コード例 #1
0
ファイル: example.go プロジェクト: skycoin/skycoin
////////////////////////////////////////////////////////////////////////////////
//
//
//
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// The body of this function lends itself to something like
//
//    ConsensusParticipant::BuildAndPropagateNewBlock()
//
// Before doing so, ConsensusParticipant would need to accumulate
// transactions, possibly negotiate with others as to who makes blocks
// etc. FOR NOW, any node can make (and publish) blocks.
//
func propagate_hash_from_node(
	h cipher.SHA256,
	nodePtr *consensus.ConsensusParticipant,
	external_use bool,
	external_seqno uint64) {

	//
	// WARNING: Do NOT use this code for obtaining any research
	// results.  This file is only an illustration. A realistic
	// simulation require to have nonzero latencies for event
	// propagation and to have an event queueu inside the
	// implementation of MeshNetworkInterface.
	//

	o := external_seqno // HACK for DEBUGGING
	if !external_use {
		o = nodePtr.GetNextBlockSeqNo() // So that blocks are ordered.
	}

	b := consensus.BlockBase{}
	b.Init(
		nodePtr.SignatureOf(h), // Signature of hash.
		h,
		o)

	nodePtr.OnBlockHeaderArrived(&b)
}
コード例 #2
0
ファイル: example_gnet.go プロジェクト: skycoin/skycoin
func (self *PoolOwner) DataCallback(context *gnet.MessageContext, xxx *BlockBaseWrapper) {

	if self.isConnSolicited[context.Conn.Addr()] {

		var msg consensus.BlockBase
		msg.Sig = xxx.Sig
		msg.Hash = xxx.Hash
		msg.Seqno = xxx.Seqno

		self.pCMan.GetNode().OnBlockHeaderArrived(&msg)

	} else {
		// Ignoring
	}
}
コード例 #3
0
ファイル: example_minimal.go プロジェクト: skycoin/skycoin
////////////////////////////////////////////////////////////////////////////////
//
// main
//
////////////////////////////////////////////////////////////////////////////////
func main() {

	var X []*MinimalConnectionManager

	// Create nodes
	for i := 0; i < Cfg_simu_num_node; i++ {
		cm := MinimalConnectionManager{}
		// Reason for mutual registration: (1) when conn man receives
		// messages, it needs to notify the node; (2) when node has
		// processed a mesage, it might need to use conn man to send
		// some data out.
		nodePtr := consensus.NewConsensusParticipantPtr(&cm)
		cm.theNodePtr = nodePtr

		X = append(X, &cm)
	}

	// Contemplate connecting nodes into a thick circle:
	n := len(X)
	for i := 0; i < n; i++ {

		cm := X[i]

		c_left := int(Cfg_simu_fanout_per_node / 2)
		c_right := Cfg_simu_fanout_per_node - c_left

		for c := 0; c < c_left; c++ {
			j := (i - 1 - c + n) % n
			cm.RegisterPublisher(X[j])
		}

		for c := 0; c < c_right; c++ {
			j := (i + 1 + c) % n
			cm.RegisterPublisher(X[j])
		}
	}

	//
	// Request connections
	//
	for i := 0; i < n; i++ {
		X[i].RequestConnectionToAllMyPublisher()
	}

	{
		//
		// Choose a node to be a block-maker
		//
		index := mathrand.Intn(Cfg_simu_num_node)
		nodePtr := X[index].GetNode()

		//
		// Make a block (actually, only a header)
		//
		x := secp256k1.RandByte(888) // Random data.
		h := cipher.SumSHA256(x)     // Its hash.
		b := consensus.BlockBase{}
		b.Init(
			nodePtr.SignatureOf(h),
			h,
			0)

		//
		// Send it to subscribers. The subscribers are also publishers;
		// they send (forward, to be exact) the header to thire respective
		// listeners etc.
		//
		nodePtr.OnBlockHeaderArrived(&b)
	}

	//
	// Print the state of each node for a review or debugging.
	//
	for i, _ := range X {
		fmt.Printf("FILE_FinalState.txt|NODE i=%d ", i)
		X[i].GetNode().Print()
		fmt.Printf("\n")
	}

}