177 lines
5.8 KiB
Go
177 lines
5.8 KiB
Go
package autopilot
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import (
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prand "math/rand"
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"net"
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"time"
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"github.com/btcsuite/btcd/btcec"
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"github.com/btcsuite/btcutil"
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)
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// ConstrainedPrefAttachment is an implementation of the AttachmentHeuristic
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// interface that implement a constrained non-linear preferential attachment
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// heuristic. This means that given a threshold to allocate to automatic
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// channel establishment, the heuristic will attempt to favor connecting to
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// nodes which already have a set amount of links, selected by sampling from a
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// power law distribution. The attachment is non-linear in that it favors
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// nodes with a higher in-degree but less so that regular linear preferential
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// attachment. As a result, this creates smaller and less clusters than regular
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// linear preferential attachment.
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//
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// TODO(roasbeef): BA, with k=-3
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type ConstrainedPrefAttachment struct {
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constraints *HeuristicConstraints
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}
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// NewConstrainedPrefAttachment creates a new instance of a
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// ConstrainedPrefAttachment heuristics given bounds on allowed channel sizes,
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// and an allocation amount which is interpreted as a percentage of funds that
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// is to be committed to channels at all times.
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func NewConstrainedPrefAttachment(
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cfg *HeuristicConstraints) *ConstrainedPrefAttachment {
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prand.Seed(time.Now().Unix())
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return &ConstrainedPrefAttachment{
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constraints: cfg,
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}
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}
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// A compile time assertion to ensure ConstrainedPrefAttachment meets the
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// AttachmentHeuristic interface.
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var _ AttachmentHeuristic = (*ConstrainedPrefAttachment)(nil)
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// NeedMoreChans is a predicate that should return true if, given the passed
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// parameters, and its internal state, more channels should be opened within
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// the channel graph. If the heuristic decides that we do indeed need more
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// channels, then the second argument returned will represent the amount of
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// additional funds to be used towards creating channels.
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//
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// NOTE: This is a part of the AttachmentHeuristic interface.
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func (p *ConstrainedPrefAttachment) NeedMoreChans(channels []Channel,
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funds btcutil.Amount) (btcutil.Amount, uint32, bool) {
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// We'll try to open more channels as long as the constraints allow it.
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availableFunds, availableChans := p.constraints.availableChans(
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channels, funds,
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)
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return availableFunds, availableChans, availableChans > 0
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}
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// NodeID is a simple type that holds an EC public key serialized in compressed
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// format.
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type NodeID [33]byte
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// NewNodeID creates a new nodeID from a passed public key.
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func NewNodeID(pub *btcec.PublicKey) NodeID {
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var n NodeID
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copy(n[:], pub.SerializeCompressed())
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return n
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}
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// NodeScores is a method that given the current channel graph, current set of
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// local channels and funds available, scores the given nodes according the the
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// preference of opening a channel with them.
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//
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// The heuristic employed by this method is one that attempts to promote a
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// scale-free network globally, via local attachment preferences for new nodes
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// joining the network with an amount of available funds to be allocated to
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// channels. Specifically, we consider the degree of each node (and the flow
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// in/out of the node available via its open channels) and utilize the
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// Barabási–Albert model to drive our recommended attachment heuristics. If
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// implemented globally for each new participant, this results in a channel
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// graph that is scale-free and follows a power law distribution with k=-3.
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//
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// The returned scores will be in the range [0.0, 1.0], where higher scores are
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// given to nodes already having high connectivity in the graph.
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//
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// NOTE: This is a part of the AttachmentHeuristic interface.
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func (p *ConstrainedPrefAttachment) NodeScores(g ChannelGraph, chans []Channel,
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fundsAvailable btcutil.Amount, nodes map[NodeID]struct{}) (
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map[NodeID]*AttachmentDirective, error) {
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// Count the number of channels in the graph. We'll also count the
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// number of channels as we go for the nodes we are interested in, and
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// record their addresses found in the db.
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var graphChans int
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nodeChanNum := make(map[NodeID]int)
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addresses := make(map[NodeID][]net.Addr)
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if err := g.ForEachNode(func(n Node) error {
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var nodeChans int
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err := n.ForEachChannel(func(_ ChannelEdge) error {
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nodeChans++
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graphChans++
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return nil
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})
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if err != nil {
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return err
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}
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// If this node is not among our nodes to score, we can return
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// early.
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nID := NodeID(n.PubKey())
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if _, ok := nodes[nID]; !ok {
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return nil
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}
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// Otherwise we'll record the number of channels, and also
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// populate the address in our channel candidates map.
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nodeChanNum[nID] = nodeChans
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addresses[nID] = n.Addrs()
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return nil
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}); err != nil {
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return nil, err
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}
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// If there are no channels in the graph we cannot determine any
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// preferences, so we return, indicating all candidates get a score of
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// zero.
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if graphChans == 0 {
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return nil, nil
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}
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existingPeers := make(map[NodeID]struct{})
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for _, c := range chans {
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existingPeers[c.Node] = struct{}{}
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}
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// For each node in the set of nodes, count their fraction of channels
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// in the graph, and use that as the score.
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candidates := make(map[NodeID]*AttachmentDirective)
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for nID, nodeChans := range nodeChanNum {
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// As channel size we'll use the maximum channel size available.
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chanSize := p.constraints.MaxChanSize
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if fundsAvailable-chanSize < 0 {
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chanSize = fundsAvailable
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}
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_, ok := existingPeers[nID]
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switch {
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// If the node is among or existing channel peers, we don't
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// need another channel.
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case ok:
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continue
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// If the amount is too small, we don't want to attempt opening
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// another channel.
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case chanSize == 0 || chanSize < p.constraints.MinChanSize:
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continue
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}
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// Otherwise we score the node according to its fraction of
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// channels in the graph.
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score := float64(nodeChans) / float64(graphChans)
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candidates[nID] = &AttachmentDirective{
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NodeID: nID,
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ChanAmt: chanSize,
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Score: score,
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}
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}
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return candidates, nil
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}
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