tailscale/tka/sync.go

252 lines
7.1 KiB
Go

// Copyright (c) 2022 Tailscale Inc & AUTHORS All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tka
import (
"errors"
"fmt"
"os"
)
const (
// Max iterations searching for any intersection.
maxSyncIter = 2000
// Max iterations searching for a head intersection.
maxSyncHeadIntersectionIter = 400
)
// ErrNoIntersection is returned when a shared AUM could
// not be determined when evaluating a remote sync offer.
var ErrNoIntersection = errors.New("no intersection")
// SyncOffer conveys information about the current head & ancestor AUMs,
// for the purpose of synchronization with some remote end.
//
// Ancestors should contain a subset of the ancestors of the chain.
// The last entry in that slice is the oldest-known AUM in the chain.
type SyncOffer struct {
Head AUMHash
Ancestors []AUMHash
}
const (
// The starting number of AUMs to skip when listing
// ancestors in a SyncOffer.
ancestorsSkipStart = 4
// How many bits to advance the skip count when listing
// ancestors in a SyncOffer.
//
// 2 bits, so (4<<2), so after skipping 4 it skips 16.
ancestorsSkipShift = 2
)
func (a *Authority) syncOffer() (SyncOffer, error) {
oldest := a.oldestAncestor.Hash()
out := SyncOffer{
Head: a.Head(),
Ancestors: make([]AUMHash, 0, 6), // 6 chosen arbitrarily.
}
// We send some subset of our ancestors to help the remote
// find a more-recent 'head intersection'.
// The number of AUMs between each ancestor entry gets
// exponentially larger.
var (
skipAmount uint64 = ancestorsSkipStart
curs AUMHash = a.Head()
)
for i := uint64(0); i < maxSyncHeadIntersectionIter; i++ {
if i > 0 && (i%skipAmount) == 0 {
out.Ancestors = append(out.Ancestors, curs)
skipAmount = skipAmount << ancestorsSkipShift
}
parent, err := a.storage.AUM(curs)
if err != nil {
if err != os.ErrNotExist {
return SyncOffer{}, err
}
break
}
// We add the oldest later on, so don't duplicate.
if parent.Hash() == oldest {
break
}
copy(curs[:], parent.PrevAUMHash)
}
out.Ancestors = append(out.Ancestors, oldest)
return out, nil
}
// SyncOffer returns an abbreviated description of the current AUM
// chain, which can be used to synchronize with another (untrusted)
// Authority instance.
//
// The returned SyncOffer structure should be transmitted to the remote
// Authority, which should call MissingAUMs() using it to determine
// AUMs which need to be transmitted. This list of AUMs from the remote
// can then be applied locally with Inform().
//
// This SyncOffer + AUM exchange should be performed by both ends,
// because its possible that either end has AUMs that the other needs
// to find out about.
func (a *Authority) SyncOffer() (SyncOffer, error) {
return a.syncOffer()
}
// intersection describes how to synchronize AUMs with a remote
// authority.
type intersection struct {
// if true, no exchange of AUMs is needed.
upToDate bool
// headIntersection is the latest common AUM on the remote. In other
// words, we need to send all AUMs since this one.
headIntersection *AUMHash
// tailIntersection is the oldest common AUM on the remote. In other
// words, we diverge with the remote after this AUM, so we both need
// to transmit our AUM chain starting here.
tailIntersection *AUMHash
}
// computeSyncIntersection determines the common AUMs between a local and
// remote SyncOffer. This intersection can be used to synchronize both
// sides.
func computeSyncIntersection(authority *Authority, localOffer, remoteOffer SyncOffer) (*intersection, error) {
// Simple case: up to date.
if remoteOffer.Head == localOffer.Head {
return &intersection{upToDate: true, headIntersection: &localOffer.Head}, nil
}
// Case: 'head intersection'
// If we have the remote's head, its more likely than not that
// we have updates that build on that head. To confirm this,
// we iterate backwards through our chain to see if the given
// head is an ancestor of our current chain.
//
// In other words:
// <Us> A -> B -> C
// <Them> A -> B
// ∴ their head intersects with our chain, we need to send C
var hasRemoteHead bool
_, err := authority.storage.AUM(remoteOffer.Head)
if err != nil {
if err != os.ErrNotExist {
return nil, err
}
} else {
hasRemoteHead = true
}
if hasRemoteHead {
curs := localOffer.Head
for i := 0; i < maxSyncHeadIntersectionIter; i++ {
parent, err := authority.storage.AUM(curs)
if err != nil {
if err != os.ErrNotExist {
return nil, err
}
break
}
if parent.Hash() == remoteOffer.Head {
h := parent.Hash()
return &intersection{headIntersection: &h}, nil
}
copy(curs[:], parent.PrevAUMHash)
}
}
// Case: 'tail intersection'
// So we don't have a clue what the remote's head is, but
// if one of the ancestors they gave us is part of our chain,
// then theres an intersection, which is a starting point for
// the remote to send us AUMs from.
//
// We iterate the list of ancestors in order because the remote
// ordered them such that the newer ones are earlier, so with
// a bit of luck we can use an earlier one and hence do less work /
// transmit fewer AUMs.
for _, a := range remoteOffer.Ancestors {
state, err := computeStateAt(authority.storage, maxSyncIter, a)
if err != nil {
if err != os.ErrNotExist {
return nil, fmt.Errorf("computeStateAt: %v", err)
}
continue
}
end, _, err := fastForward(authority.storage, maxSyncIter, state, func(curs AUM, _ State) bool {
return curs.Hash() == localOffer.Head
})
if err != nil {
return nil, err
}
// fastForward can terminate before the done condition if there are
// no more children left, so we check again before considering this
// an intersection.
if end.Hash() == localOffer.Head {
return &intersection{tailIntersection: &a}, nil
}
}
return nil, ErrNoIntersection
}
// MissingAUMs returns AUMs a remote may be missing based on the
// remotes' SyncOffer.
func (a *Authority) MissingAUMs(remoteOffer SyncOffer) ([]AUM, error) {
localOffer, err := a.syncOffer()
if err != nil {
return nil, fmt.Errorf("local syncOffer: %v", err)
}
intersection, err := computeSyncIntersection(a, localOffer, remoteOffer)
if err != nil {
return nil, fmt.Errorf("intersection: %v", err)
}
if intersection.upToDate {
return nil, nil
}
out := make([]AUM, 0, 12) // 12 chosen arbitrarily.
if intersection.headIntersection != nil {
state, err := computeStateAt(a.storage, maxSyncIter, *intersection.headIntersection)
if err != nil {
return nil, err
}
_, _, err = fastForward(a.storage, maxSyncIter, state, func(curs AUM, _ State) bool {
if curs.Hash() != *intersection.headIntersection {
out = append(out, curs)
}
return false
})
return out, err
}
if intersection.tailIntersection != nil {
state, err := computeStateAt(a.storage, maxSyncIter, *intersection.tailIntersection)
if err != nil {
return nil, err
}
_, _, err = fastForward(a.storage, maxSyncIter, state, func(curs AUM, _ State) bool {
if curs.Hash() != *intersection.tailIntersection {
out = append(out, curs)
}
return false
})
return out, err
}
panic("unreachable")
}