lbcd/wire/msgblock.go
Dave Collins bd4e64d1d4 chainhash: Abstract hash logic to new package. (#729)
This is mostly a backport of some of the same modifications made in
Decred along with a few additional things cleaned up.  In particular,
this updates the code to make use of the new chainhash package.

Also, since this required API changes anyways and the hash algorithm is
no longer tied specifically to SHA, all other functions throughout the
code base which had "Sha" in their name have been changed to Hash so
they are not incorrectly implying the hash algorithm.

The following is an overview of the changes:

- Remove the wire.ShaHash type
- Update all references to wire.ShaHash to the new chainhash.Hash type
- Rename the following functions and update all references:
  - wire.BlockHeader.BlockSha -> BlockHash
  - wire.MsgBlock.BlockSha -> BlockHash
  - wire.MsgBlock.TxShas -> TxHashes
  - wire.MsgTx.TxSha -> TxHash
  - blockchain.ShaHashToBig -> HashToBig
  - peer.ShaFunc -> peer.HashFunc
- Rename all variables that included sha in their name to include hash
  instead
- Update for function name changes in other dependent packages such as
  btcutil
- Update copyright dates on all modified files
- Update glide.lock file to use the required version of btcutil
2016-08-08 14:04:33 -05:00

250 lines
8.5 KiB
Go

// Copyright (c) 2013-2016 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package wire
import (
"bytes"
"fmt"
"io"
"github.com/btcsuite/btcd/chaincfg/chainhash"
)
// defaultTransactionAlloc is the default size used for the backing array
// for transactions. The transaction array will dynamically grow as needed, but
// this figure is intended to provide enough space for the number of
// transactions in the vast majority of blocks without needing to grow the
// backing array multiple times.
const defaultTransactionAlloc = 2048
// MaxBlocksPerMsg is the maximum number of blocks allowed per message.
const MaxBlocksPerMsg = 500
// MaxBlockPayload is the maximum bytes a block message can be in bytes.
const MaxBlockPayload = 1000000 // Not actually 1MB which would be 1024 * 1024
// maxTxPerBlock is the maximum number of transactions that could
// possibly fit into a block.
const maxTxPerBlock = (MaxBlockPayload / minTxPayload) + 1
// TxLoc holds locator data for the offset and length of where a transaction is
// located within a MsgBlock data buffer.
type TxLoc struct {
TxStart int
TxLen int
}
// MsgBlock implements the Message interface and represents a bitcoin
// block message. It is used to deliver block and transaction information in
// response to a getdata message (MsgGetData) for a given block hash.
type MsgBlock struct {
Header BlockHeader
Transactions []*MsgTx
}
// AddTransaction adds a transaction to the message.
func (msg *MsgBlock) AddTransaction(tx *MsgTx) error {
msg.Transactions = append(msg.Transactions, tx)
return nil
}
// ClearTransactions removes all transactions from the message.
func (msg *MsgBlock) ClearTransactions() {
msg.Transactions = make([]*MsgTx, 0, defaultTransactionAlloc)
}
// BtcDecode decodes r using the bitcoin 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 (msg *MsgBlock) BtcDecode(r io.Reader, pver uint32) error {
err := readBlockHeader(r, pver, &msg.Header)
if err != nil {
return err
}
txCount, err := ReadVarInt(r, pver)
if err != nil {
return err
}
// Prevent more transactions than could possibly fit into a block.
// It would be possible to cause memory exhaustion and panics without
// a sane upper bound on this count.
if txCount > maxTxPerBlock {
str := fmt.Sprintf("too many transactions to fit into a block "+
"[count %d, max %d]", txCount, maxTxPerBlock)
return messageError("MsgBlock.BtcDecode", str)
}
msg.Transactions = make([]*MsgTx, 0, txCount)
for i := uint64(0); i < txCount; i++ {
tx := MsgTx{}
err := tx.BtcDecode(r, pver)
if err != nil {
return err
}
msg.Transactions = append(msg.Transactions, &tx)
}
return nil
}
// 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 bitcoin 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 (msg *MsgBlock) Deserialize(r io.Reader) error {
// At the current time, there is no difference between the wire encoding
// at protocol version 0 and the stable long-term storage format. As
// a result, make use of BtcDecode.
return msg.BtcDecode(r, 0)
}
// 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 (msg *MsgBlock) DeserializeTxLoc(r *bytes.Buffer) ([]TxLoc, error) {
fullLen := r.Len()
// At the current time, there is no difference between the wire encoding
// at protocol version 0 and the stable long-term storage format. As
// a result, make use of existing wire protocol functions.
err := readBlockHeader(r, 0, &msg.Header)
if err != nil {
return nil, err
}
txCount, err := ReadVarInt(r, 0)
if err != nil {
return nil, err
}
// Prevent more transactions than could possibly fit into a block.
// It would be possible to cause memory exhaustion and panics without
// a sane upper bound on this count.
if txCount > maxTxPerBlock {
str := fmt.Sprintf("too many transactions to fit into a block "+
"[count %d, max %d]", txCount, maxTxPerBlock)
return nil, messageError("MsgBlock.DeserializeTxLoc", str)
}
// Deserialize each transaction while keeping track of its location
// within the byte stream.
msg.Transactions = make([]*MsgTx, 0, txCount)
txLocs := make([]TxLoc, txCount)
for i := uint64(0); i < txCount; i++ {
txLocs[i].TxStart = fullLen - r.Len()
tx := MsgTx{}
err := tx.Deserialize(r)
if err != nil {
return nil, err
}
msg.Transactions = append(msg.Transactions, &tx)
txLocs[i].TxLen = (fullLen - r.Len()) - txLocs[i].TxStart
}
return txLocs, nil
}
// BtcEncode encodes the receiver to w using the bitcoin 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 (msg *MsgBlock) BtcEncode(w io.Writer, pver uint32) error {
err := writeBlockHeader(w, pver, &msg.Header)
if err != nil {
return err
}
err = WriteVarInt(w, pver, uint64(len(msg.Transactions)))
if err != nil {
return err
}
for _, tx := range msg.Transactions {
err = tx.BtcEncode(w, pver)
if err != nil {
return err
}
}
return nil
}
// 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 bitcoin 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 (msg *MsgBlock) Serialize(w io.Writer) error {
// At the current time, there is no difference between the wire encoding
// at protocol version 0 and the stable long-term storage format. As
// a result, make use of BtcEncode.
return msg.BtcEncode(w, 0)
}
// SerializeSize returns the number of bytes it would take to serialize the
// the block.
func (msg *MsgBlock) SerializeSize() int {
// Block header bytes + Serialized varint size for the number of
// transactions.
n := blockHeaderLen + VarIntSerializeSize(uint64(len(msg.Transactions)))
for _, tx := range msg.Transactions {
n += tx.SerializeSize()
}
return n
}
// Command returns the protocol command string for the message. This is part
// of the Message interface implementation.
func (msg *MsgBlock) Command() string {
return CmdBlock
}
// MaxPayloadLength returns the maximum length the payload can be for the
// receiver. This is part of the Message interface implementation.
func (msg *MsgBlock) MaxPayloadLength(pver uint32) uint32 {
// Block header at 80 bytes + transaction count + max transactions
// which can vary up to the MaxBlockPayload (including the block header
// and transaction count).
return MaxBlockPayload
}
// BlockHash computes the block identifier hash for this block.
func (msg *MsgBlock) BlockHash() chainhash.Hash {
return msg.Header.BlockHash()
}
// TxHashes returns a slice of hashes of all of transactions in this block.
func (msg *MsgBlock) TxHashes() ([]chainhash.Hash, error) {
hashList := make([]chainhash.Hash, 0, len(msg.Transactions))
for _, tx := range msg.Transactions {
hashList = append(hashList, tx.TxHash())
}
return hashList, nil
}
// NewMsgBlock returns a new bitcoin block message that conforms to the
// Message interface. See MsgBlock for details.
func NewMsgBlock(blockHeader *BlockHeader) *MsgBlock {
return &MsgBlock{
Header: *blockHeader,
Transactions: make([]*MsgTx, 0, defaultTransactionAlloc),
}
}