mirror of
https://github.com/tailscale/tailscale.git
synced 2024-11-29 21:15:39 +00:00
a5fd51ebdc
At the current unoptimized memory utilization of the various data structures, 100k IPv6 routes consumes in the ballpark of 3-4GiB, which risks OOMing our 386 test machine. Until we have the optimizations to (drastically) reduce that consumption, skip the test that bloats too much for 32-bit machines. Signed-off-by: David Anderson <danderson@tailscale.com>
551 lines
15 KiB
Go
551 lines
15 KiB
Go
// Copyright (c) Tailscale Inc & AUTHORS
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// SPDX-License-Identifier: BSD-3-Clause
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package art
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import (
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crand "crypto/rand"
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"fmt"
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"math/rand"
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"net/netip"
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"runtime"
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"strconv"
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"testing"
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"time"
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"tailscale.com/types/ptr"
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)
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func TestInsert(t *testing.T) {
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t.Parallel()
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pfxs := randomPrefixes(10_000)
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slow := slowPrefixTable[int]{pfxs}
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fast := Table[int]{}
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for _, pfx := range pfxs {
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fast.Insert(pfx.pfx, pfx.val)
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}
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t.Logf(fast.debugSummary())
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seenVals4 := map[*int]bool{}
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seenVals6 := map[*int]bool{}
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for i := 0; i < 10_000; i++ {
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a := randomAddr()
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slowVal := slow.get(a)
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fastVal := fast.Get(a)
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if a.Is6() {
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seenVals6[fastVal] = true
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} else {
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seenVals4[fastVal] = true
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}
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if slowVal != fastVal {
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t.Errorf("get(%q) = %p, want %p", a, fastVal, slowVal)
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}
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}
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// Empirically, 10k probes into 5k v4 prefixes and 5k v6 prefixes results in
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// ~1k distinct values for v4 and ~300 for v6. distinct routes. This sanity
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// check that we didn't just return a single route for everything should be
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// very generous indeed.
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if cnt := len(seenVals4); cnt < 10 {
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t.Fatalf("saw %d distinct v4 route results, statistically expected ~1000", cnt)
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}
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if cnt := len(seenVals6); cnt < 10 {
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t.Fatalf("saw %d distinct v6 route results, statistically expected ~300", cnt)
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}
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}
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func TestInsertShuffled(t *testing.T) {
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t.Parallel()
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pfxs := randomPrefixes(10_000)
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rt := Table[int]{}
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for _, pfx := range pfxs {
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rt.Insert(pfx.pfx, pfx.val)
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}
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for i := 0; i < 10; i++ {
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pfxs2 := append([]slowPrefixEntry[int](nil), pfxs...)
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rand.Shuffle(len(pfxs2), func(i, j int) { pfxs2[i], pfxs2[j] = pfxs2[j], pfxs2[i] })
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rt2 := Table[int]{}
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for _, pfx := range pfxs2 {
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rt2.Insert(pfx.pfx, pfx.val)
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}
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// Diffing a deep tree of tables gives cmp.Diff a nervous breakdown, so
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// test for equivalence statistically with random probes instead.
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for i := 0; i < 10_000; i++ {
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a := randomAddr()
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val1 := rt.Get(a)
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val2 := rt2.Get(a)
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if (val1 == nil && val2 != nil) || (val1 != nil && val2 == nil) || (*val1 != *val2) {
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t.Errorf("get(%q) = %s, want %s", a, printIntPtr(val2), printIntPtr(val1))
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}
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}
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}
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}
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func TestDelete(t *testing.T) {
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t.Parallel()
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const (
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numPrefixes = 10_000 // total prefixes to insert (test deletes 50% of them)
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numPerFamily = numPrefixes / 2
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deleteCut = numPerFamily / 2
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numProbes = 10_000 // random addr lookups to do
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)
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// We have to do this little dance instead of just using allPrefixes,
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// because we want pfxs and toDelete to be non-overlapping sets.
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all4, all6 := randomPrefixes4(numPerFamily), randomPrefixes6(numPerFamily)
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pfxs := append([]slowPrefixEntry[int](nil), all4[:deleteCut]...)
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pfxs = append(pfxs, all6[:deleteCut]...)
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toDelete := append([]slowPrefixEntry[int](nil), all4[deleteCut:]...)
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toDelete = append(toDelete, all6[deleteCut:]...)
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slow := slowPrefixTable[int]{pfxs}
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fast := Table[int]{}
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for _, pfx := range pfxs {
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fast.Insert(pfx.pfx, pfx.val)
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}
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for _, pfx := range toDelete {
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fast.Insert(pfx.pfx, pfx.val)
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}
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for _, pfx := range toDelete {
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fast.Delete(pfx.pfx)
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}
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seenVals4 := map[*int]bool{}
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seenVals6 := map[*int]bool{}
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for i := 0; i < numProbes; i++ {
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a := randomAddr()
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slowVal := slow.get(a)
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fastVal := fast.Get(a)
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if a.Is6() {
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seenVals6[fastVal] = true
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} else {
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seenVals4[fastVal] = true
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}
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if slowVal != fastVal {
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t.Fatalf("get(%q) = %p, want %p", a, fastVal, slowVal)
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}
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}
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// Empirically, 10k probes into 5k v4 prefixes and 5k v6 prefixes results in
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// ~1k distinct values for v4 and ~300 for v6. distinct routes. This sanity
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// check that we didn't just return a single route for everything should be
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// very generous indeed.
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if cnt := len(seenVals4); cnt < 10 {
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t.Fatalf("saw %d distinct v4 route results, statistically expected ~1000", cnt)
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}
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if cnt := len(seenVals6); cnt < 10 {
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t.Fatalf("saw %d distinct v6 route results, statistically expected ~300", cnt)
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}
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}
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func TestDeleteShuffled(t *testing.T) {
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t.Parallel()
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const (
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numPrefixes = 10_000 // prefixes to insert (test deletes 50% of them)
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numPerFamily = numPrefixes / 2
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deleteCut = numPerFamily / 2
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numProbes = 10_000 // random addr lookups to do
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)
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// We have to do this little dance instead of just using allPrefixes,
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// because we want pfxs and toDelete to be non-overlapping sets.
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all4, all6 := randomPrefixes4(numPerFamily), randomPrefixes6(numPerFamily)
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pfxs := append([]slowPrefixEntry[int](nil), all4[:deleteCut]...)
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pfxs = append(pfxs, all6[:deleteCut]...)
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toDelete := append([]slowPrefixEntry[int](nil), all4[deleteCut:]...)
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toDelete = append(toDelete, all6[deleteCut:]...)
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rt := Table[int]{}
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for _, pfx := range pfxs {
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rt.Insert(pfx.pfx, pfx.val)
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}
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for _, pfx := range toDelete {
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rt.Insert(pfx.pfx, pfx.val)
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}
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for _, pfx := range toDelete {
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rt.Delete(pfx.pfx)
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}
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for i := 0; i < 10; i++ {
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pfxs2 := append([]slowPrefixEntry[int](nil), pfxs...)
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toDelete2 := append([]slowPrefixEntry[int](nil), toDelete...)
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rand.Shuffle(len(toDelete2), func(i, j int) { toDelete2[i], toDelete2[j] = toDelete2[j], toDelete2[i] })
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rt2 := Table[int]{}
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for _, pfx := range pfxs2 {
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rt2.Insert(pfx.pfx, pfx.val)
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}
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for _, pfx := range toDelete2 {
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rt2.Insert(pfx.pfx, pfx.val)
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}
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for _, pfx := range toDelete2 {
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rt2.Delete(pfx.pfx)
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}
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// Diffing a deep tree of tables gives cmp.Diff a nervous breakdown, so
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// test for equivalence statistically with random probes instead.
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for i := 0; i < numProbes; i++ {
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a := randomAddr()
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val1 := rt.Get(a)
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val2 := rt2.Get(a)
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if val1 == nil && val2 == nil {
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continue
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}
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if (val1 == nil && val2 != nil) || (val1 != nil && val2 == nil) || (*val1 != *val2) {
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t.Errorf("get(%q) = %s, want %s", a, printIntPtr(val2), printIntPtr(val1))
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}
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}
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}
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}
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// 100k routes for IPv6, at the current size of strideTable and strideEntry, is
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// in the ballpark of 4GiB if you assume worst-case prefix distribution. Future
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// optimizations will knock down the memory consumption by over an order of
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// magnitude, so for now just skip the 100k benchmarks to stay well away of
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// OOMs.
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//
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// TODO(go/bug/7781): reenable larger table tests once memory utilization is
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// optimized.
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var benchRouteCount = []int{10, 100, 1000, 10_000} //, 100_000}
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// forFamilyAndCount runs the benchmark fn with different sets of
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// routes.
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//
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// fn is called once for each combination of {addr_family, num_routes},
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// where addr_family is ipv4 or ipv6, num_routes is the values in
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// benchRouteCount.
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func forFamilyAndCount(b *testing.B, fn func(b *testing.B, routes []slowPrefixEntry[int])) {
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for _, fam := range []string{"ipv4", "ipv6"} {
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rng := randomPrefixes4
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if fam == "ipv6" {
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rng = randomPrefixes6
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}
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b.Run(fam, func(b *testing.B) {
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for _, nroutes := range benchRouteCount {
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routes := rng(nroutes)
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b.Run(fmt.Sprint(nroutes), func(b *testing.B) {
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fn(b, routes)
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})
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}
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})
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}
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}
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func BenchmarkTableInsertion(b *testing.B) {
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forFamilyAndCount(b, func(b *testing.B, routes []slowPrefixEntry[int]) {
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b.StopTimer()
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b.ResetTimer()
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var startMem, endMem runtime.MemStats
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runtime.ReadMemStats(&startMem)
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b.StartTimer()
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for i := 0; i < b.N; i++ {
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var rt Table[int]
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for _, route := range routes {
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rt.Insert(route.pfx, route.val)
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}
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}
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b.StopTimer()
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runtime.ReadMemStats(&endMem)
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inserts := float64(b.N) * float64(len(routes))
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allocs := float64(endMem.Mallocs - startMem.Mallocs)
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bytes := float64(endMem.TotalAlloc - startMem.TotalAlloc)
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elapsed := float64(b.Elapsed().Nanoseconds())
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elapsedSec := b.Elapsed().Seconds()
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b.ReportMetric(elapsed/inserts, "ns/op")
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b.ReportMetric(inserts/elapsedSec, "routes/s")
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b.ReportMetric(roundFloat64(allocs/inserts), "avg-allocs/op")
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b.ReportMetric(roundFloat64(bytes/inserts), "avg-B/op")
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})
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}
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func BenchmarkTableDelete(b *testing.B) {
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forFamilyAndCount(b, func(b *testing.B, routes []slowPrefixEntry[int]) {
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// Collect memstats for one round of insertions, so we can remove it
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// from the total at the end and get only the deletion alloc count.
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insertAllocs, insertBytes := getMemCost(func() {
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var rt Table[int]
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for _, route := range routes {
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rt.Insert(route.pfx, route.val)
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}
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})
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insertAllocs *= float64(b.N)
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insertBytes *= float64(b.N)
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var t runningTimer
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allocs, bytes := getMemCost(func() {
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for i := 0; i < b.N; i++ {
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var rt Table[int]
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for _, route := range routes {
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rt.Insert(route.pfx, route.val)
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}
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t.Start()
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for _, route := range routes {
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rt.Delete(route.pfx)
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}
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t.Stop()
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}
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})
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inserts := float64(b.N) * float64(len(routes))
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allocs -= insertAllocs
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bytes -= insertBytes
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elapsed := float64(t.Elapsed().Nanoseconds())
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elapsedSec := t.Elapsed().Seconds()
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b.ReportMetric(elapsed/inserts, "ns/op")
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b.ReportMetric(inserts/elapsedSec, "routes/s")
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b.ReportMetric(roundFloat64(allocs/inserts), "avg-allocs/op")
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b.ReportMetric(roundFloat64(bytes/inserts), "avg-B/op")
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})
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}
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var addrSink netip.Addr
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func BenchmarkTableGet(b *testing.B) {
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forFamilyAndCount(b, func(b *testing.B, routes []slowPrefixEntry[int]) {
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genAddr := randomAddr4
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if routes[0].pfx.Addr().Is6() {
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genAddr = randomAddr6
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}
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var rt Table[int]
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for _, route := range routes {
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rt.Insert(route.pfx, route.val)
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}
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addrAllocs, addrBytes := getMemCost(func() {
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// Have to run genAddr more than once, otherwise the reported
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// cost is 16 bytes - presumably due to some amortized costs in
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// the memory allocator? Either way, empirically 100 iterations
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// reliably reports the correct cost.
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for i := 0; i < 100; i++ {
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_ = genAddr()
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}
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})
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addrAllocs /= 100
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addrBytes /= 100
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var t runningTimer
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allocs, bytes := getMemCost(func() {
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for i := 0; i < b.N; i++ {
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addr := genAddr()
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t.Start()
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writeSink = rt.Get(addr)
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t.Stop()
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}
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})
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b.ReportAllocs() // Enables the output, but we report manually below
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allocs -= (addrAllocs * float64(b.N))
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bytes -= (addrBytes * float64(b.N))
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lookups := float64(b.N)
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elapsed := float64(t.Elapsed().Nanoseconds())
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elapsedSec := float64(t.Elapsed().Seconds())
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b.ReportMetric(elapsed/lookups, "ns/op")
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b.ReportMetric(lookups/elapsedSec, "addrs/s")
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b.ReportMetric(allocs/lookups, "allocs/op")
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b.ReportMetric(bytes/lookups, "B/op")
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})
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}
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// getMemCost runs fn 100 times and returns the number of allocations and bytes
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// allocated by each call to fn.
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//
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// Note that if your fn allocates very little memory (less than ~16 bytes), you
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// should make fn run its workload ~100 times and divide the results of
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// getMemCost yourself. Otherwise, the byte count you get will be rounded up due
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// to the memory allocator's bucketing granularity.
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func getMemCost(fn func()) (allocs, bytes float64) {
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var start, end runtime.MemStats
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runtime.ReadMemStats(&start)
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fn()
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runtime.ReadMemStats(&end)
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return float64(end.Mallocs - start.Mallocs), float64(end.TotalAlloc - start.TotalAlloc)
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}
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// runningTimer is a timer that keeps track of the cumulative time it's spent
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// running since creation. A newly created runningTimer is stopped.
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//
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// This timer exists because some of our benchmarks have to interleave costly
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// ancillary logic in each benchmark iteration, rather than being able to
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// front-load all the work before a single b.ResetTimer().
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//
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// As it turns out, b.StartTimer() and b.StopTimer() are expensive function
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// calls, because they do costly memory allocation accounting on every call.
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// Starting and stopping the benchmark timer in every b.N loop iteration slows
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// the benchmarks down by orders of magnitude.
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//
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// So, rather than rely on testing.B's timing facility, we use this very
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// lightweight timer combined with getMemCost to do our own accounting more
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// efficiently.
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type runningTimer struct {
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cumulative time.Duration
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start time.Time
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}
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func (t *runningTimer) Start() {
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t.Stop()
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t.start = time.Now()
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}
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func (t *runningTimer) Stop() {
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if t.start.IsZero() {
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return
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}
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t.cumulative += time.Since(t.start)
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t.start = time.Time{}
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}
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func (t *runningTimer) Elapsed() time.Duration {
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return t.cumulative
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}
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// slowPrefixTable is a routing table implemented as a set of prefixes that are
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// explicitly scanned in full for every route lookup. It is very slow, but also
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// reasonably easy to verify by inspection, and so a good correctness reference
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// for Table.
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type slowPrefixTable[T any] struct {
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prefixes []slowPrefixEntry[T]
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}
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type slowPrefixEntry[T any] struct {
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pfx netip.Prefix
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val *T
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}
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func (t *slowPrefixTable[T]) delete(pfx netip.Prefix) {
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ret := make([]slowPrefixEntry[T], 0, len(t.prefixes))
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for _, ent := range t.prefixes {
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if ent.pfx == pfx {
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continue
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}
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ret = append(ret, ent)
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}
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t.prefixes = ret
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}
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func (t *slowPrefixTable[T]) insert(pfx netip.Prefix, val *T) {
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for _, ent := range t.prefixes {
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if ent.pfx == pfx {
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ent.val = val
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return
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}
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}
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t.prefixes = append(t.prefixes, slowPrefixEntry[T]{pfx, val})
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}
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func (t *slowPrefixTable[T]) get(addr netip.Addr) *T {
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var (
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ret *T
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bestLen = -1
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)
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for _, pfx := range t.prefixes {
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if pfx.pfx.Contains(addr) && pfx.pfx.Bits() > bestLen {
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ret = pfx.val
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bestLen = pfx.pfx.Bits()
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}
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}
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return ret
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}
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// randomPrefixes returns n randomly generated prefixes and associated values,
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// distributed equally between IPv4 and IPv6.
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func randomPrefixes(n int) []slowPrefixEntry[int] {
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pfxs := randomPrefixes4(n / 2)
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pfxs = append(pfxs, randomPrefixes6(n-len(pfxs))...)
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return pfxs
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}
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// randomPrefixes4 returns n randomly generated IPv4 prefixes and associated values.
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func randomPrefixes4(n int) []slowPrefixEntry[int] {
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pfxs := map[netip.Prefix]bool{}
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for len(pfxs) < n {
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len := rand.Intn(33)
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pfx, err := randomAddr4().Prefix(len)
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if err != nil {
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panic(err)
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}
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pfxs[pfx] = true
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}
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ret := make([]slowPrefixEntry[int], 0, len(pfxs))
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for pfx := range pfxs {
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ret = append(ret, slowPrefixEntry[int]{pfx, ptr.To(rand.Int())})
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}
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return ret
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}
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// randomPrefixes6 returns n randomly generated IPv4 prefixes and associated values.
|
|
func randomPrefixes6(n int) []slowPrefixEntry[int] {
|
|
pfxs := map[netip.Prefix]bool{}
|
|
|
|
for len(pfxs) < n {
|
|
len := rand.Intn(129)
|
|
pfx, err := randomAddr6().Prefix(len)
|
|
if err != nil {
|
|
panic(err)
|
|
}
|
|
pfxs[pfx] = true
|
|
}
|
|
|
|
ret := make([]slowPrefixEntry[int], 0, len(pfxs))
|
|
for pfx := range pfxs {
|
|
ret = append(ret, slowPrefixEntry[int]{pfx, ptr.To(rand.Int())})
|
|
}
|
|
|
|
return ret
|
|
}
|
|
|
|
// randomAddr returns a randomly generated IP address.
|
|
func randomAddr() netip.Addr {
|
|
if rand.Intn(2) == 1 {
|
|
return randomAddr6()
|
|
} else {
|
|
return randomAddr4()
|
|
}
|
|
}
|
|
|
|
// randomAddr4 returns a randomly generated IPv4 address.
|
|
func randomAddr4() netip.Addr {
|
|
var b [4]byte
|
|
if _, err := crand.Read(b[:]); err != nil {
|
|
panic(err)
|
|
}
|
|
return netip.AddrFrom4(b)
|
|
}
|
|
|
|
// randomAddr6 returns a randomly generated IPv6 address.
|
|
func randomAddr6() netip.Addr {
|
|
var b [16]byte
|
|
if _, err := crand.Read(b[:]); err != nil {
|
|
panic(err)
|
|
}
|
|
return netip.AddrFrom16(b)
|
|
}
|
|
|
|
// printIntPtr returns *v as a string, or the literal "<nil>" if v is nil.
|
|
func printIntPtr(v *int) string {
|
|
if v == nil {
|
|
return "<nil>"
|
|
}
|
|
return fmt.Sprint(*v)
|
|
}
|
|
|
|
// roundFloat64 rounds f to 2 decimal places, for display.
|
|
//
|
|
// It round-trips through a float->string->float conversion, so should not be
|
|
// used in a performance critical setting.
|
|
func roundFloat64(f float64) float64 {
|
|
s := fmt.Sprintf("%.2f", f)
|
|
ret, err := strconv.ParseFloat(s, 64)
|
|
if err != nil {
|
|
panic(err)
|
|
}
|
|
return ret
|
|
}
|