active.
BIP0034Height int32
BIP0065Height int32
BIP0066Height int32
// CoinbaseMaturity is the number of blocks required before newly mined
// coins (coinbase transactions) can be spent.
CoinbaseMaturity uint16
// SubsidyReductionInterval is the interval of blocks before the subsidy
// is reduced.
SubsidyReductionInterval int32
// TargetTimespan is the desired amount of time that should elapse
// before the block difficulty requirement is examined to determine how
// it should be changed in order to maintain the desired block
// generation rate.
TargetTimespan time.Duration
// TargetTimePerBlock is the desired amount of time to generate each
// block.
TargetTimePerBlock time.Duration
// RetargetAdjustmentFactor is the adjustment factor used to limit
// the minimum and maximum amount of adjustment that can occur between
// difficulty retargets.
RetargetAdjustmentFactor int64
// ReduceMinDifficulty defines whether the network should reduce the
// minimum required difficulty after a long enough period of time has
// passed without finding a block. This is really only useful for test
// networks and should not be set on a main network.
ReduceMinDifficulty bool
// MinDiffReductionTime is the amount of time after which the minimum
// required difficulty should be reduced when a block hasn't been found.
//
// NOTE: This only applies if ReduceMinDifficulty is true.
MinDiffReductionTime time.Duration
// GenerateSupported specifies whether or not CPU mining is allowed.
GenerateSupported bool
// Checkpoints ordered from oldest to newest.
Checkpoints []Checkpoint
// These fields are related to voting on consensus rule changes as
// defined by BIP0009.
//
// RuleChangeActivationThreshold is the number of blocks in a threshold
// state retarget window for which a positive vote for a rule change
// must be cast in order to lock in a rule change. It should typically
// be 95% for the main network and 75% for test networks.
//
// MinerConfirmationWindow is the number of blocks in each threshold
// state retarget window.
//
// Deployments define the specific consensus rule changes to be voted
// on.
RuleChangeActivationThreshold uint32
MinerConfirmationWindow uint32
Deployments [DefinedDeployments]ConsensusDeployment
// Mempool parameters
RelayNonStdTxs bool
// Human-readable part for Bech32 encoded segwit addresses, as defined
// in BIP 173.
Bech32HRPSegwit string
// Address encoding magics
PubKeyHashAddrID byte // First byte of a P2PKH address
ScriptHashAddrID byte // First byte of a P2SH address
PrivateKeyID byte // First byte of a WIF private key
// BIP32 hierarchical deterministic extended key magics
HDPrivateKeyID [4]byte
HDPublicKeyID [4]byte
// BIP44 coin type used in the hierarchical deterministic path for
// address generation.
HDCoinType uint32
}
// MainNetParams defines the network parameters for the main Bitcoin network.
var MainNetParams = Params{
Name: "mainnet",
Net: wire.MainNet,
DefaultPort: "9246",
DNSSeeds: []DNSSeed{
{"dnsseed1.lbry.com", true},
{"dnsseed2.lbry.com", true},
{"dnsseed3.lbry.com", true},
{"seed.lbry.grin.io", true},
{"seed.allaboutlbc.com", true},
},
// Chain parameters
GenesisBlock: &genesisBlock,
GenesisHash: &genesisHash,
PowLimit: mainPowLimit,
PowLimitBits: 0x1f00ffff,
BIP0034Height: 1,
BIP0065Height: 200000,
BIP0066Height: 200000,
CoinbaseMaturity: 100,
SubsidyReductionInterval: 1 << 5,
TargetTimespan: time.Second * 150, // retarget every block
TargetTimePerBlock: time.Second * 150, // 150 seconds
RetargetAdjustmentFactor: 4, // 25% less, 400% more
ReduceMinDifficulty: false,
MinDiffReductionTime: 0,
GenerateSupported: false,
// Checkpoints ordered from oldest to newest.
Checkpoints: []Checkpoint{
{40000, newHashFromStr("4c55584b068108b15c0066a010d11971aa92f46b0a73d479f1b7fa57df8b05f4")},
{80000, newHashFromStr("6e9facdfb87ba8394a46c61a7c093f7f00b1397a2dabc6a04f2911e0efdcf50a")},
{120000, newHashFromStr("6a9dba420ec544b927769765dccec8b29e214e6ca9f82b54a52bf20ca517b75a")},
{160000, newHashFromStr("87b2913a509d857401f7587903c90214db7847af1a1ad63a3b6f245936e3ae9d")},
{200000, newHashFromStr("0fe8ed6019a83028006435e47be4e37a0d3ed48019cde1dc7ede6562e5829839")},
{240000, newHashFromStr("cb3c2342afbe7291012f2288403a9d105f46987f78b279d516db2deb4d35b0b7")},
{280000, newHashFromStr("9835d03eb527ea4ce45c217350c68042926d497c21fb31413b2f7824ff6fc6c3")},
{320000, newHashFromStr("ad80c7cb91ca1d9c9b7bf68ca1b6d4ba217fe25ca5ded6a7e8acbaba663b143f")},
{360000, newHashFromStr("f9fd013252439663c1e729a8afb27187a8b9cc63a253336060f867e3cfbe4dcb")},
{400000, newHashFromStr("f0e56e70782af63ccb49c76e852540688755869ba59ec68cac9c04a6b4d9f5ca")},
{440000, newHashFromStr("52760e00c369b40781a2ced32836711fab82a720fafb121118c815bb46afd996")},
{480000, newHashFromStr("cecacaf4d1a8d1ef60da39343540781115abb91f5f0c976bb08afc4d4e3218ac")},
{520000, newHashFromStr("fa5e9d6dcf9ad57ba60d8ba26fb05585741098d10f42ed9d5e6b5e90ebc278d6")},
{560000, newHashFromStr("95c6229bd9b40f03a8426b2fec740026b3f06b1628cfb87527b0cbd0da328c0c")},
{600000, newHashFromStr("532657a97d480feb2d0423bb736cbfd7400b3ac8311e81ac749a2f29103a6c6b")},
{640000, newHashFromStr("68b69e3e8765e1ddbac63cbfbbf12e1a920da994d242a26fd07624f067743080")},
{680000, newHashFromStr("7b9f30c959405b5b96d0b0c2ba8fc7c5586cd0ce40df51427de4b8a217859c45")},
{720000, newHashFromStr("42084d5f88c71c0ae09b8677070969df9c3ef875c5f434133f552d863204f0cb")},
{760000, newHashFromStr("1887cd8b50375a9ac0dc9686c98fa8ac69bca618eab6254310647057f6fe4fc9")},
{800000, newHashFromStr("d34bb871b21e6fda4bd9d9e530ebf12e044814004007f088415035c651ecf322")},
{840000, newHashFromStr("d0e73c5ce3ad5d6fdb4483aa450f0b1cf7e4570987ee3a3806ace4ad2f7cc9af")},
{880000, newHashFromStr("806a95f26bab603f1d9132b5d4ea72aab9d1198ad55ae18dac1e149f6cb70ce4")},
{920000, newHashFromStr("83bc84555105436c51728ab200e8da4d9b3a365fd3d1d47a60048ad0f977c55b")},
{960000, newHashFromStr("60e37b1c2d1f8771290b7f84865cbadf22b5b89d3ce1201d454b09f0775b42c2")},
},
// Consensus rule change deployments.
//
// The miner confirmation window is defined as:
// target proof of work timespan / target proof of work spacing
RuleChangeActivationThreshold: 1916, // 95% of MinerConfirmationWindow
MinerConfirmationWindow: 2016, //
Deployments: [DefinedDeployments]ConsensusDeployment{
DeploymentTestDummy: {
BitNumber: 28,
StartTime: 1199145601, // January 1, 2008 UTC
ExpireTime: 1230767999, // December 31, 2008 UTC
},
DeploymentCSV: {
BitNumber: 0,
StartTime: 1462060800, // May 1st, 2016
ExpireTime: 1493596800, // May 1st, 2017
ForceActiveAt: 200000,
},
DeploymentSegwit: {
BitNumber: 1,
StartTime: 1547942400, // Jan 20, 2019
ExpireTime: 1548288000, // Jan 24, 2019
ForceActiveAt: 680770,
},
},
// Mempool parameters
RelayNonStdTxs: false,
// Human-readable part for Bech32 encoded segwit addresses, as defined in
// BIP 173.
Bech32HRPSegwit: "lbc",
// Address encoding magics
PubKeyHashAddrID: 0x55,
ScriptHashAddrID: 0x7a,
PrivateKeyID: 0x1c,
// BIP32 hierarchical deterministic extended key magics
HDPrivateKeyID: [4]byte{0x04, 0x88, 0xad, 0xe4},
HDPublicKeyID: [4]byte{0x04, 0x88, 0xb2, 0x1e},
// BIP44 coin type used in the hierarchical deterministic path for
// address generation.
HDCoinType: 0,
}
// RegressionNetParams defines the network parameters for the regression test
// Bitcoin network. Not to be confused with the test Bitcoin network (version
// 3), this network is sometimes simply called "testnet".
var RegressionNetParams = Params{
Name: "regtest",
Net: wire.TestNet,
DefaultPort: "29246",
DNSSeeds: []DNSSeed{},
// Chain parameters
GenesisBlock: &regTestGenesisBlock,
GenesisHash: &regTestGenesisHash,
PowLimit: regressionPowLimit,
PowLimitBits: 0x207fffff,
CoinbaseMaturity: 100,
BIP0034Height: 1000,
BIP0065Height: 1351, // Used by regression tests
BIP0066Height: 1251, // Used by regression tests
SubsidyReductionInterval: 1 << 5,
TargetTimespan: time.Second,
TargetTimePerBlock: time.Second,
RetargetAdjustmentFactor: 4, // 25% less, 400% more
ReduceMinDifficulty: false,
MinDiffReductionTime: 0,
GenerateSupported: true,
// Checkpoints ordered from oldest to newest.
Checkpoints: nil,
// Consensus rule change deployments.
//
// The miner confirmation window is defined as:
// target proof of work timespan / target proof of work spacing
RuleChangeActivationThreshold: 108, // 75% of MinerConfirmationWindow
MinerConfirmationWindow: 144,
Deployments: [DefinedDeployments]ConsensusDeployment{
DeploymentTestDummy: {
BitNumber: 28,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires
},
DeploymentCSV: {
BitNumber: 0,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires
ForceActiveAt: 1,
},
DeploymentSegwit: {
BitNumber: 1,
StartTime: 0,
ExpireTime: math.MaxInt64,
ForceActiveAt: 150,
},
},
// Mempool parameters
RelayNonStdTxs: true,
// Human-readable part for Bech32 encoded segwit addresses, as defined in
// BIP 173.
Bech32HRPSegwit: "rlbc",
// Address encoding magics
PubKeyHashAddrID: 111, // starts with m or n
ScriptHashAddrID: 196, // starts with 2
PrivateKeyID: 239, // starts with 9 (uncompressed) or c (compressed)
// BIP32 hierarchical deterministic extended key magics
HDPrivateKeyID: [4]byte{0x04, 0x35, 0x83, 0x94}, // starts with tprv
HDPublicKeyID: [4]byte{0x04, 0x35, 0x87, 0xcf}, // starts with tpub
// BIP44 coin type used in the hierarchical deterministic path for
// address generation.
HDCoinType: 1,
}
// TestNet3Params defines the network parameters for the test Bitcoin network
// (version 3). Not to be confused with the regression test network, this
// network is sometimes simply called "testnet".
var TestNet3Params = Params{
Name: "testnet3",
Net: wire.TestNet3,
DefaultPort: "19246",
DNSSeeds: []DNSSeed{
{"testdnsseed1.lbry.com", true},
{"testdnsseed2.lbry.com", true},
},
// Chain parameters
GenesisBlock: &testNet3GenesisBlock,
GenesisHash: &testNet3GenesisHash,
PowLimit: testNet3PowLimit,
PowLimitBits: 0x1f00ffff,
BIP0034Height: 21111, // 0x0000000023b3a96d3484e5abb3755c413e7d41500f8e2a5c3f0dd01299cd8ef8
BIP0065Height: 1200000,
BIP0066Height: 1200000,
CoinbaseMaturity: 100,
SubsidyReductionInterval: 1 << 5,
TargetTimespan: time.Second * 150, // retarget every block
TargetTimePerBlock: time.Second * 150, // 150 seconds
RetargetAdjustmentFactor: 4, // 25% less, 400% more
ReduceMinDifficulty: false,
MinDiffReductionTime: 0,
GenerateSupported: true,
// Checkpoints ordered from oldest to newest.
Checkpoints: []Checkpoint{},
// Consensus rule change deployments.
//
// The miner confirmation window is defined as:
// target proof of work timespan / target proof of work spacing
RuleChangeActivationThreshold: 1512, // 75% of MinerConfirmationWindow
MinerConfirmationWindow: 2016,
Deployments: [DefinedDeployments]ConsensusDeployment{
DeploymentTestDummy: {
BitNumber: 28,
StartTime: 1199145601, // January 1, 2008 UTC
ExpireTime: 1230767999, // December 31, 2008 UTC
},
DeploymentCSV: {
BitNumber: 0,
StartTime: 1456790400, // March 1st, 2016
ExpireTime: 1493596800, // May 1st, 2017
},
DeploymentSegwit: {
BitNumber: 1,
StartTime: 1462060800, // May 1st 2016
ExpireTime: 1493596800, // May 1st 2017
ForceActiveAt: 1198600,
},
},
// Mempool parameters
RelayNonStdTxs: true,
// Human-readable part for Bech32 encoded segwit addresses, as defined in
// BIP 173.
Bech32HRPSegwit: "tlbc",
// Address encoding magics
PubKeyHashAddrID: 111,
ScriptHashAddrID: 196,
PrivateKeyID: 239,
// BIP32 hierarchical deterministic extended key magics
HDPrivateKeyID: [4]byte{0x04, 0x35, 0x83, 0x94}, // starts with tprv
HDPublicKeyID: [4]byte{0x04, 0x35, 0x87, 0xcf}, // starts with tpub
// BIP44 coin type used in the hierarchical deterministic path for
// address generation.
HDCoinType: 1,
}
// SimNetParams defines the network parameters for the simulation test Bitcoin
// network. This network is similar to the normal test network except it is
// intended for private use within a group of individuals doing simulation
// testing. The functionality is intended to differ in that the only nodes
// which are specifically specified are used to create the network rather than
// following normal discovery rules. This is important as otherwise it would
// just turn into another public testnet.
var SimNetParams = Params{
Name: "simnet",
Net: wire.SimNet,
DefaultPort: "18555",
DNSSeeds: []DNSSeed{}, // NOTE: There must NOT be any seeds.
// Chain parameters
GenesisBlock: &simNetGenesisBlock,
GenesisHash: &simNetGenesisHash,
PowLimit: simNetPowLimit,
PowLimitBits: 0x207fffff,
BIP0034Height: 0, // Always active on simnet
BIP0065Height: 0, // Always active on simnet
BIP0066Height: 0, // Always active on simnet
CoinbaseMaturity: 100,
SubsidyReductionInterval: 210000,
TargetTimespan: time.Second * 150,
TargetTimePerBlock: time.Second * 150,
RetargetAdjustmentFactor: 4, // 25% less, 400% more
ReduceMinDifficulty: true,
MinDiffReductionTime: 0,
GenerateSupported: true,
// Checkpoints ordered from oldest to newest.
Checkpoints: nil,
// Consensus rule change deployments.
//
// The miner confirmation window is defined as:
// target proof of work timespan / target proof of work spacing
RuleChangeActivationThreshold: 75, // 75% of MinerConfirmationWindow
MinerConfirmationWindow: 100,
Deployments: [DefinedDeployments]ConsensusDeployment{
DeploymentTestDummy: {
BitNumber: 28,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires
},
DeploymentCSV: {
BitNumber: 0,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires
},
DeploymentSegwit: {
BitNumber: 1,
StartTime: 0,
ExpireTime: math.MaxInt64,
},
},
// Mempool parameters
RelayNonStdTxs: true,
// Human-readable part for Bech32 encoded segwit addresses, as defined in
// BIP 173.
Bech32HRPSegwit: "slbc",
// Address encoding magics
PubKeyHashAddrID: 111,
ScriptHashAddrID: 196,
PrivateKeyID: 239,
// BIP32 hierarchical deterministic extended key magics
HDPrivateKeyID: [4]byte{0x04, 0x20, 0xb9, 0x00}, // starts with sprv
HDPublicKeyID: [4]byte{0x04, 0x20, 0xbd, 0x3a}, // starts with spub
// BIP44 coin type used in the hierarchical deterministic path for
// address generation.
HDCoinType: 115, // ASCII for s
}
// SigNetParams defines the network parameters for the default public signet
// Bitcoin network. Not to be confused with the regression test network, this
// network is sometimes simply called "signet" or "taproot signet".
var SigNetParams = CustomSignetParams(
DefaultSignetChallenge, DefaultSignetDNSSeeds,
)
// CustomSignetParams creates network parameters for a custom signet network
// from a challenge. The challenge is the binary compiled version of the block
// challenge script.
func CustomSignetParams(challenge []byte, dnsSeeds []DNSSeed) Params {
// The message start is defined as the first four bytes of the sha256d
// of the challenge script, as a single push (i.e. prefixed with the
// challenge script length).
challengeLength := byte(len(challenge))
hashDouble := chainhash.DoubleHashB(
append([]byte{challengeLength}, challenge...),
)
// We use little endian encoding of the hash prefix to be in line with
// the other wire network identities.
net := binary.LittleEndian.Uint32(hashDouble[0:4])
return Params{
Name: "signet",
Net: wire.BitcoinNet(net),
DefaultPort: "38333",
DNSSeeds: dnsSeeds,
// Chain parameters
GenesisBlock: &sigNetGenesisBlock,
GenesisHash: &sigNetGenesisHash,
PowLimit: sigNetPowLimit,
PowLimitBits: 0x1e0377ae,
BIP0034Height: 1,
BIP0065Height: 1,
BIP0066Height: 1,
CoinbaseMaturity: 100,
SubsidyReductionInterval: 210000,
TargetTimespan: time.Hour * 24 * 14, // 14 days
TargetTimePerBlock: time.Minute * 10, // 10 minutes
RetargetAdjustmentFactor: 4, // 25% less, 400% more
ReduceMinDifficulty: false,
MinDiffReductionTime: time.Minute * 20, // TargetTimePerBlock * 2
GenerateSupported: false,
// Checkpoints ordered from oldest to newest.
Checkpoints: nil,
// Consensus rule change deployments.
//
// The miner confirmation window is defined as:
// target proof of work timespan / target proof of work spacing
RuleChangeActivationThreshold: 1916, // 95% of 2016
MinerConfirmationWindow: 2016,
Deployments: [DefinedDeployments]ConsensusDeployment{
DeploymentTestDummy: {
BitNumber: 28,
StartTime: 1199145601, // January 1, 2008 UTC
ExpireTime: 1230767999, // December 31, 2008 UTC
},
DeploymentCSV: {
BitNumber: 29,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires
},
DeploymentSegwit: {
BitNumber: 29,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires.
},
DeploymentTaproot: {
BitNumber: 29,
StartTime: 0, // Always available for vote
ExpireTime: math.MaxInt64, // Never expires.
},
},
// Mempool parameters
RelayNonStdTxs: false,
// Human-readable part for Bech32 encoded segwit addresses, as defined in
// BIP 173.
Bech32HRPSegwit: "slbc",
// Address encoding magics
PubKeyHashAddrID: 0x6f, // starts with m or n
ScriptHashAddrID: 0xc4, // starts with 2
PrivateKeyID: 0xef, // starts with 9 (uncompressed) or c (compressed)
// BIP32 hierarchical deterministic extended key magics
HDPrivateKeyID: [4]byte{0x04, 0x35, 0x83, 0x94}, // starts with tprv
HDPublicKeyID: [4]byte{0x04, 0x35, 0x87, 0xcf}, // starts with tpub
// BIP44 coin type used in the hierarchical deterministic path for
// address generation.
HDCoinType: 1,
}
}
var (
// ErrDuplicateNet describes an error where the parameters for a Bitcoin
// network could not be set due to the network already being a standard
// network or previously-registered into this package.
ErrDuplicateNet = errors.New("duplicate Bitcoin network")
// ErrUnknownHDKeyID describes an error where the provided id which
// is intended to identify the network for a hierarchical deterministic
// private extended key is not registered.
ErrUnknownHDKeyID = errors.New("unknown hd private extended key bytes")
// ErrInvalidHDKeyID describes an error where the provided hierarchical
// deterministic version bytes, or hd key id, is malformed.
ErrInvalidHDKeyID = errors.New("invalid hd extended key version bytes")
)
var (
registeredNets = make(map[wire.BitcoinNet]struct{})
pubKeyHashAddrIDs = make(map[byte]struct{})
scriptHashAddrIDs = make(map[byte]struct{})
bech32SegwitPrefixes = make(map[string]struct{})
hdPrivToPubKeyIDs = make(map[[4]byte][]byte)
)
// String returns the hostname of the DNS seed in human-readable form.
func (d DNSSeed) String() string {
return d.Host
}
// Register registers the network parameters for a Bitcoin network. This may
// error with ErrDuplicateNet if the network is already registered (either
// due to a previous Register call, or the network being one of the default
// networks).
//
// Network parameters should be registered into this package by a main package
// as early as possible. Then, library packages may lookup networks or network
// parameters based on inputs and work regardless of the network being standard
// or not.
func Register(params *Params) error {
if _, ok := registeredNets[params.Net]; ok {
return ErrDuplicateNet
}
registeredNets[params.Net] = struct{}{}
pubKeyHashAddrIDs[params.PubKeyHashAddrID] = struct{}{}
scriptHashAddrIDs[params.ScriptHashAddrID] = struct{}{}
err := RegisterHDKeyID(params.HDPublicKeyID[:], params.HDPrivateKeyID[:])
if err != nil {
return err
}
// A valid Bech32 encoded segwit address always has as prefix the
// human-readable part for the given net followed by '1'.
bech32SegwitPrefixes[params.Bech32HRPSegwit+"1"] = struct{}{}
return nil
}
// mustRegister performs the same function as Register except it panics if there
// is an error. This should only be called from package init functions.
func mustRegister(params *Params) {
if err := Register(params); err != nil {
panic("failed to register network: " + err.Error())
}
}
// IsPubKeyHashAddrID returns whether the id is an identifier known to prefix a
// pay-to-pubkey-hash address on any default or registered network. This is
// used when decoding an address string into a specific address type. It is up
// to the caller to check both this and IsScriptHashAddrID and decide whether an
// address is a pubkey hash address, script hash address, neither, or
// undeterminable (if both return true).
func IsPubKeyHashAddrID(id byte) bool {
_, ok := pubKeyHashAddrIDs[id]
return ok
}
// IsScriptHashAddrID returns whether the id is an identifier known to prefix a
// pay-to-script-hash address on any default or registered network. This is
// used when decoding an address string into a specific address type. It is up
// to the caller to check both this and IsPubKeyHashAddrID and decide whether an
// address is a pubkey hash address, script hash address, neither, or
// undeterminable (if both return true).
func IsScriptHashAddrID(id byte) bool {
_, ok := scriptHashAddrIDs[id]
return ok
}
// IsBech32SegwitPrefix returns whether the prefix is a known prefix for segwit
// addresses on any default or registered network. This is used when decoding
// an address string into a specific address type.
func IsBech32SegwitPrefix(prefix string) bool {
prefix = strings.ToLower(prefix)
_, ok := bech32SegwitPrefixes[prefix]
return ok
}
// RegisterHDKeyID registers a public and private hierarchical deterministic
// extended key ID pair.
//
// Non-standard HD version bytes, such as the ones documented in SLIP-0132,
// should be registered using this method for library packages to lookup key
// IDs (aka HD version bytes). When the provided key IDs are invalid, the
// ErrInvalidHDKeyID error will be returned.
//
// Reference:
// SLIP-0132 : Registered HD version bytes for BIP-0032
// https://github.com/satoshilabs/slips/blob/master/slip-0132.md
func RegisterHDKeyID(hdPublicKeyID []byte, hdPrivateKeyID []byte) error {
if len(hdPublicKeyID) != 4 || len(hdPrivateKeyID) != 4 {
return ErrInvalidHDKeyID
}
var keyID [4]byte
copy(keyID[:], hdPrivateKeyID)
hdPrivToPubKeyIDs[keyID] = hdPublicKeyID
return nil
}
// HDPrivateKeyToPublicKeyID accepts a private hierarchical deterministic
// extended key id and returns the associated public key id. When the provided
// id is not registered, the ErrUnknownHDKeyID error will be returned.
func HDPrivateKeyToPublicKeyID(id []byte) ([]byte, error) {
if len(id) != 4 {
return nil, ErrUnknownHDKeyID
}
var key [4]byte
copy(key[:], id)
pubBytes, ok := hdPrivToPubKeyIDs[key]
if !ok {
return nil, ErrUnknownHDKeyID
}
return pubBytes, nil
}
// newHashFromStr converts the passed big-endian hex string into a
// chainhash.Hash. It only differs from the one available in chainhash in that
// it panics on an error since it will only (and must only) be called with
// hard-coded, and therefore known good, hashes.
func newHashFromStr(hexStr string) *chainhash.Hash {
hash, err := chainhash.NewHashFromStr(hexStr)
if err != nil {
// Ordinarily I don't like panics in library code since it
// can take applications down without them having a chance to
// recover which is extremely annoying, however an exception is
// being made in this case because the only way this can panic
// is if there is an error in the hard-coded hashes. Thus it
// will only ever potentially panic on init and therefore is
// 100% predictable.
panic(err)
}
return hash
}
func init() {
// Register all default networks when the package is initialized.
mustRegister(&MainNetParams)
mustRegister(&TestNet3Params)
mustRegister(&RegressionNetParams)
mustRegister(&SimNetParams)
}