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249 lines
7.5 KiB
Go
249 lines
7.5 KiB
Go
1 year ago
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// Copyright (c) Tailscale Inc & AUTHORS
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// SPDX-License-Identifier: BSD-3-Clause
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package magicsock
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import (
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"net/netip"
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"slices"
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"sync"
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"time"
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"tailscale.com/tailcfg"
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"tailscale.com/tempfork/heap"
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"tailscale.com/util/mak"
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"tailscale.com/util/set"
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)
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const (
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// endpointTrackerLifetime is how long we continue advertising an
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// endpoint after we last see it. This is intentionally chosen to be
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// slightly longer than a full netcheck period.
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endpointTrackerLifetime = 5*time.Minute + 10*time.Second
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// endpointTrackerMaxPerAddr is how many cached addresses we track for
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// a given netip.Addr. This allows e.g. restricting the number of STUN
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// endpoints we cache (which usually have the same netip.Addr but
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// different ports).
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//
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// The value of 6 is chosen because we can advertise up to 3 endpoints
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// based on the STUN IP:
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// 1. The STUN endpoint itself (EndpointSTUN)
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// 2. The STUN IP with the local Tailscale port (EndpointSTUN4LocalPort)
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// 3. The STUN IP with a portmapped port (EndpointPortmapped)
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//
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// Storing 6 endpoints in the cache means we can store up to 2 previous
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// sets of endpoints.
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endpointTrackerMaxPerAddr = 6
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)
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// endpointTrackerEntry is an entry in an endpointHeap that stores the state of
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// a given cached endpoint.
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type endpointTrackerEntry struct {
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// endpoint is the cached endpoint.
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endpoint tailcfg.Endpoint
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// until is the time until which this endpoint is being cached.
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until time.Time
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// index is the index within the containing endpointHeap.
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index int
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}
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// endpointHeap is an ordered heap of endpointTrackerEntry structs, ordered in
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// ascending order by the 'until' expiry time (i.e. oldest first).
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type endpointHeap []*endpointTrackerEntry
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var _ heap.Interface[*endpointTrackerEntry] = (*endpointHeap)(nil)
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// Len implements heap.Interface.
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func (eh endpointHeap) Len() int { return len(eh) }
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// Less implements heap.Interface.
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func (eh endpointHeap) Less(i, j int) bool {
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// We want to store items so that the lowest item in the heap is the
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// oldest, so that heap.Pop()-ing from the endpointHeap will remove the
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// oldest entry.
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return eh[i].until.Before(eh[j].until)
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}
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// Swap implements heap.Interface.
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func (eh endpointHeap) Swap(i, j int) {
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eh[i], eh[j] = eh[j], eh[i]
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eh[i].index = i
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eh[j].index = j
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}
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// Push implements heap.Interface.
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func (eh *endpointHeap) Push(item *endpointTrackerEntry) {
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n := len(*eh)
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item.index = n
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*eh = append(*eh, item)
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}
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// Pop implements heap.Interface.
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func (eh *endpointHeap) Pop() *endpointTrackerEntry {
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old := *eh
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n := len(old)
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item := old[n-1]
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old[n-1] = nil // avoid memory leak
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item.index = -1 // for safety
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*eh = old[0 : n-1]
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return item
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}
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// Min returns a pointer to the minimum element in the heap, without removing
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// it. Since this is a min-heap ordered by the 'until' field, this returns the
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// chronologically "earliest" element in the heap.
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//
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// Len() must be non-zero.
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func (eh endpointHeap) Min() *endpointTrackerEntry {
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return eh[0]
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}
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// endpointTracker caches endpoints that are advertised to peers. This allows
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// peers to still reach this node if there's a temporary endpoint flap; rather
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// than withdrawing an endpoint and then re-advertising it the next time we run
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// a netcheck, we keep advertising the endpoint until it's not present for a
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// defined timeout.
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//
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// See tailscale/tailscale#7877 for more information.
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type endpointTracker struct {
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mu sync.Mutex
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endpoints map[netip.Addr]*endpointHeap
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}
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// update takes as input the current sent of discovered endpoints and the
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// current time, and returns the set of endpoints plus any previous-cached and
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// non-expired endpoints that should be advertised to peers.
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func (et *endpointTracker) update(now time.Time, eps []tailcfg.Endpoint) (epsPlusCached []tailcfg.Endpoint) {
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var inputEps set.Slice[netip.AddrPort]
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for _, ep := range eps {
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inputEps.Add(ep.Addr)
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}
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et.mu.Lock()
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defer et.mu.Unlock()
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// Extend endpoints that already exist in the cache. We do this before
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// we remove expired endpoints, below, so we don't remove something
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// that would otherwise have survived by extending.
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until := now.Add(endpointTrackerLifetime)
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for _, ep := range eps {
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et.extendLocked(ep, until)
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}
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// Now that we've extended existing endpoints, remove everything that
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// has expired.
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et.removeExpiredLocked(now)
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// Add entries from the input set of endpoints into the cache; we do
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// this after removing expired ones so that we can store as many as
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// possible, with space freed by the entries removed after expiry.
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for _, ep := range eps {
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et.addLocked(now, ep, until)
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}
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// Finally, add entries to the return array that aren't already there.
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epsPlusCached = eps
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for _, heap := range et.endpoints {
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for _, ep := range *heap {
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// If the endpoint was in the input list, or has expired, skip it.
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if inputEps.Contains(ep.endpoint.Addr) {
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continue
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} else if now.After(ep.until) {
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// Defense-in-depth; should never happen since
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// we removed expired entries above, but ignore
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// it anyway.
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continue
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}
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// We haven't seen this endpoint; add to the return array
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epsPlusCached = append(epsPlusCached, ep.endpoint)
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}
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}
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return epsPlusCached
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}
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// extendLocked will update the expiry time of the provided endpoint in the
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// cache, if it is present. If it is not present, nothing will be done.
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//
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// et.mu must be held.
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func (et *endpointTracker) extendLocked(ep tailcfg.Endpoint, until time.Time) {
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key := ep.Addr.Addr()
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epHeap, found := et.endpoints[key]
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if !found {
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return
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}
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// Find the entry for this exact address; this loop is quick since we
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// bound the number of items in the heap.
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//
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// TODO(andrew): this means we iterate over the entire heap once per
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// endpoint; even if the heap is small, if we have a lot of input
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// endpoints this can be expensive?
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for i, entry := range *epHeap {
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if entry.endpoint == ep {
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entry.until = until
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heap.Fix(epHeap, i)
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return
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}
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}
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}
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// addLocked will store the provided endpoint(s) in the cache for a fixed
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// period of time, ensuring that the size of the endpoint cache remains below
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// the maximum.
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//
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// et.mu must be held.
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func (et *endpointTracker) addLocked(now time.Time, ep tailcfg.Endpoint, until time.Time) {
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key := ep.Addr.Addr()
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// Create or get the heap for this endpoint's addr
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epHeap := et.endpoints[key]
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if epHeap == nil {
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epHeap = new(endpointHeap)
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mak.Set(&et.endpoints, key, epHeap)
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}
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// Find the entry for this exact address; this loop is quick
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// since we bound the number of items in the heap.
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found := slices.ContainsFunc(*epHeap, func(v *endpointTrackerEntry) bool {
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return v.endpoint == ep
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})
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if !found {
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// Add address to heap; either the endpoint is new, or the heap
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// was newly-created and thus empty.
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heap.Push(epHeap, &endpointTrackerEntry{endpoint: ep, until: until})
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}
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// Now that we've added everything, pop from our heap until we're below
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// the limit. This is a min-heap, so popping removes the lowest (and
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// thus oldest) endpoint.
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for epHeap.Len() > endpointTrackerMaxPerAddr {
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heap.Pop(epHeap)
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}
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}
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// removeExpired will remove all expired entries from the cache.
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//
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// et.mu must be held.
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func (et *endpointTracker) removeExpiredLocked(now time.Time) {
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for k, epHeap := range et.endpoints {
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// The minimum element is oldest/earliest endpoint; repeatedly
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// pop from the heap while it's in the past.
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for epHeap.Len() > 0 {
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minElem := epHeap.Min()
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if now.After(minElem.until) {
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heap.Pop(epHeap)
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} else {
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break
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}
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}
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if epHeap.Len() == 0 {
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// Free up space in the map by removing the empty heap.
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delete(et.endpoints, k)
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}
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}
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}
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