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// Package discover implements the Node Discovery Protocol.
//
// The Node Discovery protocol provides a way to find RLPx nodes that
// can be connected to. It uses a Kademlia-like protocol to maintain a
// distributed database of the IDs and endpoints of all listening
// nodes.
package discover

import (
    "net"
    "sort"
    "sync"
    "time"
)

const (
    alpha      = 3              // Kademlia concurrency factor
    bucketSize = 16             // Kademlia bucket size
    nBuckets   = nodeIDBits + 1 // Number of buckets
)

type Table struct {
    mutex   sync.Mutex        // protects buckets, their content, and nursery
    buckets [nBuckets]*bucket // index of known nodes by distance
    nursery []*Node           // bootstrap nodes

    net  transport
    self *Node // metadata of the local node
}

// transport is implemented by the UDP transport.
// it is an interface so we can test without opening lots of UDP
// sockets and without generating a private key.
type transport interface {
    ping(*Node) error
    findnode(e *Node, target NodeID) ([]*Node, error)
    close()
}

// bucket contains nodes, ordered by their last activity.
type bucket struct {
    lastLookup time.Time
    entries    []*Node
}

func newTable(t transport, ourID NodeID, ourAddr *net.UDPAddr) *Table {
    tab := &Table{net: t, self: newNode(ourID, ourAddr)}
    for i := range tab.buckets {
        tab.buckets[i] = new(bucket)
    }
    return tab
}

// Self returns the local node.
func (tab *Table) Self() *Node {
    return tab.self
}

// Close terminates the network listener.
func (tab *Table) Close() {
    tab.net.close()
}

// Bootstrap sets the bootstrap nodes. These nodes are used to connect
// to the network if the table is empty. Bootstrap will also attempt to
// fill the table by performing random lookup operations on the
// network.
func (tab *Table) Bootstrap(nodes []*Node) {
    tab.mutex.Lock()
    // TODO: maybe filter nodes with bad fields (nil, etc.) to avoid strange crashes
    tab.nursery = make([]*Node, 0, len(nodes))
    for _, n := range nodes {
        cpy := *n
        tab.nursery = append(tab.nursery, &cpy)
    }
    tab.mutex.Unlock()
    tab.refresh()
}

// Lookup performs a network search for nodes close
// to the given target. It approaches the target by querying
// nodes that are closer to it on each iteration.
func (tab *Table) Lookup(target NodeID) []*Node {
    var (
        asked          = make(map[NodeID]bool)
        seen           = make(map[NodeID]bool)
        reply          = make(chan []*Node, alpha)
        pendingQueries = 0
    )
    // don't query further if we hit the target or ourself.
    // unlikely to happen often in practice.
    asked[target] = true
    asked[tab.self.ID] = true

    tab.mutex.Lock()
    // update last lookup stamp (for refresh logic)
    tab.buckets[logdist(tab.self.ID, target)].lastLookup = time.Now()
    // generate initial result set
    result := tab.closest(target, bucketSize)
    tab.mutex.Unlock()

    for {
        // ask the alpha closest nodes that we haven't asked yet
        for i := 0; i < len(result.entries) && pendingQueries < alpha; i++ {
            n := result.entries[i]
            if !asked[n.ID] {
                asked[n.ID] = true
                pendingQueries++
                go func() {
                    result, _ := tab.net.findnode(n, target)
                    reply <- result
                }()
            }
        }
        if pendingQueries == 0 {
            // we have asked all closest nodes, stop the search
            break
        }

        // wait for the next reply
        for _, n := range <-reply {
            cn := n
            if !seen[n.ID] {
                seen[n.ID] = true
                result.push(cn, bucketSize)
            }
        }
        pendingQueries--
    }
    return result.entries
}

// refresh performs a lookup for a random target to keep buckets full.
func (tab *Table) refresh() {
    ld := -1 // logdist of chosen bucket
    tab.mutex.Lock()
    for i, b := range tab.buckets {
        if i > 0 && b.lastLookup.Before(time.Now().Add(-1*time.Hour)) {
            ld = i
            break
        }
    }
    tab.mutex.Unlock()

    result := tab.Lookup(randomID(tab.self.ID, ld))
    if len(result) == 0 {
        // bootstrap the table with a self lookup
        tab.mutex.Lock()
        tab.add(tab.nursery)
        tab.mutex.Unlock()
        tab.Lookup(tab.self.ID)
        // TODO: the Kademlia paper says that we're supposed to perform
        // random lookups in all buckets further away than our closest neighbor.
    }
}

// closest returns the n nodes in the table that are closest to the
// given id. The caller must hold tab.mutex.
func (tab *Table) closest(target NodeID, nresults int) *nodesByDistance {
    // This is a very wasteful way to find the closest nodes but
    // obviously correct. I believe that tree-based buckets would make
    // this easier to implement efficiently.
    close := &nodesByDistance{target: target}
    for _, b := range tab.buckets {
        for _, n := range b.entries {
            close.push(n, nresults)
        }
    }
    return close
}

func (tab *Table) len() (n int) {
    for _, b := range tab.buckets {
        n += len(b.entries)
    }
    return n
}

// bumpOrAdd updates the activity timestamp for the given node and
// attempts to insert the node into a bucket. The returned Node might
// not be part of the table. The caller must hold tab.mutex.
func (tab *Table) bumpOrAdd(node NodeID, from *net.UDPAddr) (n *Node) {
    b := tab.buckets[logdist(tab.self.ID, node)]
    if n = b.bump(node); n == nil {
        n = newNode(node, from)
        if len(b.entries) == bucketSize {
            tab.pingReplace(n, b)
        } else {
            b.entries = append(b.entries, n)
        }
    }
    return n
}

func (tab *Table) pingReplace(n *Node, b *bucket) {
    old := b.entries[bucketSize-1]
    go func() {
        if err := tab.net.ping(old); err == nil {
            // it responded, we don't need to replace it.
            return
        }
        // it didn't respond, replace the node if it is still the oldest node.
        tab.mutex.Lock()
        if len(b.entries) > 0 && b.entries[len(b.entries)-1] == old {
            // slide down other entries and put the new one in front.
            // TODO: insert in correct position to keep the order
            copy(b.entries[1:], b.entries)
            b.entries[0] = n
        }
        tab.mutex.Unlock()
    }()
}

// bump updates the activity timestamp for the given node.
// The caller must hold tab.mutex.
func (tab *Table) bump(node NodeID) {
    tab.buckets[logdist(tab.self.ID, node)].bump(node)
}

// add puts the entries into the table if their corresponding
// bucket is not full. The caller must hold tab.mutex.
func (tab *Table) add(entries []*Node) {
outer:
    for _, n := range entries {
        if n == nil || n.ID == tab.self.ID {
            // skip bad entries. The RLP decoder returns nil for empty
            // input lists.
            continue
        }
        bucket := tab.buckets[logdist(tab.self.ID, n.ID)]
        for i := range bucket.entries {
            if bucket.entries[i].ID == n.ID {
                // already in bucket
                continue outer
            }
        }
        if len(bucket.entries) < bucketSize {
            bucket.entries = append(bucket.entries, n)
        }
    }
}

func (b *bucket) bump(id NodeID) *Node {
    for i, n := range b.entries {
        if n.ID == id {
            n.active = time.Now()
            // move it to the front
            copy(b.entries[1:], b.entries[:i+1])
            b.entries[0] = n
            return n
        }
    }
    return nil
}

// nodesByDistance is a list of nodes, ordered by
// distance to target.
type nodesByDistance struct {
    entries []*Node
    target  NodeID
}

// push adds the given node to the list, keeping the total size below maxElems.
func (h *nodesByDistance) push(n *Node, maxElems int) {
    ix := sort.Search(len(h.entries), func(i int) bool {
        return distcmp(h.target, h.entries[i].ID, n.ID) > 0
    })
    if len(h.entries) < maxElems {
        h.entries = append(h.entries, n)
    }
    if ix == len(h.entries) {
        // farther away than all nodes we already have.
        // if there was room for it, the node is now the last element.
    } else {
        // slide existing entries down to make room
        // this will overwrite the entry we just appended.
        copy(h.entries[ix+1:], h.entries[ix:])
        h.entries[ix] = n
    }
}