| public static ReverseBytes ( byte bytes ) : byte[] | ||
| bytes | byte | |
| return | byte[] | |
/// <exception cref="ProtocolException"/>
protected override void Parse()
{
_version = ReadUint32();
_prevBlockHash = ReadHash();
_merkleRoot = ReadHash();
_time = ReadUint32();
_difficultyTarget = ReadUint32();
_nonce = ReadUint32();
_hash = new Sha256Hash(Utils.ReverseBytes(Utils.DoubleDigest(Bytes, 0, Cursor)));
if (Cursor == Bytes.Length)
{
// This message is just a header, it has no transactions.
return;
}
var numTransactions = (int)ReadVarInt();
Transactions = new List <Transaction>(numTransactions);
for (var i = 0; i < numTransactions; i++)
{
var tx = new Transaction(Params, Bytes, Cursor);
Transactions.Add(tx);
Cursor += tx.MessageSize;
}
}
private IList <byte[]> BuildMerkleTree()
{
// The Merkle root is based on a tree of hashes calculated from the transactions:
//
// root
// /\
// / \
// A B
// / \ / \
// t1 t2 t3 t4
//
// The tree is represented as a list: t1,t2,t3,t4,A,B,root where each entry is a hash.
//
// The hashing algorithm is double SHA-256. The leaves are a hash of the serialized contents of the
// transaction. The interior nodes are hashes of the concentration of the two child hashes.
//
// This structure allows the creation of proof that a transaction was included into a block without having to
// provide the full block contents. Instead, you can provide only a Merkle branch. For example to prove tx2 was
// in a block you can just provide tx2, the hash(tx1) and B. Now the other party has everything they need to
// derive the root, which can be checked against the block header. These proofs aren't used right now but
// will be helpful later when we want to download partial block contents.
//
// Note that if the number of transactions is not even the last tx is repeated to make it so (see
// tx3 above). A tree with 5 transactions would look like this:
//
// root
// / \
// 1 \
// / \ \
// 2 3 4
// / \ / \ / \
// t1 t2 t3 t4 t5 t5
var tree = new List <byte[]>();
// Start by adding all the hashes of the transactions as leaves of the tree.
foreach (var t in Transactions)
{
tree.Add(t.Hash.Bytes);
}
var levelOffset = 0; // Offset in the list where the currently processed level starts.
// Step through each level, stopping when we reach the root (levelSize == 1).
for (var levelSize = Transactions.Count; levelSize > 1; levelSize = (levelSize + 1) / 2)
{
// For each pair of nodes on that level:
for (var left = 0; left < levelSize; left += 2)
{
// The right hand node can be the same as the left hand, in the case where we don't have enough
// transactions.
var right = Math.Min(left + 1, levelSize - 1);
var leftBytes = Utils.ReverseBytes(tree[levelOffset + left]);
var rightBytes = Utils.ReverseBytes(tree[levelOffset + right]);
tree.Add(Utils.ReverseBytes(Utils.DoubleDigestTwoBuffers(leftBytes, 0, 32, rightBytes, 0, 32)));
}
// Move to the next level.
levelOffset += levelSize;
}
return(tree);
}
/// <summary>
/// Calculates the block hash by serializing the block and hashing the resulting bytes.
/// </summary>
private Sha256Hash CalculateHash()
{
using (var bos = new MemoryStream())
{
WriteHeader(bos);
return(new Sha256Hash(Utils.ReverseBytes(Utils.DoubleDigest(bos.ToArray()))));
}
}
/// <exception cref="IOException"/>
private void WriteHeader(Stream stream)
{
Utils.Uint32ToByteStreamLe(_version, stream);
stream.Write(Utils.ReverseBytes(_prevBlockHash.Bytes));
stream.Write(Utils.ReverseBytes(MerkleRoot.Bytes));
Utils.Uint32ToByteStreamLe(_time, stream);
Utils.Uint32ToByteStreamLe(_difficultyTarget, stream);
Utils.Uint32ToByteStreamLe(_nonce, stream);
}
internal Sha256Hash ReadHash()
{
var hash = new byte[32];
Array.Copy(Bytes, Cursor, hash, 0, 32);
// We have to flip it around, as it's been read off the wire in little endian.
// Not the most efficient way to do this but the clearest.
hash = Utils.ReverseBytes(hash);
Cursor += 32;
return(new Sha256Hash(hash));
}
/// <exception cref="IOException"/>
public override void BitcoinSerializeToStream(Stream stream)
{
stream.Write(new VarInt((ulong)_items.Count).Encode());
foreach (var i in _items)
{
// Write out the type code.
Utils.Uint32ToByteStreamLe((uint)i.Type, stream);
// And now the hash.
stream.Write(Utils.ReverseBytes(i.Hash.Bytes));
}
}
public override byte[] BitcoinSerialize()
{
using (var buf = new MemoryStream())
{
// Version, for some reason.
Utils.Uint32ToByteStreamLe(NetworkParameters.ProtocolVersion, buf);
// Then a vector of block hashes. This is actually a "block locator", a set of block
// identifiers that spans the entire chain with exponentially increasing gaps between
// them, until we end up at the genesis block. See CBlockLocator::Set()
buf.Write(new VarInt((ulong)_locator.Count).Encode());
foreach (var hash in _locator)
{
// Have to reverse as wire format is little endian.
buf.Write(Utils.ReverseBytes(hash.Bytes));
}
// Next, a block ID to stop at.
buf.Write(_stopHash.Bytes);
return(buf.ToArray());
}
}
/// <exception cref="IOException"/>
public override void BitcoinSerializeToStream(Stream stream)
{
stream.Write(Utils.ReverseBytes(Hash.Bytes));
Utils.Uint32ToByteStreamLe((uint)Index, stream);
}