wire

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Published: May 10, 2024 License: ISC Imports: 19 Imported by: 21

README

wire

Build Status ISC License GoDoc

Package wire implements the litecoin wire protocol. A comprehensive suite of tests with 100% test coverage is provided to ensure proper functionality.

There is an associated blog post about the release of this package here.

This package has intentionally been designed so it can be used as a standalone package for any projects needing to interface with litecoin peers at the wire protocol level.

Installation and Updating

$ go get -u github.com/ltcmweb/ltcd/wire

Litecoin Message Overview

The litecoin protocol consists of exchanging messages between peers. Each message is preceded by a header which identifies information about it such as which litecoin network it is a part of, its type, how big it is, and a checksum to verify validity. All encoding and decoding of message headers is handled by this package.

To accomplish this, there is a generic interface for litecoin messages named Message which allows messages of any type to be read, written, or passed around through channels, functions, etc. In addition, concrete implementations of most of the currently supported litecoin messages are provided. For these supported messages, all of the details of marshalling and unmarshalling to and from the wire using litecoin encoding are handled so the caller doesn't have to concern themselves with the specifics.

Reading Messages Example

In order to unmarshal litecoin messages from the wire, use the ReadMessage function. It accepts any io.Reader, but typically this will be a net.Conn to a remote node running a litecoin peer. Example syntax is:

	// Use the most recent protocol version supported by the package and the
	// main litecoin network.
	pver := wire.ProtocolVersion
	btcnet := wire.MainNet

	// Reads and validates the next litecoin message from conn using the
	// protocol version pver and the litecoin network btcnet.  The returns
	// are a wire.Message, a []byte which contains the unmarshalled
	// raw payload, and a possible error.
	msg, rawPayload, err := wire.ReadMessage(conn, pver, btcnet)
	if err != nil {
		// Log and handle the error
	}

See the package documentation for details on determining the message type.

Writing Messages Example

In order to marshal litecoin messages to the wire, use the WriteMessage function. It accepts any io.Writer, but typically this will be a net.Conn to a remote node running a litecoin peer. Example syntax to request addresses from a remote peer is:

	// Use the most recent protocol version supported by the package and the
	// main litecoin network.
	pver := wire.ProtocolVersion
	btcnet := wire.MainNet

	// Create a new getaddr litecoin message.
	msg := wire.NewMsgGetAddr()

	// Writes a litecoin message msg to conn using the protocol version
	// pver, and the litecoin network btcnet.  The return is a possible
	// error.
	err := wire.WriteMessage(conn, msg, pver, btcnet)
	if err != nil {
		// Log and handle the error
	}

GPG Verification Key

All official release tags are signed by Conformal so users can ensure the code has not been tampered with and is coming from the ltcsuite developers. To verify the signature perform the following:

  • Download the public key from the Conformal website at https://opensource.conformal.com/GIT-GPG-KEY-conformal.txt

  • Import the public key into your GPG keyring:

    gpg --import GIT-GPG-KEY-conformal.txt
    
  • Verify the release tag with the following command where TAG_NAME is a placeholder for the specific tag:

    git tag -v TAG_NAME
    

License

Package wire is licensed under the copyfree ISC License.

Documentation

Overview

Package wire implements the litecoin wire protocol.

For the complete details of the litecoin protocol, see the official wiki entry at https://en.bitcoin.it/wiki/Protocol_specification. The following only serves as a quick overview to provide information on how to use the package.

At a high level, this package provides support for marshalling and unmarshalling supported litecoin messages to and from the wire. This package does not deal with the specifics of message handling such as what to do when a message is received. This provides the caller with a high level of flexibility.

Litecoin Message Overview

The litecoin protocol consists of exchanging messages between peers. Each message is preceded by a header which identifies information about it such as which litecoin network it is a part of, its type, how big it is, and a checksum to verify validity. All encoding and decoding of message headers is handled by this package.

To accomplish this, there is a generic interface for litecoin messages named Message which allows messages of any type to be read, written, or passed around through channels, functions, etc. In addition, concrete implementations of most of the currently supported litecoin messages are provided. For these supported messages, all of the details of marshalling and unmarshalling to and from the wire using litecoin encoding are handled so the caller doesn't have to concern themselves with the specifics.

Message Interaction

The following provides a quick summary of how the litecoin messages are intended to interact with one another. As stated above, these interactions are not directly handled by this package. For more in-depth details about the appropriate interactions, see the official litecoin protocol wiki entry at https://en.bitcoin.it/wiki/Protocol_specification.

The initial handshake consists of two peers sending each other a version message (MsgVersion) followed by responding with a verack message (MsgVerAck). Both peers use the information in the version message (MsgVersion) to negotiate things such as protocol version and supported services with each other. Once the initial handshake is complete, the following chart indicates message interactions in no particular order.

Peer A Sends                          Peer B Responds
----------------------------------------------------------------------------
getaddr message (MsgGetAddr)          addr message (MsgAddr)
getblocks message (MsgGetBlocks)      inv message (MsgInv)
inv message (MsgInv)                  getdata message (MsgGetData)
getdata message (MsgGetData)          block message (MsgBlock) -or-
                                      tx message (MsgTx) -or-
                                      notfound message (MsgNotFound)
getheaders message (MsgGetHeaders)    headers message (MsgHeaders)
ping message (MsgPing)                pong message (MsgHeaders)* -or-
                                      (none -- Ability to send message is enough)

NOTES:
* The pong message was not added until later protocol versions as defined
  in BIP0031.  The BIP0031Version constant can be used to detect a recent
  enough protocol version for this purpose (version > BIP0031Version).

Common Parameters

There are several common parameters that arise when using this package to read and write litecoin messages. The following sections provide a quick overview of these parameters so the next sections can build on them.

Protocol Version

The protocol version should be negotiated with the remote peer at a higher level than this package via the version (MsgVersion) message exchange, however, this package provides the wire.ProtocolVersion constant which indicates the latest protocol version this package supports and is typically the value to use for all outbound connections before a potentially lower protocol version is negotiated.

Litecoin Network

The litecoin network is a magic number which is used to identify the start of a message and which litecoin network the message applies to. This package provides the following constants:

wire.MainNet
wire.TestNet  (Regression test network)
wire.TestNet4 (Test network version 4)
wire.SimNet   (Simulation test network)

Determining Message Type

As discussed in the litecoin message overview section, this package reads and writes litecoin messages using a generic interface named Message. In order to determine the actual concrete type of the message, use a type switch or type assertion. An example of a type switch follows:

// Assumes msg is already a valid concrete message such as one created
// via NewMsgVersion or read via ReadMessage.
switch msg := msg.(type) {
case *wire.MsgVersion:
	// The message is a pointer to a MsgVersion struct.
	fmt.Printf("Protocol version: %v", msg.ProtocolVersion)
case *wire.MsgBlock:
	// The message is a pointer to a MsgBlock struct.
	fmt.Printf("Number of tx in block: %v", msg.Header.TxnCount)
}

Reading Messages

In order to unmarshall litecoin messages from the wire, use the ReadMessage function. It accepts any io.Reader, but typically this will be a net.Conn to a remote node running a litecoin peer. Example syntax is:

// Reads and validates the next litecoin message from conn using the
// protocol version pver and the litecoin network btcnet.  The returns
// are a wire.Message, a []byte which contains the unmarshalled
// raw payload, and a possible error.
msg, rawPayload, err := wire.ReadMessage(conn, pver, btcnet)
if err != nil {
	// Log and handle the error
}

Writing Messages

In order to marshall litecoin messages to the wire, use the WriteMessage function. It accepts any io.Writer, but typically this will be a net.Conn to a remote node running a litecoin peer. Example syntax to request addresses from a remote peer is:

// Create a new getaddr litecoin message.
msg := wire.NewMsgGetAddr()

// Writes a litecoin message msg to conn using the protocol version
// pver, and the litecoin network btcnet.  The return is a possible
// error.
err := wire.WriteMessage(conn, msg, pver, btcnet)
if err != nil {
	// Log and handle the error
}

Errors

Errors returned by this package are either the raw errors provided by underlying calls to read/write from streams such as io.EOF, io.ErrUnexpectedEOF, and io.ErrShortWrite, or of type wire.MessageError. This allows the caller to differentiate between general IO errors and malformed messages through type assertions.

Bitcoin Improvement Proposals

This package includes spec changes outlined by the following BIPs:

BIP0014 (https://github.com/bitcoin/bips/blob/master/bip-0014.mediawiki)
BIP0031 (https://github.com/bitcoin/bips/blob/master/bip-0031.mediawiki)
BIP0035 (https://github.com/bitcoin/bips/blob/master/bip-0035.mediawiki)
BIP0037 (https://github.com/bitcoin/bips/blob/master/bip-0037.mediawiki)
BIP0111	(https://github.com/bitcoin/bips/blob/master/bip-0111.mediawiki)
BIP0130 (https://github.com/bitcoin/bips/blob/master/bip-0130.mediawiki)
BIP0133 (https://github.com/bitcoin/bips/blob/master/bip-0133.mediawiki)

Index

Constants

View Source
const (
	// MaxInvPerMsg is the maximum number of inventory vectors that can be in a
	// single litecoin inv message.
	MaxInvPerMsg = 50000

	// InvWitnessFlag denotes that the inventory vector type is requesting,
	// or sending a version which includes witness data.
	InvWitnessFlag = 1 << 30

	// InvMwebFlag denotes that the inventory vector type is requesting,
	// or sending a version which includes MWEB data.
	InvMwebFlag = 1 << 29
)
View Source
const (
	CmdVersion      = "version"
	CmdVerAck       = "verack"
	CmdGetAddr      = "getaddr"
	CmdAddr         = "addr"
	CmdAddrV2       = "addrv2"
	CmdGetBlocks    = "getblocks"
	CmdInv          = "inv"
	CmdGetData      = "getdata"
	CmdNotFound     = "notfound"
	CmdBlock        = "block"
	CmdTx           = "tx"
	CmdGetHeaders   = "getheaders"
	CmdHeaders      = "headers"
	CmdPing         = "ping"
	CmdPong         = "pong"
	CmdAlert        = "alert"
	CmdMemPool      = "mempool"
	CmdFilterAdd    = "filteradd"
	CmdFilterClear  = "filterclear"
	CmdFilterLoad   = "filterload"
	CmdMerkleBlock  = "merkleblock"
	CmdReject       = "reject"
	CmdSendHeaders  = "sendheaders"
	CmdFeeFilter    = "feefilter"
	CmdGetCFilters  = "getcfilters"
	CmdGetCFHeaders = "getcfheaders"
	CmdGetCFCheckpt = "getcfcheckpt"
	CmdCFilter      = "cfilter"
	CmdCFHeaders    = "cfheaders"
	CmdCFCheckpt    = "cfcheckpt"
	CmdSendAddrV2   = "sendaddrv2"
	CmdMwebHeader   = "mwebheader"
	CmdMwebLeafset  = "mwebleafset"
	CmdGetMwebUtxos = "getmwebutxos"
	CmdMwebUtxos    = "mwebutxos"
)

Commands used in litecoin message headers which describe the type of message.

View Source
const (
	// MaxCFHeaderPayload is the maximum byte size of a committed
	// filter header.
	MaxCFHeaderPayload = chainhash.HashSize

	// MaxCFHeadersPerMsg is the maximum number of committed filter headers
	// that can be in a single litecoin cfheaders message.
	MaxCFHeadersPerMsg = 2000
)
View Source
const (
	// MaxFilterLoadHashFuncs is the maximum number of hash functions to
	// load into the Bloom filter.
	MaxFilterLoadHashFuncs = 50

	// MaxFilterLoadFilterSize is the maximum size in bytes a filter may be.
	MaxFilterLoadFilterSize = 36000
)
View Source
const (
	// TxVersion is the current latest supported transaction version.
	TxVersion = 1

	// MaxTxInSequenceNum is the maximum sequence number the sequence field
	// of a transaction input can be.
	MaxTxInSequenceNum uint32 = 0xffffffff

	// MaxPrevOutIndex is the maximum index the index field of a previous
	// outpoint can be.
	MaxPrevOutIndex uint32 = 0xffffffff

	// SequenceLockTimeDisabled is a flag that if set on a transaction
	// input's sequence number, the sequence number will not be interpreted
	// as a relative locktime.
	SequenceLockTimeDisabled = 1 << 31

	// SequenceLockTimeIsSeconds is a flag that if set on a transaction
	// input's sequence number, the relative locktime has units of 512
	// seconds.
	SequenceLockTimeIsSeconds = 1 << 22

	// SequenceLockTimeMask is a mask that extracts the relative locktime
	// when masked against the transaction input sequence number.
	SequenceLockTimeMask = 0x0000ffff

	// SequenceLockTimeGranularity is the defined time based granularity
	// for seconds-based relative time locks. When converting from seconds
	// to a sequence number, the value is right shifted by this amount,
	// therefore the granularity of relative time locks in 512 or 2^9
	// seconds. Enforced relative lock times are multiples of 512 seconds.
	SequenceLockTimeGranularity = 9

	// MinTxOutPayload is the minimum payload size for a transaction output.
	// Value 8 bytes + Varint for PkScript length 1 byte.
	MinTxOutPayload = 9
)
View Source
const (
	// TorV2EncodedSize is the size of a torv2 address encoded in base32
	// with the ".onion" suffix.
	TorV2EncodedSize = 22

	// TorV3EncodedSize is the size of a torv3 address encoded in base32
	// with the ".onion" suffix.
	TorV3EncodedSize = 62
)
View Source
const (
	// ProtocolVersion is the latest protocol version this package supports.
	ProtocolVersion uint32 = 70016

	// MultipleAddressVersion is the protocol version which added multiple
	// addresses per message (pver >= MultipleAddressVersion).
	MultipleAddressVersion uint32 = 209

	// NetAddressTimeVersion is the protocol version which added the
	// timestamp field (pver >= NetAddressTimeVersion).
	NetAddressTimeVersion uint32 = 31402

	// BIP0031Version is the protocol version AFTER which a pong message
	// and nonce field in ping were added (pver > BIP0031Version).
	BIP0031Version uint32 = 60000

	// BIP0035Version is the protocol version which added the mempool
	// message (pver >= BIP0035Version).
	BIP0035Version uint32 = 60002

	// BIP0037Version is the protocol version which added new connection
	// bloom filtering related messages and extended the version message
	// with a relay flag (pver >= BIP0037Version).
	BIP0037Version uint32 = 70001

	// RejectVersion is the protocol version which added a new reject
	// message.
	RejectVersion uint32 = 70002

	// BIP0111Version is the protocol version which added the SFNodeBloom
	// service flag.
	BIP0111Version uint32 = 70011

	// SendHeadersVersion is the protocol version which added a new
	// sendheaders message.
	SendHeadersVersion uint32 = 70012

	// FeeFilterVersion is the protocol version which added a new
	// feefilter message.
	FeeFilterVersion uint32 = 70013

	// AddrV2Version is the protocol version which added two new messages.
	// sendaddrv2 is sent during the version-verack handshake and signals
	// support for sending and receiving the addrv2 message. In the future,
	// new messages that occur during the version-verack handshake will not
	// come with a protocol version bump.
	AddrV2Version uint32 = 70016

	// MwebLightClientVersion is the protocol version which added four new messages.
	// These are getmwebutxos, mwebutxos, mwebheader and mwebleafset.
	MwebLightClientVersion uint32 = 70017
)

XXX pedro: we will probably need to bump this.

View Source
const (
	// SFNodeNetwork is a flag used to indicate a peer is a full node.
	SFNodeNetwork ServiceFlag = 1 << iota

	// SFNodeGetUTXO is a flag used to indicate a peer supports the
	// getutxos and utxos commands (BIP0064).
	SFNodeGetUTXO

	// SFNodeBloom is a flag used to indicate a peer supports bloom
	// filtering.
	SFNodeBloom

	// SFNodeWitness is a flag used to indicate a peer supports blocks
	// and transactions including witness data (BIP0144).
	SFNodeWitness

	// SFNodeCF is a flag used to indicate a peer supports committed
	// filters (CFs).
	SFNodeCF = 1 << 6

	// SFNodeNetworkLimited is a flag used to indicate a peer supports serving
	// the last 288 blocks.
	SFNodeNetworkLimited = 1 << 10

	// SFNodeMWEBLightClient is a flag used to indicate a peer supports
	// serving MWEB light client data.
	SFNodeMWEBLightClient = 1 << 23

	// SFNodeMWEB is a flag used to indicate a peer support MWEB blocks.
	SFNodeMWEB = 1 << 24
)
View Source
const (
	// CFCheckptInterval is the gap (in number of blocks) between each
	// filter header checkpoint.
	CFCheckptInterval = 1000
)
View Source
const CommandSize = 12

CommandSize is the fixed size of all commands in the common litecoin message header. Shorter commands must be zero padded.

View Source
const DefaultUserAgent = "/ltcwire:0.5.0/"

DefaultUserAgent for wire in the stack

View Source
const MaxAddrPerMsg = 1000

MaxAddrPerMsg is the maximum number of addresses that can be in a single litecoin addr message (MsgAddr).

View Source
const MaxBlockHeaderPayload = 16 + (chainhash.HashSize * 2)

MaxBlockHeaderPayload is the maximum number of bytes a block header can be. Version 4 bytes + Timestamp 4 bytes + Bits 4 bytes + Nonce 4 bytes + PrevBlock and MerkleRoot hashes.

View Source
const MaxBlockHeadersPerMsg = 2000

MaxBlockHeadersPerMsg is the maximum number of block headers that can be in a single litecoin headers message.

View Source
const MaxBlockLocatorsPerMsg = 500

MaxBlockLocatorsPerMsg is the maximum number of block locator hashes allowed per message.

View Source
const MaxBlockPayload = 4000000

MaxBlockPayload is the maximum bytes a block message can be in bytes. After Segregated Witness, the max block payload has been raised to 4MB.

View Source
const MaxBlocksPerMsg = 500

MaxBlocksPerMsg is the maximum number of blocks allowed per message.

View Source
const (
	// MaxCFilterDataSize is the maximum byte size of a committed filter.
	// The maximum size is currently defined as 256KiB.
	MaxCFilterDataSize = 256 * 1024
)
View Source
const (
	// MaxFilterAddDataSize is the maximum byte size of a data
	// element to add to the Bloom filter.  It is equal to the
	// maximum element size of a script.
	MaxFilterAddDataSize = 520
)
View Source
const MaxGetCFiltersReqRange = 1000

MaxGetCFiltersReqRange the maximum number of filters that may be requested in a getcfheaders message.

View Source
const MaxMessagePayload = (1024 * 1024 * 32) // 32MB

MaxMessagePayload is the maximum bytes a message can be regardless of other individual limits imposed by messages themselves.

View Source
const MaxMwebUtxosPerQuery = 4096
View Source
const MaxUserAgentLen = 256

MaxUserAgentLen is the maximum allowed length for the user agent field in a version message (MsgVersion).

View Source
const MaxV2AddrPerMsg = 1000

MaxV2AddrPerMsg is the maximum number of version 2 addresses that will exist in a single addrv2 message (MsgAddrV2).

View Source
const (
	// MaxVarIntPayload is the maximum payload size for a variable length integer.
	MaxVarIntPayload = 9
)
View Source
const MessageHeaderSize = 24

MessageHeaderSize is the number of bytes in a litecoin message header. Litecoin network (magic) 4 bytes + command 12 bytes + payload length 4 bytes + checksum 4 bytes.

View Source
const (

	// TorV3Size is the size of a torv3 address in bytes.
	TorV3Size = 32
)
View Source
const TxFlagMarker = 0x00

TxFlagMarker is the first byte of the FLAG field in a litecoin tx message. It allows decoders to distinguish a regular serialized transaction from one that would require a different parsing logic.

Position of FLAG in a litecoin tx message:

┌─────────┬────────────────────┬─────────────┬─────┐
│ VERSION │ FLAG               │ TX-IN-COUNT │ ... │
│ 4 bytes │ 2 bytes (optional) │ varint      │     │
└─────────┴────────────────────┴─────────────┴─────┘

Zooming into the FLAG field:

┌── FLAG ─────────────┬────────┐
│ TxFlagMarker (0x00) │ TxFlag │
│ 1 byte              │ 1 byte │
└─────────────────────┴────────┘

Variables

View Source
var (
	// ErrInvalidAddressSize is an error that means an incorrect address
	// size was decoded for a networkID or that the address exceeded the
	// maximum size for an unknown networkID.
	ErrInvalidAddressSize = fmt.Errorf("invalid address size")

	// ErrSkippedNetworkID is returned when the cjdns, i2p, or unknown
	// networks are encountered during decoding. ltcd does not support i2p
	// or cjdns addresses. In the case of an unknown networkID, this is so
	// that a future BIP reserving a new networkID does not cause older
	// addrv2-supporting ltcd software to disconnect upon receiving the new
	// addresses. This error can also be returned when an OnionCat-encoded
	// torv2 address is received with the ipv6 networkID. This error
	// signals to the caller to continue reading.
	ErrSkippedNetworkID = fmt.Errorf("skipped networkID")
)
View Source
var ErrInsaneCFHeaderCount = errors.New(
	"refusing to decode unreasonable number of filter headers")

ErrInsaneCFHeaderCount signals that we were asked to decode an unreasonable number of cfilter headers.

View Source
var ErrInvalidHandshake = fmt.Errorf("invalid message during handshake")

ErrInvalidHandshake is the error returned when a peer sends us a known message that does not belong in the version-verack handshake.

View Source
var ErrUnknownMessage = fmt.Errorf("received unknown message")

ErrUnknownMessage is the error returned when decoding an unknown message.

Functions

func RandomUint64

func RandomUint64() (uint64, error)

RandomUint64 returns a cryptographically random uint64 value.

func ReadTxOut

func ReadTxOut(r io.Reader, pver uint32, version int32, to *TxOut) error

ReadTxOut reads the next sequence of bytes from r as a transaction output (TxOut).

func ReadVarBytes

func ReadVarBytes(r io.Reader, pver uint32, maxAllowed uint32,
	fieldName string) ([]byte, error)

ReadVarBytes reads a variable length byte array. A byte array is encoded as a varInt containing the length of the array followed by the bytes themselves. An error is returned if the length is greater than the passed maxAllowed parameter which helps protect against memory exhaustion attacks and forced panics through malformed messages. The fieldName parameter is only used for the error message so it provides more context in the error.

func ReadVarInt

func ReadVarInt(r io.Reader, pver uint32) (uint64, error)

ReadVarInt reads a variable length integer from r and returns it as a uint64.

func ReadVarString

func ReadVarString(r io.Reader, pver uint32) (string, error)

ReadVarString reads a variable length string from r and returns it as a Go string. A variable length string is encoded as a variable length integer containing the length of the string followed by the bytes that represent the string itself. An error is returned if the length is greater than the maximum block payload size since it helps protect against memory exhaustion attacks and forced panics through malformed messages.

func VarIntSerializeSize

func VarIntSerializeSize(val uint64) int

VarIntSerializeSize returns the number of bytes it would take to serialize val as a variable length integer.

func WriteMessage

func WriteMessage(w io.Writer, msg Message, pver uint32, btcnet BitcoinNet) error

WriteMessage writes a litecoin Message to w including the necessary header information. This function is the same as WriteMessageN except it doesn't doesn't return the number of bytes written. This function is mainly provided for backwards compatibility with the original API, but it's also useful for callers that don't care about byte counts.

func WriteMessageN

func WriteMessageN(w io.Writer, msg Message, pver uint32, btcnet BitcoinNet) (int, error)

WriteMessageN writes a litecoin Message to w including the necessary header information and returns the number of bytes written. This function is the same as WriteMessage except it also returns the number of bytes written.

func WriteMessageWithEncodingN

func WriteMessageWithEncodingN(w io.Writer, msg Message, pver uint32,
	btcnet BitcoinNet, encoding MessageEncoding) (int, error)

WriteMessageWithEncodingN writes a litecoin Message to w including the necessary header information and returns the number of bytes written. This function is the same as WriteMessageN except it also allows the caller to specify the message encoding format to be used when serializing wire messages.

func WriteOutPoint

func WriteOutPoint(w io.Writer, pver uint32, version int32, op *OutPoint) error

WriteOutPoint encodes op to the litecoin protocol encoding for an OutPoint to w.

func WriteTxOut

func WriteTxOut(w io.Writer, pver uint32, version int32, to *TxOut) error

WriteTxOut encodes to into the litecoin protocol encoding for a transaction output (TxOut) to w.

NOTE: This function is exported in order to allow txscript to compute the new sighashes for witness transactions (BIP0143).

func WriteVarBytes

func WriteVarBytes(w io.Writer, pver uint32, bytes []byte) error

WriteVarBytes serializes a variable length byte array to w as a varInt containing the number of bytes, followed by the bytes themselves.

func WriteVarInt

func WriteVarInt(w io.Writer, pver uint32, val uint64) error

WriteVarInt serializes val to w using a variable number of bytes depending on its value.

func WriteVarString

func WriteVarString(w io.Writer, pver uint32, str string) error

WriteVarString serializes str to w as a variable length integer containing the length of the string followed by the bytes that represent the string itself.

Types

type Alert

type Alert struct {
	// Alert format version
	Version int32

	// Timestamp beyond which nodes should stop relaying this alert
	RelayUntil int64

	// Timestamp beyond which this alert is no longer in effect and
	// should be ignored
	Expiration int64

	// A unique ID number for this alert
	ID int32

	// All alerts with an ID less than or equal to this number should
	// cancelled, deleted and not accepted in the future
	Cancel int32

	// All alert IDs contained in this set should be cancelled as above
	SetCancel []int32

	// This alert only applies to versions greater than or equal to this
	// version. Other versions should still relay it.
	MinVer int32

	// This alert only applies to versions less than or equal to this version.
	// Other versions should still relay it.
	MaxVer int32

	// If this set contains any elements, then only nodes that have their
	// subVer contained in this set are affected by the alert. Other versions
	// should still relay it.
	SetSubVer []string

	// Relative priority compared to other alerts
	Priority int32

	// A comment on the alert that is not displayed
	Comment string

	// The alert message that is displayed to the user
	StatusBar string

	// Reserved
	Reserved string
}

Alert contains the data deserialized from the MsgAlert payload.

func NewAlert

func NewAlert(version int32, relayUntil int64, expiration int64,
	id int32, cancel int32, setCancel []int32, minVer int32,
	maxVer int32, setSubVer []string, priority int32, comment string,
	statusBar string) *Alert

NewAlert returns an new Alert with values provided.

func NewAlertFromPayload

func NewAlertFromPayload(serializedPayload []byte, pver uint32) (*Alert, error)

NewAlertFromPayload returns an Alert with values deserialized from the serialized payload.

func (*Alert) Deserialize

func (alert *Alert) Deserialize(r io.Reader, pver uint32) error

Deserialize decodes from r into the receiver using the alert protocol encoding format.

func (*Alert) Serialize

func (alert *Alert) Serialize(w io.Writer, pver uint32) error

Serialize encodes the alert to w using the alert protocol encoding format.

type BitcoinNet

type BitcoinNet uint32

BitcoinNet represents which litecoin network a message belongs to.

const (
	// MainNet represents the main litecoin network.
	MainNet BitcoinNet = 0xdbb6c0fb

	// TestNet represents the regression test network.
	TestNet BitcoinNet = 0xdab5bffa

	// TestNet4 represents the test network (version 4).
	TestNet4 BitcoinNet = 0xf1c8d2fd

	// SimNet represents the simulation test network.
	SimNet BitcoinNet = 0x12141c16
)

Constants used to indicate the message litecoin network. They can also be used to seek to the next message when a stream's state is unknown, but this package does not provide that functionality since it's generally a better idea to simply disconnect clients that are misbehaving over TCP.

func (BitcoinNet) String

func (n BitcoinNet) String() string

String returns the BitcoinNet in human-readable form.

type BlockHeader

type BlockHeader struct {
	// Version of the block.  This is not the same as the protocol version.
	Version int32

	// Hash of the previous block header in the block chain.
	PrevBlock chainhash.Hash

	// Merkle tree reference to hash of all transactions for the block.
	MerkleRoot chainhash.Hash

	// Time the block was created.  This is, unfortunately, encoded as a
	// uint32 on the wire and therefore is limited to 2106.
	Timestamp time.Time

	// Difficulty target for the block.
	Bits uint32

	// Nonce used to generate the block.
	Nonce uint32
}

BlockHeader defines information about a block and is used in the litecoin block (MsgBlock) and headers (MsgHeaders) messages.

func NewBlockHeader

func NewBlockHeader(version int32, prevHash, merkleRootHash *chainhash.Hash,
	bits uint32, nonce uint32) *BlockHeader

NewBlockHeader returns a new BlockHeader using the provided version, previous block hash, merkle root hash, difficulty bits, and nonce used to generate the block with defaults for the remaining fields.

func (*BlockHeader) BlockHash

func (h *BlockHeader) BlockHash() chainhash.Hash

BlockHash computes the block identifier hash for the given block header.

func (*BlockHeader) BtcDecode

func (h *BlockHeader) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation. See Deserialize for decoding block headers stored to disk, such as in a database, as opposed to decoding block headers from the wire.

func (*BlockHeader) BtcEncode

func (h *BlockHeader) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation. See Serialize for encoding block headers to be stored to disk, such as in a database, as opposed to encoding block headers for the wire.

func (*BlockHeader) Deserialize

func (h *BlockHeader) Deserialize(r io.Reader) error

Deserialize decodes a block header from r into the receiver using a format that is suitable for long-term storage such as a database while respecting the Version field.

func (*BlockHeader) PowHash

func (h *BlockHeader) PowHash() chainhash.Hash

PowHash returns the litecoin scrypt hash of this block header. This value is used to check the PoW on blocks advertised on the network.

func (*BlockHeader) Serialize

func (h *BlockHeader) Serialize(w io.Writer) error

Serialize encodes a block header from r into the receiver using a format that is suitable for long-term storage such as a database while respecting the Version field.

type BloomUpdateType

type BloomUpdateType uint8

BloomUpdateType specifies how the filter is updated when a match is found

const (
	// BloomUpdateNone indicates the filter is not adjusted when a match is
	// found.
	BloomUpdateNone BloomUpdateType = 0

	// BloomUpdateAll indicates if the filter matches any data element in a
	// public key script, the outpoint is serialized and inserted into the
	// filter.
	BloomUpdateAll BloomUpdateType = 1

	// BloomUpdateP2PubkeyOnly indicates if the filter matches a data
	// element in a public key script and the script is of the standard
	// pay-to-pubkey or multisig, the outpoint is serialized and inserted
	// into the filter.
	BloomUpdateP2PubkeyOnly BloomUpdateType = 2
)

type FilterType

type FilterType uint8

FilterType is used to represent a filter type.

const (
	// GCSFilterRegular is the regular filter type.
	GCSFilterRegular FilterType = iota
)

type InvType

type InvType uint32

InvType represents the allowed types of inventory vectors. See InvVect.

const (
	InvTypeError                InvType = 0
	InvTypeTx                   InvType = 1
	InvTypeBlock                InvType = 2
	InvTypeFilteredBlock        InvType = 3
	InvTypeWitnessBlock         InvType = InvTypeBlock | InvWitnessFlag
	InvTypeWitnessTx            InvType = InvTypeTx | InvWitnessFlag
	InvTypeFilteredWitnessBlock InvType = InvTypeFilteredBlock | InvWitnessFlag
	InvTypeMwebBlock            InvType = InvTypeWitnessBlock | InvMwebFlag
	InvTypeMwebTx               InvType = InvTypeWitnessTx | InvMwebFlag
	InvTypeMwebHeader           InvType = 8 | InvMwebFlag
	InvTypeMwebLeafset          InvType = 9 | InvMwebFlag
)

These constants define the various supported inventory vector types.

func (InvType) String

func (invtype InvType) String() string

String returns the InvType in human-readable form.

type InvVect

type InvVect struct {
	Type InvType        // Type of data
	Hash chainhash.Hash // Hash of the data
}

InvVect defines a litecoin inventory vector which is used to describe data, as specified by the Type field, that a peer wants, has, or does not have to another peer.

func NewInvVect

func NewInvVect(typ InvType, hash *chainhash.Hash) *InvVect

NewInvVect returns a new InvVect using the provided type and hash.

type Message

type Message interface {
	BtcDecode(io.Reader, uint32, MessageEncoding) error
	BtcEncode(io.Writer, uint32, MessageEncoding) error
	Command() string
	MaxPayloadLength(uint32) uint32
}

Message is an interface that describes a litecoin message. A type that implements Message has complete control over the representation of its data and may therefore contain additional or fewer fields than those which are used directly in the protocol encoded message.

func ReadMessage

func ReadMessage(r io.Reader, pver uint32, btcnet BitcoinNet) (Message, []byte, error)

ReadMessage reads, validates, and parses the next litecoin Message from r for the provided protocol version and litecoin network. It returns the parsed Message and raw bytes which comprise the message. This function only differs from ReadMessageN in that it doesn't return the number of bytes read. This function is mainly provided for backwards compatibility with the original API, but it's also useful for callers that don't care about byte counts.

func ReadMessageN

func ReadMessageN(r io.Reader, pver uint32, btcnet BitcoinNet) (int, Message, []byte, error)

ReadMessageN reads, validates, and parses the next litecoin Message from r for the provided protocol version and litecoin network. It returns the number of bytes read in addition to the parsed Message and raw bytes which comprise the message. This function is the same as ReadMessage except it also returns the number of bytes read.

func ReadMessageWithEncodingN

func ReadMessageWithEncodingN(r io.Reader, pver uint32, btcnet BitcoinNet,
	enc MessageEncoding) (int, Message, []byte, error)

ReadMessageWithEncodingN reads, validates, and parses the next litecoin Message from r for the provided protocol version and litecoin network. It returns the number of bytes read in addition to the parsed Message and raw bytes which comprise the message. This function is the same as ReadMessageN except it allows the caller to specify which message encoding is to to consult when decoding wire messages.

type MessageEncoding

type MessageEncoding uint32

MessageEncoding represents the wire message encoding format to be used.

const (
	// BaseEncoding encodes all messages in the default format specified
	// for the Litecoin wire protocol.
	BaseEncoding MessageEncoding = 1 << iota

	// WitnessEncoding encodes all messages other than transaction messages
	// using the default Litecoin wire protocol specification. For transaction
	// messages, the new encoding format detailed in BIP0144 will be used.
	WitnessEncoding

	// MwebEncoding encodes all messages other than transaction messages
	// using the default Litecoin wire protocol specification. For transaction
	// messages, the new encoding format detailed in LIP0003 will be used.
	MwebEncoding

	// LatestEncoding is the most recently specified encoding for the
	// Litecoin wire protocol.
	LatestEncoding = WitnessEncoding | MwebEncoding
)

type MessageError

type MessageError struct {
	Func        string // Function name
	Description string // Human readable description of the issue
}

MessageError describes an issue with a message. An example of some potential issues are messages from the wrong litecoin network, invalid commands, mismatched checksums, and exceeding max payloads.

This provides a mechanism for the caller to type assert the error to differentiate between general io errors such as io.EOF and issues that resulted from malformed messages.

func (*MessageError) Error

func (e *MessageError) Error() string

Error satisfies the error interface and prints human-readable errors.

type MsgAddr

type MsgAddr struct {
	AddrList []*NetAddress
}

MsgAddr implements the Message interface and represents a litecoin addr message. It is used to provide a list of known active peers on the network. An active peer is considered one that has transmitted a message within the last 3 hours. Nodes which have not transmitted in that time frame should be forgotten. Each message is limited to a maximum number of addresses, which is currently 1000. As a result, multiple messages must be used to relay the full list.

Use the AddAddress function to build up the list of known addresses when sending an addr message to another peer.

func NewMsgAddr

func NewMsgAddr() *MsgAddr

NewMsgAddr returns a new litecoin addr message that conforms to the Message interface. See MsgAddr for details.

func (*MsgAddr) AddAddress

func (msg *MsgAddr) AddAddress(na *NetAddress) error

AddAddress adds a known active peer to the message.

func (*MsgAddr) AddAddresses

func (msg *MsgAddr) AddAddresses(netAddrs ...*NetAddress) error

AddAddresses adds multiple known active peers to the message.

func (*MsgAddr) BtcDecode

func (msg *MsgAddr) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgAddr) BtcEncode

func (msg *MsgAddr) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgAddr) ClearAddresses

func (msg *MsgAddr) ClearAddresses()

ClearAddresses removes all addresses from the message.

func (*MsgAddr) Command

func (msg *MsgAddr) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgAddr) MaxPayloadLength

func (msg *MsgAddr) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgAddrV2

type MsgAddrV2 struct {
	AddrList []*NetAddressV2
}

MsgAddrV2 implements the Message interface and represents a litecoin addrv2 message that can support longer-length addresses like torv3, cjdns, and i2p. It is used to gossip addresses on the network. Each message is limited to MaxV2AddrPerMsg addresses. This is the same limit as MsgAddr.

func NewMsgAddrV2

func NewMsgAddrV2() *MsgAddrV2

NewMsgAddrV2 returns a new litecoin addrv2 message that conforms to the Message interface.

func (*MsgAddrV2) BtcDecode

func (m *MsgAddrV2) BtcDecode(r io.Reader, pver uint32,
	enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol into a MsgAddrV2.

func (*MsgAddrV2) BtcEncode

func (m *MsgAddrV2) BtcEncode(w io.Writer, pver uint32,
	enc MessageEncoding) error

BtcEncode encodes the MsgAddrV2 into a writer w.

func (*MsgAddrV2) Command

func (m *MsgAddrV2) Command() string

Command returns the protocol command string for MsgAddrV2.

func (*MsgAddrV2) MaxPayloadLength

func (m *MsgAddrV2) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length payload possible for MsgAddrV2.

type MsgAlert

type MsgAlert struct {
	// SerializedPayload is the alert payload serialized as a string so that the
	// version can change but the Alert can still be passed on by older
	// clients.
	SerializedPayload []byte

	// Signature is the ECDSA signature of the message.
	Signature []byte

	// Deserialized Payload
	Payload *Alert
}

MsgAlert implements the Message interface and defines a litecoin alert message.

This is a signed message that provides notifications that the client should display if the signature matches the key. litecoind/litecoin-qt only checks against a signature from the core developers.

func NewMsgAlert

func NewMsgAlert(serializedPayload []byte, signature []byte) *MsgAlert

NewMsgAlert returns a new litecoin alert message that conforms to the Message interface. See MsgAlert for details.

func (*MsgAlert) BtcDecode

func (msg *MsgAlert) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgAlert) BtcEncode

func (msg *MsgAlert) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgAlert) Command

func (msg *MsgAlert) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgAlert) MaxPayloadLength

func (msg *MsgAlert) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgBlock

type MsgBlock struct {
	Header           BlockHeader
	Transactions     []*MsgTx
	MwebHeader       *MwebHeader
	MwebTransactions *MwebTxBody
}

MsgBlock implements the Message interface and represents a litecoin block message. It is used to deliver block and transaction information in response to a getdata message (MsgGetData) for a given block hash.

func NewMsgBlock

func NewMsgBlock(blockHeader *BlockHeader) *MsgBlock

NewMsgBlock returns a new litecoin block message that conforms to the Message interface. See MsgBlock for details.

func (*MsgBlock) AddTransaction

func (msg *MsgBlock) AddTransaction(tx *MsgTx) error

AddTransaction adds a transaction to the message.

func (*MsgBlock) BlockHash

func (msg *MsgBlock) BlockHash() chainhash.Hash

BlockHash computes the block identifier hash for this block.

func (*MsgBlock) BtcDecode

func (msg *MsgBlock) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation. See Deserialize for decoding blocks stored to disk, such as in a database, as opposed to decoding blocks from the wire.

func (*MsgBlock) BtcEncode

func (msg *MsgBlock) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation. See Serialize for encoding blocks to be stored to disk, such as in a database, as opposed to encoding blocks for the wire.

func (*MsgBlock) ClearTransactions

func (msg *MsgBlock) ClearTransactions()

ClearTransactions removes all transactions from the message.

func (*MsgBlock) Command

func (msg *MsgBlock) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgBlock) Deserialize

func (msg *MsgBlock) Deserialize(r io.Reader) error

Deserialize decodes a block from r into the receiver using a format that is suitable for long-term storage such as a database while respecting the Version field in the block. This function differs from BtcDecode in that BtcDecode decodes from the litecoin wire protocol as it was sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored block at all. As of the time this comment was written, the encoded block is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgBlock) DeserializeNoWitness

func (msg *MsgBlock) DeserializeNoWitness(r io.Reader) error

DeserializeNoWitness decodes a block from r into the receiver similar to Deserialize, however DeserializeWitness strips all (if any) witness data from the transactions within the block before encoding them.

func (*MsgBlock) DeserializeTxLoc

func (msg *MsgBlock) DeserializeTxLoc(r *bytes.Buffer) ([]TxLoc, error)

DeserializeTxLoc decodes r in the same manner Deserialize does, but it takes a byte buffer instead of a generic reader and returns a slice containing the start and length of each transaction within the raw data that is being deserialized.

func (*MsgBlock) MaxPayloadLength

func (msg *MsgBlock) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

func (*MsgBlock) Serialize

func (msg *MsgBlock) Serialize(w io.Writer) error

Serialize encodes the block to w using a format that suitable for long-term storage such as a database while respecting the Version field in the block. This function differs from BtcEncode in that BtcEncode encodes the block to the litecoin wire protocol in order to be sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored block at all. As of the time this comment was written, the encoded block is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgBlock) SerializeNoWitness

func (msg *MsgBlock) SerializeNoWitness(w io.Writer) error

SerializeNoWitness encodes a block to w using an identical format to Serialize, with all (if any) witness data stripped from all transactions. This method is provided in additon to the regular Serialize, in order to allow one to selectively encode transaction witness data to non-upgraded peers which are unaware of the new encoding.

func (*MsgBlock) SerializeSize

func (msg *MsgBlock) SerializeSize() int

SerializeSize returns the number of bytes it would take to serialize the block, factoring in any witness data within transaction.

func (*MsgBlock) SerializeSizeStripped

func (msg *MsgBlock) SerializeSizeStripped() int

SerializeSizeStripped returns the number of bytes it would take to serialize the block, excluding any witness data (if any).

func (*MsgBlock) TxHashes

func (msg *MsgBlock) TxHashes() ([]chainhash.Hash, error)

TxHashes returns a slice of hashes of all of transactions in this block.

type MsgCFCheckpt

type MsgCFCheckpt struct {
	FilterType    FilterType
	StopHash      chainhash.Hash
	FilterHeaders []*chainhash.Hash
}

MsgCFCheckpt implements the Message interface and represents a litecoin cfcheckpt message. It is used to deliver committed filter header information in response to a getcfcheckpt message (MsgGetCFCheckpt). See MsgGetCFCheckpt for details on requesting the headers.

func NewMsgCFCheckpt

func NewMsgCFCheckpt(filterType FilterType, stopHash *chainhash.Hash,
	headersCount int) *MsgCFCheckpt

NewMsgCFCheckpt returns a new litecoin cfheaders message that conforms to the Message interface. See MsgCFCheckpt for details.

func (*MsgCFCheckpt) AddCFHeader

func (msg *MsgCFCheckpt) AddCFHeader(header *chainhash.Hash) error

AddCFHeader adds a new committed filter header to the message.

func (*MsgCFCheckpt) BtcDecode

func (msg *MsgCFCheckpt) BtcDecode(r io.Reader, pver uint32, _ MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgCFCheckpt) BtcEncode

func (msg *MsgCFCheckpt) BtcEncode(w io.Writer, pver uint32, _ MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgCFCheckpt) Command

func (msg *MsgCFCheckpt) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgCFCheckpt) Deserialize

func (msg *MsgCFCheckpt) Deserialize(r io.Reader) error

Deserialize decodes a filter header from r into the receiver using a format that is suitable for long-term storage such as a database. This function differs from BtcDecode in that BtcDecode decodes from the litecoin wire protocol as it was sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored filter header at all. As of the time this comment was written, the encoded filter header is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgCFCheckpt) MaxPayloadLength

func (msg *MsgCFCheckpt) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgCFHeaders

type MsgCFHeaders struct {
	FilterType       FilterType
	StopHash         chainhash.Hash
	PrevFilterHeader chainhash.Hash
	FilterHashes     []*chainhash.Hash
}

MsgCFHeaders implements the Message interface and represents a litecoin cfheaders message. It is used to deliver committed filter header information in response to a getcfheaders message (MsgGetCFHeaders). The maximum number of committed filter headers per message is currently 2000. See MsgGetCFHeaders for details on requesting the headers.

func NewMsgCFHeaders

func NewMsgCFHeaders() *MsgCFHeaders

NewMsgCFHeaders returns a new litecoin cfheaders message that conforms to the Message interface. See MsgCFHeaders for details.

func (*MsgCFHeaders) AddCFHash

func (msg *MsgCFHeaders) AddCFHash(hash *chainhash.Hash) error

AddCFHash adds a new filter hash to the message.

func (*MsgCFHeaders) BtcDecode

func (msg *MsgCFHeaders) BtcDecode(r io.Reader, pver uint32, _ MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgCFHeaders) BtcEncode

func (msg *MsgCFHeaders) BtcEncode(w io.Writer, pver uint32, _ MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgCFHeaders) Command

func (msg *MsgCFHeaders) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgCFHeaders) Deserialize

func (msg *MsgCFHeaders) Deserialize(r io.Reader) error

Deserialize decodes a filter header from r into the receiver using a format that is suitable for long-term storage such as a database. This function differs from BtcDecode in that BtcDecode decodes from the litecoin wire protocol as it was sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored filter header at all. As of the time this comment was written, the encoded filter header is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgCFHeaders) MaxPayloadLength

func (msg *MsgCFHeaders) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgCFilter

type MsgCFilter struct {
	FilterType FilterType
	BlockHash  chainhash.Hash
	Data       []byte
}

MsgCFilter implements the Message interface and represents a litecoin cfilter message. It is used to deliver a committed filter in response to a getcfilters (MsgGetCFilters) message.

func NewMsgCFilter

func NewMsgCFilter(filterType FilterType, blockHash *chainhash.Hash,
	data []byte) *MsgCFilter

NewMsgCFilter returns a new litecoin cfilter message that conforms to the Message interface. See MsgCFilter for details.

func (*MsgCFilter) BtcDecode

func (msg *MsgCFilter) BtcDecode(r io.Reader, pver uint32, _ MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgCFilter) BtcEncode

func (msg *MsgCFilter) BtcEncode(w io.Writer, pver uint32, _ MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgCFilter) Command

func (msg *MsgCFilter) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgCFilter) Deserialize

func (msg *MsgCFilter) Deserialize(r io.Reader) error

Deserialize decodes a filter from r into the receiver using a format that is suitable for long-term storage such as a database. This function differs from BtcDecode in that BtcDecode decodes from the litecoin wire protocol as it was sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored filter at all. As of the time this comment was written, the encoded filter is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgCFilter) MaxPayloadLength

func (msg *MsgCFilter) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgFeeFilter

type MsgFeeFilter struct {
	MinFee int64
}

MsgFeeFilter implements the Message interface and represents a litecoin feefilter message. It is used to request the receiving peer does not announce any transactions below the specified minimum fee rate.

This message was not added until protocol versions starting with FeeFilterVersion.

func NewMsgFeeFilter

func NewMsgFeeFilter(minfee int64) *MsgFeeFilter

NewMsgFeeFilter returns a new litecoin feefilter message that conforms to the Message interface. See MsgFeeFilter for details.

func (*MsgFeeFilter) BtcDecode

func (msg *MsgFeeFilter) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgFeeFilter) BtcEncode

func (msg *MsgFeeFilter) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgFeeFilter) Command

func (msg *MsgFeeFilter) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgFeeFilter) MaxPayloadLength

func (msg *MsgFeeFilter) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgFilterAdd

type MsgFilterAdd struct {
	Data []byte
}

MsgFilterAdd implements the Message interface and represents a litecoin filteradd message. It is used to add a data element to an existing Bloom filter.

This message was not added until protocol version BIP0037Version.

func NewMsgFilterAdd

func NewMsgFilterAdd(data []byte) *MsgFilterAdd

NewMsgFilterAdd returns a new litecoin filteradd message that conforms to the Message interface. See MsgFilterAdd for details.

func (*MsgFilterAdd) BtcDecode

func (msg *MsgFilterAdd) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgFilterAdd) BtcEncode

func (msg *MsgFilterAdd) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgFilterAdd) Command

func (msg *MsgFilterAdd) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgFilterAdd) MaxPayloadLength

func (msg *MsgFilterAdd) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgFilterClear

type MsgFilterClear struct{}

MsgFilterClear implements the Message interface and represents a litecoin filterclear message which is used to reset a Bloom filter.

This message was not added until protocol version BIP0037Version and has no payload.

func NewMsgFilterClear

func NewMsgFilterClear() *MsgFilterClear

NewMsgFilterClear returns a new litecoin filterclear message that conforms to the Message interface. See MsgFilterClear for details.

func (*MsgFilterClear) BtcDecode

func (msg *MsgFilterClear) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgFilterClear) BtcEncode

func (msg *MsgFilterClear) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgFilterClear) Command

func (msg *MsgFilterClear) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgFilterClear) MaxPayloadLength

func (msg *MsgFilterClear) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgFilterLoad

type MsgFilterLoad struct {
	Filter    []byte
	HashFuncs uint32
	Tweak     uint32
	Flags     BloomUpdateType
}

MsgFilterLoad implements the Message interface and represents a litecoin filterload message which is used to reset a Bloom filter.

This message was not added until protocol version BIP0037Version.

func NewMsgFilterLoad

func NewMsgFilterLoad(filter []byte, hashFuncs uint32, tweak uint32, flags BloomUpdateType) *MsgFilterLoad

NewMsgFilterLoad returns a new litecoin filterload message that conforms to the Message interface. See MsgFilterLoad for details.

func (*MsgFilterLoad) BtcDecode

func (msg *MsgFilterLoad) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgFilterLoad) BtcEncode

func (msg *MsgFilterLoad) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgFilterLoad) Command

func (msg *MsgFilterLoad) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgFilterLoad) MaxPayloadLength

func (msg *MsgFilterLoad) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetAddr

type MsgGetAddr struct{}

MsgGetAddr implements the Message interface and represents a litecoin getaddr message. It is used to request a list of known active peers on the network from a peer to help identify potential nodes. The list is returned via one or more addr messages (MsgAddr).

This message has no payload.

func NewMsgGetAddr

func NewMsgGetAddr() *MsgGetAddr

NewMsgGetAddr returns a new litecoin getaddr message that conforms to the Message interface. See MsgGetAddr for details.

func (*MsgGetAddr) BtcDecode

func (msg *MsgGetAddr) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetAddr) BtcEncode

func (msg *MsgGetAddr) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetAddr) Command

func (msg *MsgGetAddr) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetAddr) MaxPayloadLength

func (msg *MsgGetAddr) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetBlocks

type MsgGetBlocks struct {
	ProtocolVersion    uint32
	BlockLocatorHashes []*chainhash.Hash
	HashStop           chainhash.Hash
}

MsgGetBlocks implements the Message interface and represents a litecoin getblocks message. It is used to request a list of blocks starting after the last known hash in the slice of block locator hashes. The list is returned via an inv message (MsgInv) and is limited by a specific hash to stop at or the maximum number of blocks per message, which is currently 500.

Set the HashStop field to the hash at which to stop and use AddBlockLocatorHash to build up the list of block locator hashes.

The algorithm for building the block locator hashes should be to add the hashes in reverse order until you reach the genesis block. In order to keep the list of locator hashes to a reasonable number of entries, first add the most recent 10 block hashes, then double the step each loop iteration to exponentially decrease the number of hashes the further away from head and closer to the genesis block you get.

func NewMsgGetBlocks

func NewMsgGetBlocks(hashStop *chainhash.Hash) *MsgGetBlocks

NewMsgGetBlocks returns a new litecoin getblocks message that conforms to the Message interface using the passed parameters and defaults for the remaining fields.

func (*MsgGetBlocks) AddBlockLocatorHash

func (msg *MsgGetBlocks) AddBlockLocatorHash(hash *chainhash.Hash) error

AddBlockLocatorHash adds a new block locator hash to the message.

func (*MsgGetBlocks) BtcDecode

func (msg *MsgGetBlocks) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetBlocks) BtcEncode

func (msg *MsgGetBlocks) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetBlocks) Command

func (msg *MsgGetBlocks) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetBlocks) MaxPayloadLength

func (msg *MsgGetBlocks) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetCFCheckpt

type MsgGetCFCheckpt struct {
	FilterType FilterType
	StopHash   chainhash.Hash
}

MsgGetCFCheckpt is a request for filter headers at evenly spaced intervals throughout the blockchain history. It allows to set the FilterType field to get headers in the chain of basic (0x00) or extended (0x01) headers.

func NewMsgGetCFCheckpt

func NewMsgGetCFCheckpt(filterType FilterType, stopHash *chainhash.Hash) *MsgGetCFCheckpt

NewMsgGetCFCheckpt returns a new litecoin getcfcheckpt message that conforms to the Message interface using the passed parameters and defaults for the remaining fields.

func (*MsgGetCFCheckpt) BtcDecode

func (msg *MsgGetCFCheckpt) BtcDecode(r io.Reader, pver uint32, _ MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetCFCheckpt) BtcEncode

func (msg *MsgGetCFCheckpt) BtcEncode(w io.Writer, pver uint32, _ MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetCFCheckpt) Command

func (msg *MsgGetCFCheckpt) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetCFCheckpt) MaxPayloadLength

func (msg *MsgGetCFCheckpt) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetCFHeaders

type MsgGetCFHeaders struct {
	FilterType  FilterType
	StartHeight uint32
	StopHash    chainhash.Hash
}

MsgGetCFHeaders is a message similar to MsgGetHeaders, but for committed filter headers. It allows to set the FilterType field to get headers in the chain of basic (0x00) or extended (0x01) headers.

func NewMsgGetCFHeaders

func NewMsgGetCFHeaders(filterType FilterType, startHeight uint32,
	stopHash *chainhash.Hash) *MsgGetCFHeaders

NewMsgGetCFHeaders returns a new litecoin getcfheader message that conforms to the Message interface using the passed parameters and defaults for the remaining fields.

func (*MsgGetCFHeaders) BtcDecode

func (msg *MsgGetCFHeaders) BtcDecode(r io.Reader, pver uint32, _ MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetCFHeaders) BtcEncode

func (msg *MsgGetCFHeaders) BtcEncode(w io.Writer, pver uint32, _ MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetCFHeaders) Command

func (msg *MsgGetCFHeaders) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetCFHeaders) MaxPayloadLength

func (msg *MsgGetCFHeaders) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetCFilters

type MsgGetCFilters struct {
	FilterType  FilterType
	StartHeight uint32
	StopHash    chainhash.Hash
}

MsgGetCFilters implements the Message interface and represents a litecoin getcfilters message. It is used to request committed filters for a range of blocks.

func NewMsgGetCFilters

func NewMsgGetCFilters(filterType FilterType, startHeight uint32,
	stopHash *chainhash.Hash) *MsgGetCFilters

NewMsgGetCFilters returns a new litecoin getcfilters message that conforms to the Message interface using the passed parameters and defaults for the remaining fields.

func (*MsgGetCFilters) BtcDecode

func (msg *MsgGetCFilters) BtcDecode(r io.Reader, pver uint32, _ MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetCFilters) BtcEncode

func (msg *MsgGetCFilters) BtcEncode(w io.Writer, pver uint32, _ MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetCFilters) Command

func (msg *MsgGetCFilters) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetCFilters) MaxPayloadLength

func (msg *MsgGetCFilters) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetData

type MsgGetData struct {
	InvList []*InvVect
}

MsgGetData implements the Message interface and represents a litecoin getdata message. It is used to request data such as blocks and transactions from another peer. It should be used in response to the inv (MsgInv) message to request the actual data referenced by each inventory vector the receiving peer doesn't already have. Each message is limited to a maximum number of inventory vectors, which is currently 50,000. As a result, multiple messages must be used to request larger amounts of data.

Use the AddInvVect function to build up the list of inventory vectors when sending a getdata message to another peer.

func NewMsgGetData

func NewMsgGetData() *MsgGetData

NewMsgGetData returns a new litecoin getdata message that conforms to the Message interface. See MsgGetData for details.

func NewMsgGetDataSizeHint

func NewMsgGetDataSizeHint(sizeHint uint) *MsgGetData

NewMsgGetDataSizeHint returns a new litecoin getdata message that conforms to the Message interface. See MsgGetData for details. This function differs from NewMsgGetData in that it allows a default allocation size for the backing array which houses the inventory vector list. This allows callers who know in advance how large the inventory list will grow to avoid the overhead of growing the internal backing array several times when appending large amounts of inventory vectors with AddInvVect. Note that the specified hint is just that - a hint that is used for the default allocation size. Adding more (or less) inventory vectors will still work properly. The size hint is limited to MaxInvPerMsg.

func (*MsgGetData) AddInvVect

func (msg *MsgGetData) AddInvVect(iv *InvVect) error

AddInvVect adds an inventory vector to the message.

func (*MsgGetData) BtcDecode

func (msg *MsgGetData) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetData) BtcEncode

func (msg *MsgGetData) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetData) Command

func (msg *MsgGetData) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetData) MaxPayloadLength

func (msg *MsgGetData) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetHeaders

type MsgGetHeaders struct {
	ProtocolVersion    uint32
	BlockLocatorHashes []*chainhash.Hash
	HashStop           chainhash.Hash
}

MsgGetHeaders implements the Message interface and represents a litecoin getheaders message. It is used to request a list of block headers for blocks starting after the last known hash in the slice of block locator hashes. The list is returned via a headers message (MsgHeaders) and is limited by a specific hash to stop at or the maximum number of block headers per message, which is currently 2000.

Set the HashStop field to the hash at which to stop and use AddBlockLocatorHash to build up the list of block locator hashes.

The algorithm for building the block locator hashes should be to add the hashes in reverse order until you reach the genesis block. In order to keep the list of locator hashes to a resonable number of entries, first add the most recent 10 block hashes, then double the step each loop iteration to exponentially decrease the number of hashes the further away from head and closer to the genesis block you get.

func NewMsgGetHeaders

func NewMsgGetHeaders() *MsgGetHeaders

NewMsgGetHeaders returns a new litecoin getheaders message that conforms to the Message interface. See MsgGetHeaders for details.

func (*MsgGetHeaders) AddBlockLocatorHash

func (msg *MsgGetHeaders) AddBlockLocatorHash(hash *chainhash.Hash) error

AddBlockLocatorHash adds a new block locator hash to the message.

func (*MsgGetHeaders) BtcDecode

func (msg *MsgGetHeaders) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetHeaders) BtcEncode

func (msg *MsgGetHeaders) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetHeaders) Command

func (msg *MsgGetHeaders) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetHeaders) MaxPayloadLength

func (msg *MsgGetHeaders) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgGetMwebUtxos

type MsgGetMwebUtxos struct {
	BlockHash    chainhash.Hash
	StartIndex   uint64
	NumRequested uint16
	OutputFormat MwebNetUtxoType
}

MsgGetMwebUtxos implements the Message interface and represents a litecoin getmwebutxos message which is used to request a batch of MWEB UTXOs.

This message was not added until protocol version MwebLightClientVersion.

func NewMsgGetMwebUtxos

func NewMsgGetMwebUtxos(blockHash chainhash.Hash, startIndex uint64,
	numRequested uint16, outputFormat MwebNetUtxoType) *MsgGetMwebUtxos

NewMsgGetMwebUtxos returns a new litecoin getmwebutxos message that conforms to the Message interface. See MsgGetMwebUtxos for details.

func (*MsgGetMwebUtxos) BtcDecode

func (msg *MsgGetMwebUtxos) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgGetMwebUtxos) BtcEncode

func (msg *MsgGetMwebUtxos) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgGetMwebUtxos) Command

func (msg *MsgGetMwebUtxos) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgGetMwebUtxos) MaxPayloadLength

func (msg *MsgGetMwebUtxos) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgHeaders

type MsgHeaders struct {
	Headers []*BlockHeader
}

MsgHeaders implements the Message interface and represents a litecoin headers message. It is used to deliver block header information in response to a getheaders message (MsgGetHeaders). The maximum number of block headers per message is currently 2000. See MsgGetHeaders for details on requesting the headers.

func NewMsgHeaders

func NewMsgHeaders() *MsgHeaders

NewMsgHeaders returns a new litecoin headers message that conforms to the Message interface. See MsgHeaders for details.

func (*MsgHeaders) AddBlockHeader

func (msg *MsgHeaders) AddBlockHeader(bh *BlockHeader) error

AddBlockHeader adds a new block header to the message.

func (*MsgHeaders) BtcDecode

func (msg *MsgHeaders) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgHeaders) BtcEncode

func (msg *MsgHeaders) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgHeaders) Command

func (msg *MsgHeaders) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgHeaders) MaxPayloadLength

func (msg *MsgHeaders) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgInv

type MsgInv struct {
	InvList []*InvVect
}

MsgInv implements the Message interface and represents a litecoin inv message. It is used to advertise a peer's known data such as blocks and transactions through inventory vectors. It may be sent unsolicited to inform other peers of the data or in response to a getblocks message (MsgGetBlocks). Each message is limited to a maximum number of inventory vectors, which is currently 50,000.

Use the AddInvVect function to build up the list of inventory vectors when sending an inv message to another peer.

func NewMsgInv

func NewMsgInv() *MsgInv

NewMsgInv returns a new litecoin inv message that conforms to the Message interface. See MsgInv for details.

func NewMsgInvSizeHint

func NewMsgInvSizeHint(sizeHint uint) *MsgInv

NewMsgInvSizeHint returns a new litecoin inv message that conforms to the Message interface. See MsgInv for details. This function differs from NewMsgInv in that it allows a default allocation size for the backing array which houses the inventory vector list. This allows callers who know in advance how large the inventory list will grow to avoid the overhead of growing the internal backing array several times when appending large amounts of inventory vectors with AddInvVect. Note that the specified hint is just that - a hint that is used for the default allocation size. Adding more (or less) inventory vectors will still work properly. The size hint is limited to MaxInvPerMsg.

func (*MsgInv) AddInvVect

func (msg *MsgInv) AddInvVect(iv *InvVect) error

AddInvVect adds an inventory vector to the message.

func (*MsgInv) BtcDecode

func (msg *MsgInv) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgInv) BtcEncode

func (msg *MsgInv) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgInv) Command

func (msg *MsgInv) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgInv) MaxPayloadLength

func (msg *MsgInv) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgMemPool

type MsgMemPool struct{}

MsgMemPool implements the Message interface and represents a litecoin mempool message. It is used to request a list of transactions still in the active memory pool of a relay.

This message has no payload and was not added until protocol versions starting with BIP0035Version.

func NewMsgMemPool

func NewMsgMemPool() *MsgMemPool

NewMsgMemPool returns a new litecoin pong message that conforms to the Message interface. See MsgPong for details.

func (*MsgMemPool) BtcDecode

func (msg *MsgMemPool) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgMemPool) BtcEncode

func (msg *MsgMemPool) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgMemPool) Command

func (msg *MsgMemPool) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgMemPool) MaxPayloadLength

func (msg *MsgMemPool) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgMerkleBlock

type MsgMerkleBlock struct {
	Header       BlockHeader
	Transactions uint32
	Hashes       []*chainhash.Hash
	Flags        []byte
}

MsgMerkleBlock implements the Message interface and represents a litecoin merkleblock message which is used to reset a Bloom filter.

This message was not added until protocol version BIP0037Version.

func NewMsgMerkleBlock

func NewMsgMerkleBlock(bh *BlockHeader) *MsgMerkleBlock

NewMsgMerkleBlock returns a new litecoin merkleblock message that conforms to the Message interface. See MsgMerkleBlock for details.

func (*MsgMerkleBlock) AddTxHash

func (msg *MsgMerkleBlock) AddTxHash(hash *chainhash.Hash) error

AddTxHash adds a new transaction hash to the message.

func (*MsgMerkleBlock) BtcDecode

func (msg *MsgMerkleBlock) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgMerkleBlock) BtcEncode

func (msg *MsgMerkleBlock) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgMerkleBlock) Command

func (msg *MsgMerkleBlock) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgMerkleBlock) MaxPayloadLength

func (msg *MsgMerkleBlock) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgMwebHeader

type MsgMwebHeader struct {
	Merkle     MsgMerkleBlock
	Hogex      MsgTx
	MwebHeader MwebHeader
}

MsgMwebHeader implements the Message interface and represents a litecoin mwebheader message which is used for syncing MWEB headers.

This message was not added until protocol version MwebLightClientVersion.

func NewMsgMwebHeader

func NewMsgMwebHeader(mb *MsgMerkleBlock, hogex *MsgTx, mh *MwebHeader) *MsgMwebHeader

NewMsgMwebHeader returns a new litecoin mwebheader message that conforms to the Message interface. See MsgMwebHeader for details.

func (*MsgMwebHeader) BtcDecode

func (msg *MsgMwebHeader) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgMwebHeader) BtcEncode

func (msg *MsgMwebHeader) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgMwebHeader) Command

func (msg *MsgMwebHeader) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgMwebHeader) MaxPayloadLength

func (msg *MsgMwebHeader) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgMwebLeafset

type MsgMwebLeafset struct {
	BlockHash chainhash.Hash
	Leafset   []byte
}

MsgMwebLeafset implements the Message interface and represents a litecoin mwebleafset message which is used for retrieving the leaf indices of all unspent MWEB UTXOs.

This message was not added until protocol version MwebLightClientVersion.

func NewMsgMwebLeafset

func NewMsgMwebLeafset(blockHash *chainhash.Hash, leafset []byte) *MsgMwebLeafset

NewMsgMwebLeafset returns a new litecoin mwebleafset message that conforms to the Message interface. See MsgMwebLeafset for details.

func (*MsgMwebLeafset) BtcDecode

func (msg *MsgMwebLeafset) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgMwebLeafset) BtcEncode

func (msg *MsgMwebLeafset) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgMwebLeafset) Command

func (msg *MsgMwebLeafset) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgMwebLeafset) MaxPayloadLength

func (msg *MsgMwebLeafset) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgMwebUtxos

type MsgMwebUtxos struct {
	BlockHash    chainhash.Hash
	StartIndex   uint64
	OutputFormat MwebNetUtxoType
	Utxos        []*MwebNetUtxo
	ProofHashes  []*chainhash.Hash
}

MsgMwebUtxos implements the Message interface and represents a litecoin mwebutxos message which is used to send a batch of MWEB UTXOs.

This message was not added until protocol version MwebLightClientVersion.

func NewMsgMwebUtxos

func NewMsgMwebUtxos(blockHash chainhash.Hash, startIndex uint64,
	outputFormat MwebNetUtxoType) *MsgMwebUtxos

NewMsgMwebUtxos returns a new litecoin mwebutxos message that conforms to the Message interface. See MsgMwebUtxos for details.

func (*MsgMwebUtxos) BtcDecode

func (msg *MsgMwebUtxos) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgMwebUtxos) BtcEncode

func (msg *MsgMwebUtxos) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgMwebUtxos) Command

func (msg *MsgMwebUtxos) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgMwebUtxos) MaxPayloadLength

func (msg *MsgMwebUtxos) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgNotFound

type MsgNotFound struct {
	InvList []*InvVect
}

MsgNotFound defines a litecoin notfound message which is sent in response to a getdata message if any of the requested data in not available on the peer. Each message is limited to a maximum number of inventory vectors, which is currently 50,000.

Use the AddInvVect function to build up the list of inventory vectors when sending a notfound message to another peer.

func NewMsgNotFound

func NewMsgNotFound() *MsgNotFound

NewMsgNotFound returns a new litecoin notfound message that conforms to the Message interface. See MsgNotFound for details.

func (*MsgNotFound) AddInvVect

func (msg *MsgNotFound) AddInvVect(iv *InvVect) error

AddInvVect adds an inventory vector to the message.

func (*MsgNotFound) BtcDecode

func (msg *MsgNotFound) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgNotFound) BtcEncode

func (msg *MsgNotFound) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgNotFound) Command

func (msg *MsgNotFound) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgNotFound) MaxPayloadLength

func (msg *MsgNotFound) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgPing

type MsgPing struct {
	// Unique value associated with message that is used to identify
	// specific ping message.
	Nonce uint64
}

MsgPing implements the Message interface and represents a litecoin ping message.

For versions BIP0031Version and earlier, it is used primarily to confirm that a connection is still valid. A transmission error is typically interpreted as a closed connection and that the peer should be removed. For versions AFTER BIP0031Version it contains an identifier which can be returned in the pong message to determine network timing.

The payload for this message just consists of a nonce used for identifying it later.

func NewMsgPing

func NewMsgPing(nonce uint64) *MsgPing

NewMsgPing returns a new litecoin ping message that conforms to the Message interface. See MsgPing for details.

func (*MsgPing) BtcDecode

func (msg *MsgPing) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgPing) BtcEncode

func (msg *MsgPing) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgPing) Command

func (msg *MsgPing) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgPing) MaxPayloadLength

func (msg *MsgPing) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgPong

type MsgPong struct {
	// Unique value associated with message that is used to identify
	// specific ping message.
	Nonce uint64
}

MsgPong implements the Message interface and represents a litecoin pong message which is used primarily to confirm that a connection is still valid in response to a litecoin ping message (MsgPing).

This message was not added until protocol versions AFTER BIP0031Version.

func NewMsgPong

func NewMsgPong(nonce uint64) *MsgPong

NewMsgPong returns a new litecoin pong message that conforms to the Message interface. See MsgPong for details.

func (*MsgPong) BtcDecode

func (msg *MsgPong) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgPong) BtcEncode

func (msg *MsgPong) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgPong) Command

func (msg *MsgPong) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgPong) MaxPayloadLength

func (msg *MsgPong) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgReject

type MsgReject struct {
	// Cmd is the command for the message which was rejected such as
	// as CmdBlock or CmdTx.  This can be obtained from the Command function
	// of a Message.
	Cmd string

	// RejectCode is a code indicating why the command was rejected.  It
	// is encoded as a uint8 on the wire.
	Code RejectCode

	// Reason is a human-readable string with specific details (over and
	// above the reject code) about why the command was rejected.
	Reason string

	// Hash identifies a specific block or transaction that was rejected
	// and therefore only applies the MsgBlock and MsgTx messages.
	Hash chainhash.Hash
}

MsgReject implements the Message interface and represents a litecoin reject message.

This message was not added until protocol version RejectVersion.

func NewMsgReject

func NewMsgReject(command string, code RejectCode, reason string) *MsgReject

NewMsgReject returns a new litecoin reject message that conforms to the Message interface. See MsgReject for details.

func (*MsgReject) BtcDecode

func (msg *MsgReject) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgReject) BtcEncode

func (msg *MsgReject) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgReject) Command

func (msg *MsgReject) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgReject) MaxPayloadLength

func (msg *MsgReject) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgSendAddrV2

type MsgSendAddrV2 struct{}

MsgSendAddrV2 defines a litecoin sendaddrv2 message which is used for a peer to signal support for receiving ADDRV2 messages (BIP155). It implements the Message interface.

This message has no payload.

func NewMsgSendAddrV2

func NewMsgSendAddrV2() *MsgSendAddrV2

NewMsgSendAddrV2 returns a new litecoin sendaddrv2 message that conforms to the Message interface.

func (*MsgSendAddrV2) BtcDecode

func (msg *MsgSendAddrV2) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgSendAddrV2) BtcEncode

func (msg *MsgSendAddrV2) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgSendAddrV2) Command

func (msg *MsgSendAddrV2) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgSendAddrV2) MaxPayloadLength

func (msg *MsgSendAddrV2) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgSendHeaders

type MsgSendHeaders struct{}

MsgSendHeaders implements the Message interface and represents a litecoin sendheaders message. It is used to request the peer send block headers rather than inventory vectors.

This message has no payload and was not added until protocol versions starting with SendHeadersVersion.

func NewMsgSendHeaders

func NewMsgSendHeaders() *MsgSendHeaders

NewMsgSendHeaders returns a new litecoin sendheaders message that conforms to the Message interface. See MsgSendHeaders for details.

func (*MsgSendHeaders) BtcDecode

func (msg *MsgSendHeaders) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgSendHeaders) BtcEncode

func (msg *MsgSendHeaders) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgSendHeaders) Command

func (msg *MsgSendHeaders) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgSendHeaders) MaxPayloadLength

func (msg *MsgSendHeaders) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgTx

type MsgTx struct {
	Version  int32
	TxIn     []*TxIn
	TxOut    []*TxOut
	LockTime uint32
	IsHogEx  bool
	Mweb     *MwebTx
}

MsgTx implements the Message interface and represents a litecoin tx message. It is used to deliver transaction information in response to a getdata message (MsgGetData) for a given transaction.

Use the AddTxIn and AddTxOut functions to build up the list of transaction inputs and outputs.

func NewMsgTx

func NewMsgTx(version int32) *MsgTx

NewMsgTx returns a new litecoin tx message that conforms to the Message interface. The return instance has a default version of TxVersion and there are no transaction inputs or outputs. Also, the lock time is set to zero to indicate the transaction is valid immediately as opposed to some time in future.

func (*MsgTx) AddTxIn

func (msg *MsgTx) AddTxIn(ti *TxIn)

AddTxIn adds a transaction input to the message.

func (*MsgTx) AddTxOut

func (msg *MsgTx) AddTxOut(to *TxOut)

AddTxOut adds a transaction output to the message.

func (*MsgTx) BtcDecode

func (msg *MsgTx) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation. See Deserialize for decoding transactions stored to disk, such as in a database, as opposed to decoding transactions from the wire.

func (*MsgTx) BtcEncode

func (msg *MsgTx) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation. See Serialize for encoding transactions to be stored to disk, such as in a database, as opposed to encoding transactions for the wire.

func (*MsgTx) Command

func (msg *MsgTx) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgTx) Copy

func (msg *MsgTx) Copy() *MsgTx

Copy creates a deep copy of a transaction so that the original does not get modified when the copy is manipulated.

func (*MsgTx) Deserialize

func (msg *MsgTx) Deserialize(r io.Reader) error

Deserialize decodes a transaction from r into the receiver using a format that is suitable for long-term storage such as a database while respecting the Version field in the transaction. This function differs from BtcDecode in that BtcDecode decodes from the litecoin wire protocol as it was sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored transaction at all. As of the time this comment was written, the encoded transaction is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgTx) DeserializeNoWitness

func (msg *MsgTx) DeserializeNoWitness(r io.Reader) error

DeserializeNoWitness decodes a transaction from r into the receiver, where the transaction encoding format within r MUST NOT utilize the new serialization format created to encode transaction bearing witness data within inputs.

func (*MsgTx) HasWitness

func (msg *MsgTx) HasWitness() bool

HasWitness returns false if none of the inputs within the transaction contain witness data, true false otherwise.

func (*MsgTx) MaxPayloadLength

func (msg *MsgTx) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

func (*MsgTx) PkScriptLocs

func (msg *MsgTx) PkScriptLocs() []int

PkScriptLocs returns a slice containing the start of each public key script within the raw serialized transaction. The caller can easily obtain the length of each script by using len on the script available via the appropriate transaction output entry.

func (*MsgTx) Serialize

func (msg *MsgTx) Serialize(w io.Writer) error

Serialize encodes the transaction to w using a format that suitable for long-term storage such as a database while respecting the Version field in the transaction. This function differs from BtcEncode in that BtcEncode encodes the transaction to the litecoin wire protocol in order to be sent across the network. The wire encoding can technically differ depending on the protocol version and doesn't even really need to match the format of a stored transaction at all. As of the time this comment was written, the encoded transaction is the same in both instances, but there is a distinct difference and separating the two allows the API to be flexible enough to deal with changes.

func (*MsgTx) SerializeNoWitness

func (msg *MsgTx) SerializeNoWitness(w io.Writer) error

SerializeNoWitness encodes the transaction to w in an identical manner to Serialize, however even if the source transaction has inputs with witness data, the old serialization format will still be used.

func (*MsgTx) SerializeSize

func (msg *MsgTx) SerializeSize() int

SerializeSize returns the number of bytes it would take to serialize the the transaction.

func (*MsgTx) SerializeSizeStripped

func (msg *MsgTx) SerializeSizeStripped() int

SerializeSizeStripped returns the number of bytes it would take to serialize the transaction, excluding any included witness data.

func (*MsgTx) TxHash

func (msg *MsgTx) TxHash() chainhash.Hash

TxHash generates the Hash for the transaction.

func (*MsgTx) WitnessHash

func (msg *MsgTx) WitnessHash() chainhash.Hash

WitnessHash generates the hash of the transaction serialized according to the new witness serialization defined in BIP0141 and BIP0144. The final output is used within the Segregated Witness commitment of all the witnesses within a block. If a transaction has no witness data, then the witness hash, is the same as its txid.

type MsgVerAck

type MsgVerAck struct{}

MsgVerAck defines a litecoin verack message which is used for a peer to acknowledge a version message (MsgVersion) after it has used the information to negotiate parameters. It implements the Message interface.

This message has no payload.

func NewMsgVerAck

func NewMsgVerAck() *MsgVerAck

NewMsgVerAck returns a new litecoin verack message that conforms to the Message interface.

func (*MsgVerAck) BtcDecode

func (msg *MsgVerAck) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. This is part of the Message interface implementation.

func (*MsgVerAck) BtcEncode

func (msg *MsgVerAck) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgVerAck) Command

func (msg *MsgVerAck) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgVerAck) MaxPayloadLength

func (msg *MsgVerAck) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MsgVersion

type MsgVersion struct {
	// Version of the protocol the node is using.
	ProtocolVersion int32

	// Bitfield which identifies the enabled services.
	Services ServiceFlag

	// Time the message was generated.  This is encoded as an int64 on the wire.
	Timestamp time.Time

	// Address of the remote peer.
	AddrYou NetAddress

	// Address of the local peer.
	AddrMe NetAddress

	// Unique value associated with message that is used to detect self
	// connections.
	Nonce uint64

	// The user agent that generated messsage.  This is a encoded as a varString
	// on the wire.  This has a max length of MaxUserAgentLen.
	UserAgent string

	// Last block seen by the generator of the version message.
	LastBlock int32

	// Don't announce transactions to peer.
	DisableRelayTx bool
}

MsgVersion implements the Message interface and represents a litecoin version message. It is used for a peer to advertise itself as soon as an outbound connection is made. The remote peer then uses this information along with its own to negotiate. The remote peer must then respond with a version message of its own containing the negotiated values followed by a verack message (MsgVerAck). This exchange must take place before any further communication is allowed to proceed.

func NewMsgVersion

func NewMsgVersion(me *NetAddress, you *NetAddress, nonce uint64,
	lastBlock int32) *MsgVersion

NewMsgVersion returns a new litecoin version message that conforms to the Message interface using the passed parameters and defaults for the remaining fields.

func (*MsgVersion) AddService

func (msg *MsgVersion) AddService(service ServiceFlag)

AddService adds service as a supported service by the peer generating the message.

func (*MsgVersion) AddUserAgent

func (msg *MsgVersion) AddUserAgent(name string, version string,
	comments ...string) error

AddUserAgent adds a user agent to the user agent string for the version message. The version string is not defined to any strict format, although it is recommended to use the form "major.minor.revision" e.g. "2.6.41".

func (*MsgVersion) BtcDecode

func (msg *MsgVersion) BtcDecode(r io.Reader, pver uint32, enc MessageEncoding) error

BtcDecode decodes r using the litecoin protocol encoding into the receiver. The version message is special in that the protocol version hasn't been negotiated yet. As a result, the pver field is ignored and any fields which are added in new versions are optional. This also mean that r must be a *bytes.Buffer so the number of remaining bytes can be ascertained.

This is part of the Message interface implementation.

func (*MsgVersion) BtcEncode

func (msg *MsgVersion) BtcEncode(w io.Writer, pver uint32, enc MessageEncoding) error

BtcEncode encodes the receiver to w using the litecoin protocol encoding. This is part of the Message interface implementation.

func (*MsgVersion) Command

func (msg *MsgVersion) Command() string

Command returns the protocol command string for the message. This is part of the Message interface implementation.

func (*MsgVersion) HasService

func (msg *MsgVersion) HasService(service ServiceFlag) bool

HasService returns whether the specified service is supported by the peer that generated the message.

func (*MsgVersion) MaxPayloadLength

func (msg *MsgVersion) MaxPayloadLength(pver uint32) uint32

MaxPayloadLength returns the maximum length the payload can be for the receiver. This is part of the Message interface implementation.

type MwebHeader

type MwebHeader struct {
	Height        int32
	OutputRoot    chainhash.Hash
	KernelRoot    chainhash.Hash
	LeafsetRoot   chainhash.Hash
	KernelOffset  chainhash.Hash
	StealthOffset chainhash.Hash
	OutputMMRSize uint64
	KernelMMRSize uint64
}

The MWEB header struct

func (*MwebHeader) Hash

func (mh *MwebHeader) Hash() *chainhash.Hash

Hash of the mweb header

type MwebInput

type MwebInput struct {
	Features     MwebInputFeatureBit
	OutputId     chainhash.Hash
	Commitment   mw.Commitment
	InputPubKey  *mw.PublicKey
	OutputPubKey mw.PublicKey
	ExtraData    []byte
	Signature    mw.Signature
}

func (*MwebInput) Hash

func (mi *MwebInput) Hash() *chainhash.Hash

type MwebInputFeatureBit

type MwebInputFeatureBit byte
const (
	MwebInputStealthKeyFeatureBit MwebInputFeatureBit = 0x1
	MwebInputExtraDataFeatureBit  MwebInputFeatureBit = 0x2
)

type MwebKernel

type MwebKernel struct {
	Features      MwebKernelFeatureBit
	Fee           uint64
	Pegin         uint64
	Pegouts       []*TxOut
	LockHeight    int32
	StealthExcess mw.PublicKey
	ExtraData     []byte
	Excess        mw.Commitment
	Signature     mw.Signature
}

func (*MwebKernel) Hash

func (mk *MwebKernel) Hash() *chainhash.Hash

func (*MwebKernel) MessageHash

func (mk *MwebKernel) MessageHash() *chainhash.Hash

type MwebKernelFeatureBit

type MwebKernelFeatureBit byte
const (
	MwebKernelFeeFeatureBit MwebKernelFeatureBit = 1 << iota
	MwebKernelPeginFeatureBit
	MwebKernelPegoutFeatureBit
	MwebKernelHeightLockFeatureBit
	MwebKernelStealthExcessFeatureBit
	MwebKernelExtraDataFeatureBit

	MwebKernelAllFeatureBits = MwebKernelFeeFeatureBit |
		MwebKernelPeginFeatureBit | MwebKernelPegoutFeatureBit |
		MwebKernelHeightLockFeatureBit | MwebKernelStealthExcessFeatureBit |
		MwebKernelExtraDataFeatureBit
)

type MwebNetUtxo

type MwebNetUtxo struct {
	Height    int32 // memory only
	LeafIndex uint64
	Output    *MwebOutput
	OutputId  *chainhash.Hash
}

type MwebNetUtxoType

type MwebNetUtxoType byte
const (
	MwebNetUtxoFull MwebNetUtxoType = iota
	MwebNetUtxoHashOnly
	MwebNetUtxoCompact
)

type MwebOutput

type MwebOutput struct {
	Commitment     mw.Commitment
	SenderPubKey   mw.PublicKey
	ReceiverPubKey mw.PublicKey
	Message        MwebOutputMessage
	RangeProof     *mw.RangeProof
	RangeProofHash chainhash.Hash
	Signature      mw.Signature
	// contains filtered or unexported fields
}

func (*MwebOutput) Deserialize

func (mo *MwebOutput) Deserialize(r io.Reader) error

func (*MwebOutput) Hash

func (mo *MwebOutput) Hash() *chainhash.Hash

func (*MwebOutput) Serialize

func (mo *MwebOutput) Serialize(w io.Writer) error

type MwebOutputMessage

type MwebOutputMessage struct {
	Features          MwebOutputMessageFeatureBit
	KeyExchangePubKey mw.PublicKey
	ViewTag           byte
	MaskedValue       uint64
	MaskedNonce       big.Int
	ExtraData         []byte
}

func (*MwebOutputMessage) Deserialize

func (om *MwebOutputMessage) Deserialize(r io.Reader) error

func (*MwebOutputMessage) Hash

func (om *MwebOutputMessage) Hash() *chainhash.Hash

func (*MwebOutputMessage) Serialize

func (om *MwebOutputMessage) Serialize(w io.Writer) error

type MwebOutputMessageFeatureBit

type MwebOutputMessageFeatureBit byte
const (
	MwebOutputMessageStandardFieldsFeatureBit MwebOutputMessageFeatureBit = 0x1
	MwebOutputMessageExtraDataFeatureBit      MwebOutputMessageFeatureBit = 0x2
)

type MwebTx

type MwebTx struct {
	KernelOffset  mw.BlindingFactor
	StealthOffset mw.BlindingFactor
	TxBody        *MwebTxBody
}

type MwebTxBody

type MwebTxBody struct {
	Inputs  []*MwebInput
	Outputs []*MwebOutput
	Kernels []*MwebKernel
}

type NetAddress

type NetAddress struct {
	// Last time the address was seen.  This is, unfortunately, encoded as a
	// uint32 on the wire and therefore is limited to 2106.  This field is
	// not present in the litecoin version message (MsgVersion) nor was it
	// added until protocol version >= NetAddressTimeVersion.
	Timestamp time.Time

	// Bitfield which identifies the services supported by the address.
	Services ServiceFlag

	// IP address of the peer.
	IP net.IP

	// Port the peer is using.  This is encoded in big endian on the wire
	// which differs from most everything else.
	Port uint16
}

NetAddress defines information about a peer on the network including the time it was last seen, the services it supports, its IP address, and port.

func NewNetAddress

func NewNetAddress(addr *net.TCPAddr, services ServiceFlag) *NetAddress

NewNetAddress returns a new NetAddress using the provided TCP address and supported services with defaults for the remaining fields.

func NewNetAddressIPPort

func NewNetAddressIPPort(ip net.IP, port uint16, services ServiceFlag) *NetAddress

NewNetAddressIPPort returns a new NetAddress using the provided IP, port, and supported services with defaults for the remaining fields.

func NewNetAddressTimestamp

func NewNetAddressTimestamp(
	timestamp time.Time, services ServiceFlag, ip net.IP, port uint16) *NetAddress

NewNetAddressTimestamp returns a new NetAddress using the provided timestamp, IP, port, and supported services. The timestamp is rounded to single second precision.

func (*NetAddress) AddService

func (na *NetAddress) AddService(service ServiceFlag)

AddService adds service as a supported service by the peer generating the message.

func (*NetAddress) HasService

func (na *NetAddress) HasService(service ServiceFlag) bool

HasService returns whether the specified service is supported by the address.

type NetAddressV2

type NetAddressV2 struct {
	// Last time the address was seen. This is, unfortunately, encoded as a
	// uint32 on the wire and therefore is limited to 2106. This field is
	// not present in the litecoin version message (MsgVersion) nor was it
	// added until protocol version >= NetAddressTimeVersion.
	Timestamp time.Time

	// Services is a bitfield which identifies the services supported by
	// the address. This is encoded in CompactSize.
	Services ServiceFlag

	// Addr is the network address of the peer. This is a variable-length
	// address. Network() returns the BIP-155 networkID which is a uint8
	// encoded as a string. String() returns the address as a string.
	Addr net.Addr

	// Port is the port of the address. This is 0 if the network doesn't
	// use ports.
	Port uint16
}

NetAddressV2 defines information about a peer on the network including the last time it was seen, the services it supports, its address, and port. This struct is used in the addrv2 message (MsgAddrV2) and can contain larger addresses, like Tor. Additionally, it can contain any NetAddress address.

func NetAddressV2FromBytes

func NetAddressV2FromBytes(timestamp time.Time, services ServiceFlag,
	addrBytes []byte, port uint16) *NetAddressV2

NetAddressV2FromBytes creates a NetAddressV2 from a byte slice. It will also handle a torv2 address using the OnionCat encoding.

func (*NetAddressV2) AddService

func (na *NetAddressV2) AddService(service ServiceFlag)

AddService adds a service to the Services bitfield.

func (*NetAddressV2) HasService

func (na *NetAddressV2) HasService(service ServiceFlag) bool

HasService returns whether the specified service is supported by the address.

func (*NetAddressV2) IsTorV3

func (na *NetAddressV2) IsTorV3() bool

IsTorV3 returns a bool that signals to the caller whether or not this is a torv3 address.

func (*NetAddressV2) ToLegacy

func (na *NetAddressV2) ToLegacy() *NetAddress

ToLegacy attempts to convert a NetAddressV2 to a legacy NetAddress. This only works for ipv4, ipv6, or torv2 addresses as they can be encoded with the OnionCat encoding. If this method is called on a torv3 address, nil will be returned.

func (*NetAddressV2) TorV3Key

func (na *NetAddressV2) TorV3Key() byte

TorV3Key returns the first byte of the v3 public key. This is used in the addrmgr to calculate a key from a network group.

type OutPoint

type OutPoint struct {
	Hash  chainhash.Hash
	Index uint32
}

OutPoint defines a litecoin data type that is used to track previous transaction outputs.

func NewOutPoint

func NewOutPoint(hash *chainhash.Hash, index uint32) *OutPoint

NewOutPoint returns a new litecoin transaction outpoint point with the provided hash and index.

func NewOutPointFromString

func NewOutPointFromString(outpoint string) (*OutPoint, error)

NewOutPointFromString returns a new litecoin transaction outpoint parsed from the provided string, which should be in the format "hash:index".

func (OutPoint) String

func (o OutPoint) String() string

String returns the OutPoint in the human-readable form "hash:index".

type RejectCode

type RejectCode uint8

RejectCode represents a numeric value by which a remote peer indicates why a message was rejected.

const (
	RejectMalformed       RejectCode = 0x01
	RejectInvalid         RejectCode = 0x10
	RejectObsolete        RejectCode = 0x11
	RejectDuplicate       RejectCode = 0x12
	RejectNonstandard     RejectCode = 0x40
	RejectDust            RejectCode = 0x41
	RejectInsufficientFee RejectCode = 0x42
	RejectCheckpoint      RejectCode = 0x43
)

These constants define the various supported reject codes.

func (RejectCode) String

func (code RejectCode) String() string

String returns the RejectCode in human-readable form.

type ServiceFlag

type ServiceFlag uint64

ServiceFlag identifies services supported by a litecoin peer.

func (ServiceFlag) String

func (f ServiceFlag) String() string

String returns the ServiceFlag in human-readable form.

type TxFlag

type TxFlag = byte

TxFlag is the second byte of the FLAG field in a litecoin tx message. It indicates the decoding logic to use in the transaction parser, if TxFlagMarker is detected in the tx message.

As of writing this, only the witness flag (0x01) is supported, but may be extended in the future to accommodate auxiliary non-committed fields.

const (
	// WitnessFlag is a flag specific to witness encoding. If the TxFlagMarker
	// is encountered followed by the WitnessFlag, then it indicates a
	// transaction has witness data. This allows decoders to distinguish a
	// serialized transaction with witnesses from a legacy one.
	WitnessFlag TxFlag = 0x01
	MwebFlag    TxFlag = 0x08
)

type TxIn

type TxIn struct {
	PreviousOutPoint OutPoint
	SignatureScript  []byte
	Witness          TxWitness
	Sequence         uint32
}

TxIn defines a litecoin transaction input.

func NewTxIn

func NewTxIn(prevOut *OutPoint, signatureScript []byte, witness [][]byte) *TxIn

NewTxIn returns a new litecoin transaction input with the provided previous outpoint point and signature script with a default sequence of MaxTxInSequenceNum.

func (*TxIn) SerializeSize

func (t *TxIn) SerializeSize() int

SerializeSize returns the number of bytes it would take to serialize the the transaction input.

type TxLoc

type TxLoc struct {
	TxStart int
	TxLen   int
}

TxLoc holds locator data for the offset and length of where a transaction is located within a MsgBlock data buffer.

type TxOut

type TxOut struct {
	Value    int64
	PkScript []byte
}

TxOut defines a litecoin transaction output.

func NewTxOut

func NewTxOut(value int64, pkScript []byte) *TxOut

NewTxOut returns a new litecoin transaction output with the provided transaction value and public key script.

func (*TxOut) SerializeSize

func (t *TxOut) SerializeSize() int

SerializeSize returns the number of bytes it would take to serialize the the transaction output.

type TxWitness

type TxWitness [][]byte

TxWitness defines the witness for a TxIn. A witness is to be interpreted as a slice of byte slices, or a stack with one or many elements.

func (TxWitness) SerializeSize

func (t TxWitness) SerializeSize() int

SerializeSize returns the number of bytes it would take to serialize the transaction input's witness.

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