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tailscale/net/art/stride_table_test.go
Will Norris 3ec5be3f51 all: remove AUTHORS file and references to it 
This file was never truly necessary and has never actually been used in
the history of Tailscale's open source releases.

A Brief History of AUTHORS files
---

The AUTHORS file was a pattern developed at Google, originally for
Chromium, then adopted by Go and a bunch of other projects. The problem
was that Chromium originally had a copyright line only recognizing
Google as the copyright holder. Because Google (and most open source
projects) do not require copyright assignemnt for contributions, each
contributor maintains their copyright. Some large corporate contributors
then tried to add their own name to the copyright line in the LICENSE
file or in file headers. This quickly becomes unwieldy, and puts a
tremendous burden on anyone building on top of Chromium, since the
license requires that they keep all copyright lines intact.

The compromise was to create an AUTHORS file that would list all of the
copyright holders. The LICENSE file and source file headers would then
include that list by reference, listing the copyright holder as "The
Chromium Authors".

This also become cumbersome to simply keep the file up to date with a
high rate of new contributors. Plus it's not always obvious who the
copyright holder is. Sometimes it is the individual making the
contribution, but many times it may be their employer. There is no way
for the proejct maintainer to know.

Eventually, Google changed their policy to no longer recommend trying to
keep the AUTHORS file up to date proactively, and instead to only add to
it when requested: https://opensource.google/docs/releasing/authors.
They are also clear that:

> Adding contributors to the AUTHORS file is entirely within the
> project's discretion and has no implications for copyright ownership.

It was primarily added to appease a small number of large contributors
that insisted that they be recognized as copyright holders (which was
entirely their right to do). But it's not truly necessary, and not even
the most accurate way of identifying contributors and/or copyright
holders.

In practice, we've never added anyone to our AUTHORS file. It only lists
Tailscale, so it's not really serving any purpose. It also causes
confusion because Tailscalars put the "Tailscale Inc & AUTHORS" header
in other open source repos which don't actually have an AUTHORS file, so
it's ambiguous what that means.

Instead, we just acknowledge that the contributors to Tailscale (whoever
they are) are copyright holders for their individual contributions. We
also have the benefit of using the DCO (developercertificate.org) which
provides some additional certification of their right to make the
contribution.

The source file changes were purely mechanical with:

    git ls-files | xargs sed -i -e 's/\(Tailscale Inc &\) AUTHORS/\1 contributors/g'

Updates #cleanup

Change-Id: Ia101a4a3005adb9118051b3416f5a64a4a45987d
Signed-off-by: Will Norris <will@tailscale.com>
2026-01-23 15:49:45 -08:00

412 lines
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// Copyright (c) Tailscale Inc & contributors
// SPDX-License-Identifier: BSD-3-Clause
package art
import (
"bytes"
"fmt"
"math/rand"
"net/netip"
"runtime"
"sort"
"strings"
"testing"
"github.com/google/go-cmp/cmp"
)
func TestInversePrefix(t *testing.T) {
t.Parallel()
for i := range 256 {
for len := 0; len < 9; len++ {
addr := i & (0xFF << (8 - len))
idx := prefixIndex(uint8(addr), len)
addr2, len2 := inversePrefixIndex(idx)
if addr2 != uint8(addr) || len2 != len {
t.Errorf("inverse(index(%d/%d)) != %d/%d", addr, len, addr2, len2)
}
}
}
}
func TestHostIndex(t *testing.T) {
t.Parallel()
for i := range 256 {
got := hostIndex(uint8(i))
want := prefixIndex(uint8(i), 8)
if got != want {
t.Errorf("hostIndex(%d) = %d, want %d", i, got, want)
}
}
}
func TestStrideTableInsert(t *testing.T) {
t.Parallel()
// Verify that strideTable's lookup results after a bunch of inserts exactly
// match those of a naive implementation that just scans all prefixes on
// every lookup. The naive implementation is very slow, but its behavior is
// easy to verify by inspection.
pfxs := shufflePrefixes(allPrefixes())[:100]
slow := slowTable[int]{pfxs}
fast := strideTable[int]{}
if debugStrideInsert {
t.Logf("slow table:\n%s", slow.String())
}
for _, pfx := range pfxs {
fast.insert(pfx.addr, pfx.len, pfx.val)
if debugStrideInsert {
t.Logf("after insert %d/%d:\n%s", pfx.addr, pfx.len, fast.tableDebugString())
}
}
for i := range 256 {
addr := uint8(i)
slowVal, slowOK := slow.get(addr)
fastVal, fastOK := fast.get(addr)
if !getsEqual(fastVal, fastOK, slowVal, slowOK) {
t.Fatalf("strideTable.get(%d) = (%v, %v), want (%v, %v)", addr, fastVal, fastOK, slowVal, slowOK)
}
}
}
func TestStrideTableInsertShuffled(t *testing.T) {
t.Parallel()
// The order in which routes are inserted into a route table does not
// influence the final shape of the table, as long as the same set of
// prefixes is being inserted. This test verifies that strideTable behaves
// this way.
//
// In addition to the basic shuffle test, we also check that this behavior
// is maintained if all inserted routes have the same value pointer. This
// shouldn't matter (the strideTable still needs to correctly account for
// each inserted route, regardless of associated value), but during initial
// development a subtle bug made the table corrupt itself in that setup, so
// this test includes a regression test for that.
routes := shufflePrefixes(allPrefixes())[:100]
zero := 0
rt := strideTable[int]{}
// strideTable has a value interface, but internally has to keep
// track of distinct routes even if they all have the same
// value. rtZero uses the same value for all routes, and expects
// correct behavior.
rtZero := strideTable[int]{}
for _, route := range routes {
rt.insert(route.addr, route.len, route.val)
rtZero.insert(route.addr, route.len, zero)
}
// Order of insertion should not affect the final shape of the stride table.
routes2 := append([]slowEntry[int](nil), routes...) // dup so we can print both slices on fail
for range 100 {
rand.Shuffle(len(routes2), func(i, j int) { routes2[i], routes2[j] = routes2[j], routes2[i] })
rt2 := strideTable[int]{}
for _, route := range routes2 {
rt2.insert(route.addr, route.len, route.val)
}
if diff := cmp.Diff(rt.tableDebugString(), rt2.tableDebugString()); diff != "" {
t.Errorf("tables ended up different with different insertion order (-got+want):\n%s\n\nOrder 1: %v\nOrder 2: %v", diff, formatSlowEntriesShort(routes), formatSlowEntriesShort(routes2))
}
rtZero2 := strideTable[int]{}
for _, route := range routes2 {
rtZero2.insert(route.addr, route.len, zero)
}
if diff := cmp.Diff(rtZero.tableDebugString(), rtZero2.tableDebugString(), cmpDiffOpts...); diff != "" {
t.Errorf("tables with identical vals ended up different with different insertion order (-got+want):\n%s\n\nOrder 1: %v\nOrder 2: %v", diff, formatSlowEntriesShort(routes), formatSlowEntriesShort(routes2))
}
}
}
func TestStrideTableDelete(t *testing.T) {
t.Parallel()
// Compare route deletion to our reference slowTable.
pfxs := shufflePrefixes(allPrefixes())[:100]
slow := slowTable[int]{pfxs}
fast := strideTable[int]{}
if debugStrideDelete {
t.Logf("slow table:\n%s", slow.String())
}
for _, pfx := range pfxs {
fast.insert(pfx.addr, pfx.len, pfx.val)
if debugStrideDelete {
t.Logf("after insert %d/%d:\n%s", pfx.addr, pfx.len, fast.tableDebugString())
}
}
toDelete := pfxs[:50]
for _, pfx := range toDelete {
slow.delete(pfx.addr, pfx.len)
fast.delete(pfx.addr, pfx.len)
}
// Sanity check that slowTable seems to have done the right thing.
if cnt := len(slow.prefixes); cnt != 50 {
t.Fatalf("slowTable has %d entries after deletes, want 50", cnt)
}
for i := range 256 {
addr := uint8(i)
slowVal, slowOK := slow.get(addr)
fastVal, fastOK := fast.get(addr)
if !getsEqual(fastVal, fastOK, slowVal, slowOK) {
t.Fatalf("strideTable.get(%d) = (%v, %v), want (%v, %v)", addr, fastVal, fastOK, slowVal, slowOK)
}
}
}
func TestStrideTableDeleteShuffle(t *testing.T) {
t.Parallel()
// Same as TestStrideTableInsertShuffle, the order in which prefixes are
// deleted should not impact the final shape of the route table.
routes := shufflePrefixes(allPrefixes())[:100]
toDelete := routes[:50]
zero := 0
rt := strideTable[int]{}
// strideTable has a value interface, but internally has to keep
// track of distinct routes even if they all have the same
// value. rtZero uses the same value for all routes, and expects
// correct behavior.
rtZero := strideTable[int]{}
for _, route := range routes {
rt.insert(route.addr, route.len, route.val)
rtZero.insert(route.addr, route.len, zero)
}
for _, route := range toDelete {
rt.delete(route.addr, route.len)
rtZero.delete(route.addr, route.len)
}
// Order of deletion should not affect the final shape of the stride table.
toDelete2 := append([]slowEntry[int](nil), toDelete...) // dup so we can print both slices on fail
for range 100 {
rand.Shuffle(len(toDelete2), func(i, j int) { toDelete2[i], toDelete2[j] = toDelete2[j], toDelete2[i] })
rt2 := strideTable[int]{}
for _, route := range routes {
rt2.insert(route.addr, route.len, route.val)
}
for _, route := range toDelete2 {
rt2.delete(route.addr, route.len)
}
if diff := cmp.Diff(rt.tableDebugString(), rt2.tableDebugString(), cmpDiffOpts...); diff != "" {
t.Errorf("tables ended up different with different deletion order (-got+want):\n%s\n\nOrder 1: %v\nOrder 2: %v", diff, formatSlowEntriesShort(toDelete), formatSlowEntriesShort(toDelete2))
}
rtZero2 := strideTable[int]{}
for _, route := range routes {
rtZero2.insert(route.addr, route.len, zero)
}
for _, route := range toDelete2 {
rtZero2.delete(route.addr, route.len)
}
if diff := cmp.Diff(rtZero.tableDebugString(), rtZero2.tableDebugString(), cmpDiffOpts...); diff != "" {
t.Errorf("tables with identical vals ended up different with different deletion order (-got+want):\n%s\n\nOrder 1: %v\nOrder 2: %v", diff, formatSlowEntriesShort(toDelete), formatSlowEntriesShort(toDelete2))
}
}
}
var strideRouteCount = []int{10, 50, 100, 200}
// forCountAndOrdering runs the benchmark fn with different sets of routes.
//
// fn is called once for each combination of {num_routes, order}, where
// num_routes is the values in strideRouteCount, and order is the order of the
// routes in the list: random, largest prefix first (/0 to /8), and smallest
// prefix first (/8 to /0).
func forStrideCountAndOrdering(b *testing.B, fn func(b *testing.B, routes []slowEntry[int])) {
routes := shufflePrefixes(allPrefixes())
for _, nroutes := range strideRouteCount {
b.Run(fmt.Sprint(nroutes), func(b *testing.B) {
runAndRecord := func(b *testing.B) {
b.ReportAllocs()
var startMem, endMem runtime.MemStats
runtime.ReadMemStats(&startMem)
fn(b, routes)
runtime.ReadMemStats(&endMem)
ops := float64(b.N) * float64(len(routes))
allocs := float64(endMem.Mallocs - startMem.Mallocs)
bytes := float64(endMem.TotalAlloc - startMem.TotalAlloc)
b.ReportMetric(roundFloat64(allocs/ops), "allocs/op")
b.ReportMetric(roundFloat64(bytes/ops), "B/op")
}
routes := append([]slowEntry[int](nil), routes[:nroutes]...)
b.Run("random_order", runAndRecord)
sort.Slice(routes, func(i, j int) bool {
if routes[i].len < routes[j].len {
return true
}
return routes[i].addr < routes[j].addr
})
b.Run("largest_first", runAndRecord)
sort.Slice(routes, func(i, j int) bool {
if routes[j].len < routes[i].len {
return true
}
return routes[j].addr < routes[i].addr
})
b.Run("smallest_first", runAndRecord)
})
}
}
func BenchmarkStrideTableInsertion(b *testing.B) {
forStrideCountAndOrdering(b, func(b *testing.B, routes []slowEntry[int]) {
val := 0
for range b.N {
var rt strideTable[int]
for _, route := range routes {
rt.insert(route.addr, route.len, val)
}
}
inserts := float64(b.N) * float64(len(routes))
elapsed := float64(b.Elapsed().Nanoseconds())
elapsedSec := b.Elapsed().Seconds()
b.ReportMetric(elapsed/inserts, "ns/op")
b.ReportMetric(inserts/elapsedSec, "routes/s")
})
}
func BenchmarkStrideTableDeletion(b *testing.B) {
forStrideCountAndOrdering(b, func(b *testing.B, routes []slowEntry[int]) {
val := 0
var rt strideTable[int]
for _, route := range routes {
rt.insert(route.addr, route.len, val)
}
b.ResetTimer()
for range b.N {
rt2 := rt
for _, route := range routes {
rt2.delete(route.addr, route.len)
}
}
deletes := float64(b.N) * float64(len(routes))
elapsed := float64(b.Elapsed().Nanoseconds())
elapsedSec := b.Elapsed().Seconds()
b.ReportMetric(elapsed/deletes, "ns/op")
b.ReportMetric(deletes/elapsedSec, "routes/s")
})
}
var writeSink int
func BenchmarkStrideTableGet(b *testing.B) {
// No need to forCountAndOrdering here, route lookup time is independent of
// the route count.
routes := shufflePrefixes(allPrefixes())[:100]
var rt strideTable[int]
for _, route := range routes {
rt.insert(route.addr, route.len, route.val)
}
b.ResetTimer()
for i := range b.N {
writeSink, _ = rt.get(uint8(i))
}
gets := float64(b.N)
elapsedSec := b.Elapsed().Seconds()
b.ReportMetric(gets/elapsedSec, "routes/s")
}
// slowTable is an 8-bit routing table implemented as a set of prefixes that are
// explicitly scanned in full for every route lookup. It is very slow, but also
// reasonably easy to verify by inspection, and so a good comparison target for
// strideTable.
type slowTable[T any] struct {
prefixes []slowEntry[T]
}
type slowEntry[T any] struct {
addr uint8
len int
val T
}
func (t *slowTable[T]) String() string {
pfxs := append([]slowEntry[T](nil), t.prefixes...)
sort.Slice(pfxs, func(i, j int) bool {
if pfxs[i].len != pfxs[j].len {
return pfxs[i].len < pfxs[j].len
}
return pfxs[i].addr < pfxs[j].addr
})
var ret bytes.Buffer
for _, pfx := range pfxs {
fmt.Fprintf(&ret, "%3d/%d (%08b/%08b) = %v\n", pfx.addr, pfx.len, pfx.addr, pfxMask(pfx.len), pfx.val)
}
return ret.String()
}
func (t *slowTable[T]) delete(addr uint8, prefixLen int) {
pfx := make([]slowEntry[T], 0, len(t.prefixes))
for _, e := range t.prefixes {
if e.addr == addr && e.len == prefixLen {
continue
}
pfx = append(pfx, e)
}
t.prefixes = pfx
}
func (t *slowTable[T]) get(addr uint8) (ret T, ok bool) {
var curLen = -1
for _, e := range t.prefixes {
if addr&pfxMask(e.len) == e.addr && e.len >= curLen {
ret = e.val
curLen = e.len
}
}
return ret, curLen != -1
}
func pfxMask(pfxLen int) uint8 {
return 0xFF << (8 - pfxLen)
}
func allPrefixes() []slowEntry[int] {
ret := make([]slowEntry[int], 0, lastHostIndex)
for i := 1; i < lastHostIndex+1; i++ {
a, ln := inversePrefixIndex(i)
ret = append(ret, slowEntry[int]{a, ln, i})
}
return ret
}
func shufflePrefixes(pfxs []slowEntry[int]) []slowEntry[int] {
rand.Shuffle(len(pfxs), func(i, j int) { pfxs[i], pfxs[j] = pfxs[j], pfxs[i] })
return pfxs
}
func formatSlowEntriesShort[T any](ents []slowEntry[T]) string {
var ret []string
for _, ent := range ents {
ret = append(ret, fmt.Sprintf("%d/%d", ent.addr, ent.len))
}
return "[" + strings.Join(ret, " ") + "]"
}
var cmpDiffOpts = []cmp.Option{
cmp.Comparer(func(a, b netip.Prefix) bool { return a == b }),
}
func getsEqual[T comparable](a T, aOK bool, b T, bOK bool) bool {
if !aOK && !bOK {
return true
}
if aOK != bOK {
return false
}
return a == b
}
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