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topological.go
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topological.go
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// Copyright (C) 2019-2022, Ava Labs, Inc. All rights reserved.
// See the file LICENSE for licensing terms.
package snowman
import (
"errors"
"fmt"
"strings"
"go.uber.org/zap"
"github.com/ava-labs/avalanchego/ids"
"github.com/ava-labs/avalanchego/snow"
"github.com/ava-labs/avalanchego/snow/choices"
"github.com/ava-labs/avalanchego/snow/consensus/metrics"
"github.com/ava-labs/avalanchego/snow/consensus/snowball"
)
var (
errDuplicateAdd = errors.New("duplicate block add")
_ Factory = &TopologicalFactory{}
_ Consensus = &Topological{}
)
// TopologicalFactory implements Factory by returning a topological struct
type TopologicalFactory struct{}
func (TopologicalFactory) New() Consensus { return &Topological{} }
// Topological implements the Snowman interface by using a tree tracking the
// strongly preferred branch. This tree structure amortizes network polls to
// vote on more than just the next block.
type Topological struct {
metrics.Latency
metrics.Polls
metrics.Height
// pollNumber is the number of times RecordPolls has been called
pollNumber uint64
// ctx is the context this snowman instance is executing in
ctx *snow.ConsensusContext
// params are the parameters that should be used to initialize snowball
// instances
params snowball.Parameters
// head is the last accepted block
head ids.ID
// height is the height of the last accepted block
height uint64
// blocks stores the last accepted block and all the pending blocks
blocks map[ids.ID]*snowmanBlock // blockID -> snowmanBlock
// preferredIDs stores the set of IDs that are currently preferred.
preferredIDs ids.Set
// tail is the preferred block with no children
tail ids.ID
// Used in [calculateInDegree] and.
// Should only be accessed in that method.
// We use this one instance of ids.Set instead of creating a
// new ids.Set during each call to [calculateInDegree].
leaves ids.Set
// Kahn nodes used in [calculateInDegree] and [markAncestorInDegrees].
// Should only be accessed in those methods.
// We use this one map instead of creating a new map
// during each call to [calculateInDegree].
kahnNodes map[ids.ID]kahnNode
}
// Used to track the kahn topological sort status
type kahnNode struct {
// inDegree is the number of children that haven't been processed yet. If
// inDegree is 0, then this node is a leaf
inDegree int
// votes for all the children of this node, so far
votes ids.Bag
}
// Used to track which children should receive votes
type votes struct {
// parentID is the parent of all the votes provided in the votes bag
parentID ids.ID
// votes for all the children of the parent
votes ids.Bag
}
func (ts *Topological) Initialize(ctx *snow.ConsensusContext, params snowball.Parameters, rootID ids.ID, rootHeight uint64) error {
if err := params.Verify(); err != nil {
return err
}
latencyMetrics, err := metrics.NewLatency("blks", "block(s)", ctx.Log, "", ctx.Registerer)
if err != nil {
return err
}
ts.Latency = latencyMetrics
pollsMetrics, err := metrics.NewPolls("", ctx.Registerer)
if err != nil {
return err
}
ts.Polls = pollsMetrics
heightMetrics, err := metrics.NewHeight("", ctx.Registerer)
if err != nil {
return err
}
ts.Height = heightMetrics
ts.leaves = ids.Set{}
ts.kahnNodes = make(map[ids.ID]kahnNode)
ts.ctx = ctx
ts.params = params
ts.head = rootID
ts.height = rootHeight
ts.blocks = map[ids.ID]*snowmanBlock{
rootID: {sm: ts},
}
ts.tail = rootID
// Initially set the height to the last accepted block.
ts.Height.Accepted(ts.height)
return nil
}
func (ts *Topological) Parameters() snowball.Parameters { return ts.params }
func (ts *Topological) NumProcessing() int { return len(ts.blocks) - 1 }
func (ts *Topological) Add(blk Block) error {
blkID := blk.ID()
// Make sure a block is not inserted twice. This enforces the invariant that
// blocks are always added in topological order. Essentially, a block that
// is being added should never have a child that was already added.
// Additionally, this prevents any edge cases that may occur due to adding
// different blocks with the same ID.
if ts.Decided(blk) || ts.Processing(blkID) {
return errDuplicateAdd
}
ts.Latency.Issued(blkID, ts.pollNumber)
parentID := blk.Parent()
parentNode, ok := ts.blocks[parentID]
if !ok {
// If the ancestor is missing, this means the ancestor must have already
// been pruned. Therefore, the dependent should be transitively
// rejected.
if err := blk.Reject(); err != nil {
return err
}
ts.Latency.Rejected(blkID, ts.pollNumber)
return nil
}
// add the block as a child of its parent, and add the block to the tree
parentNode.AddChild(blk)
ts.blocks[blkID] = &snowmanBlock{
sm: ts,
blk: blk,
}
// If we are extending the tail, this is the new tail
if ts.tail == parentID {
ts.tail = blkID
ts.preferredIDs.Add(blkID)
}
return nil
}
func (ts *Topological) Decided(blk Block) bool {
// If the block is decided, then it must have been previously issued.
if blk.Status().Decided() {
return true
}
// If the block is marked as fetched, we can check if it has been
// transitively rejected.
return blk.Status() == choices.Processing && blk.Height() <= ts.height
}
func (ts *Topological) Processing(blkID ids.ID) bool {
// The last accepted block is in the blocks map, so we first must ensure the
// requested block isn't the last accepted block.
if blkID == ts.head {
return false
}
// If the block is in the map of current blocks and not the head, then the
// block is currently processing.
_, ok := ts.blocks[blkID]
return ok
}
func (ts *Topological) IsPreferred(blk Block) bool {
// If the block is accepted, then it must be transitively preferred.
if blk.Status() == choices.Accepted {
return true
}
return ts.preferredIDs.Contains(blk.ID())
}
func (ts *Topological) Preference() ids.ID { return ts.tail }
// The votes bag contains at most K votes for blocks in the tree. If there is a
// vote for a block that isn't in the tree, the vote is dropped.
//
// Votes are propagated transitively towards the genesis. All blocks in the tree
// that result in at least Alpha votes will record the poll on their children.
// Every other block will have an unsuccessful poll registered.
//
// After collecting which blocks should be voted on, the polls are registered
// and blocks are accepted/rejected as needed. The tail is then updated to equal
// the leaf on the preferred branch.
//
// To optimize the theoretical complexity of the vote propagation, a topological
// sort is done over the blocks that are reachable from the provided votes.
// During the sort, votes are pushed towards the genesis. To prevent interating
// over all blocks that had unsuccessful polls, we set a flag on the block to
// know that any future traversal through that block should register an
// unsuccessful poll on that block and every descendant block.
//
// The complexity of this function is:
// - Runtime = 3 * |live set| + |votes|
// - Space = 2 * |live set| + |votes|
func (ts *Topological) RecordPoll(voteBag ids.Bag) error {
// Register a new poll call
ts.pollNumber++
var voteStack []votes
if voteBag.Len() >= ts.params.Alpha {
// Since we received at least alpha votes, it's possible that
// we reached an alpha majority on a processing block.
// We must perform the traversals to calculate all block
// that reached an alpha majority.
// Populates [ts.kahnNodes] and [ts.leaves]
// Runtime = |live set| + |votes| ; Space = |live set| + |votes|
ts.calculateInDegree(voteBag)
// Runtime = |live set| ; Space = |live set|
voteStack = ts.pushVotes()
}
// Runtime = |live set| ; Space = Constant
preferred, err := ts.vote(voteStack)
if err != nil {
return err
}
// If the set of preferred IDs already contains the preference, then the
// tail is guaranteed to already be set correctly. This is because the value
// returned from vote reports the next preferred block after the last
// preferred block that was voted for. If this block was previously
// preferred, then we know that following the preferences down the chain
// will return the current tail.
if ts.preferredIDs.Contains(preferred) {
return nil
}
// Runtime = |live set| ; Space = Constant
ts.preferredIDs.Clear()
ts.tail = preferred
startBlock := ts.blocks[ts.tail]
// Runtime = |live set| ; Space = Constant
// Traverse from the preferred ID to the last accepted ancestor.
for block := startBlock; !block.Accepted(); {
ts.preferredIDs.Add(block.blk.ID())
block = ts.blocks[block.blk.Parent()]
}
// Traverse from the preferred ID to the preferred child until there are no
// children.
for block := startBlock; block.sb != nil; block = ts.blocks[ts.tail] {
ts.tail = block.sb.Preference()
ts.preferredIDs.Add(ts.tail)
}
return nil
}
func (ts *Topological) Finalized() bool { return len(ts.blocks) == 1 }
// HealthCheck returns information about the consensus health.
func (ts *Topological) HealthCheck() (interface{}, error) {
numOutstandingBlks := ts.Latency.NumProcessing()
isOutstandingBlks := numOutstandingBlks <= ts.params.MaxOutstandingItems
healthy := isOutstandingBlks
details := map[string]interface{}{
"outstandingBlocks": numOutstandingBlks,
}
// check for long running blocks
timeReqRunning := ts.Latency.MeasureAndGetOldestDuration()
isProcessingTime := timeReqRunning <= ts.params.MaxItemProcessingTime
healthy = healthy && isProcessingTime
details["longestRunningBlock"] = timeReqRunning.String()
if !healthy {
var errorReasons []string
if !isOutstandingBlks {
errorReasons = append(errorReasons, fmt.Sprintf("number of outstanding blocks %d > %d", numOutstandingBlks, ts.params.MaxOutstandingItems))
}
if !isProcessingTime {
errorReasons = append(errorReasons, fmt.Sprintf("block processing time %s > %s", timeReqRunning, ts.params.MaxItemProcessingTime))
}
return details, fmt.Errorf("snowman consensus is not healthy reason: %s", strings.Join(errorReasons, ", "))
}
return details, nil
}
// takes in a list of votes and sets up the topological ordering. Returns the
// reachable section of the graph annotated with the number of inbound edges and
// the non-transitively applied votes. Also returns the list of leaf blocks.
func (ts *Topological) calculateInDegree(votes ids.Bag) {
// Clear the Kahn node set
for k := range ts.kahnNodes {
delete(ts.kahnNodes, k)
}
// Clear the leaf set
ts.leaves.Clear()
for _, vote := range votes.List() {
votedBlock, validVote := ts.blocks[vote]
// If the vote is for a block that isn't in the current pending set,
// then the vote is dropped
if !validVote {
continue
}
// If the vote is for the last accepted block, the vote is dropped
if votedBlock.Accepted() {
continue
}
// The parent contains the snowball instance of its children
parentID := votedBlock.blk.Parent()
// Add the votes for this block to the parent's set of responses
numVotes := votes.Count(vote)
kahn, previouslySeen := ts.kahnNodes[parentID]
kahn.votes.AddCount(vote, numVotes)
ts.kahnNodes[parentID] = kahn
// If the parent block already had registered votes, then there is no
// need to iterate into the parents
if previouslySeen {
continue
}
// If I've never seen this parent block before, it is currently a leaf.
ts.leaves.Add(parentID)
// iterate through all the block's ancestors and set up the inDegrees of
// the blocks
for n := ts.blocks[parentID]; !n.Accepted(); n = ts.blocks[parentID] {
parentID = n.blk.Parent()
// Increase the inDegree by one
kahn := ts.kahnNodes[parentID]
kahn.inDegree++
ts.kahnNodes[parentID] = kahn
// If we have already seen this block, then we shouldn't increase
// the inDegree of the ancestors through this block again.
if kahn.inDegree != 1 {
break
}
// If I am transitively seeing this block for the first time, either
// the block was previously unknown or it was previously a leaf.
// Regardless, it shouldn't be tracked as a leaf.
ts.leaves.Remove(parentID)
}
}
}
// convert the tree into a branch of snowball instances with at least alpha
// votes
func (ts *Topological) pushVotes() []votes {
voteStack := make([]votes, 0, len(ts.kahnNodes))
for ts.leaves.Len() > 0 {
// Pop one element of [leaves]
leafID, _ := ts.leaves.Pop()
// Should never return false because we just
// checked that [ts.leaves] is non-empty.
// get the block and sort information about the block
kahnNode := ts.kahnNodes[leafID]
block := ts.blocks[leafID]
// If there are at least Alpha votes, then this block needs to record
// the poll on the snowball instance
if kahnNode.votes.Len() >= ts.params.Alpha {
voteStack = append(voteStack, votes{
parentID: leafID,
votes: kahnNode.votes,
})
}
// If the block is accepted, then we don't need to push votes to the
// parent block
if block.Accepted() {
continue
}
parentID := block.blk.Parent()
// Remove an inbound edge from the parent kahn node and push the votes.
parentKahnNode := ts.kahnNodes[parentID]
parentKahnNode.inDegree--
parentKahnNode.votes.AddCount(leafID, kahnNode.votes.Len())
ts.kahnNodes[parentID] = parentKahnNode
// If the inDegree is zero, then the parent node is now a leaf
if parentKahnNode.inDegree == 0 {
ts.leaves.Add(parentID)
}
}
return voteStack
}
// apply votes to the branch that received an Alpha threshold and returns the
// next preferred block after the last preferred block that received an Alpha
// threshold.
func (ts *Topological) vote(voteStack []votes) (ids.ID, error) {
// If the voteStack is empty, then the full tree should falter. This won't
// change the preferred branch.
if len(voteStack) == 0 {
headBlock := ts.blocks[ts.head]
headBlock.shouldFalter = true
if numProcessing := len(ts.blocks) - 1; numProcessing > 0 {
ts.ctx.Log.Verbo("no progress was made after processing pending blocks",
zap.Int("numProcessing", numProcessing),
)
ts.Polls.Failed()
}
return ts.tail, nil
}
// keep track of the new preferred block
newPreferred := ts.head
onPreferredBranch := true
pollSuccessful := false
for len(voteStack) > 0 {
// pop a vote off the stack
newStackSize := len(voteStack) - 1
vote := voteStack[newStackSize]
voteStack = voteStack[:newStackSize]
// get the block that we are going to vote on
parentBlock, notRejected := ts.blocks[vote.parentID]
// if the block block we are going to vote on was already rejected, then
// we should stop applying the votes
if !notRejected {
break
}
// keep track of transitive falters to propagate to this block's
// children
shouldTransitivelyFalter := parentBlock.shouldFalter
// if the block was previously marked as needing to falter, the block
// should falter before applying the vote
if shouldTransitivelyFalter {
ts.ctx.Log.Verbo("resetting confidence below parent",
zap.Stringer("parentID", vote.parentID),
)
parentBlock.sb.RecordUnsuccessfulPoll()
parentBlock.shouldFalter = false
}
// apply the votes for this snowball instance
pollSuccessful = parentBlock.sb.RecordPoll(vote.votes) || pollSuccessful
// Only accept when you are finalized and the head.
if parentBlock.sb.Finalized() && ts.head == vote.parentID {
if err := ts.acceptPreferredChild(parentBlock); err != nil {
return ids.ID{}, err
}
// by accepting the child of parentBlock, the last accepted block is
// no longer voteParentID, but its child. So, voteParentID can be
// removed from the tree.
delete(ts.blocks, vote.parentID)
}
// If we are on the preferred branch, then the parent's preference is
// the next block on the preferred branch.
parentPreference := parentBlock.sb.Preference()
if onPreferredBranch {
newPreferred = parentPreference
}
// Get the ID of the child that is having a RecordPoll called. All other
// children will need to have their confidence reset. If there isn't a
// child having RecordPoll called, then the nextID will default to the
// nil ID.
nextID := ids.ID{}
if len(voteStack) > 0 {
nextID = voteStack[newStackSize-1].parentID
}
// If we are on the preferred branch and the nextID is the preference of
// the snowball instance, then we are following the preferred branch.
onPreferredBranch = onPreferredBranch && nextID == parentPreference
// If there wasn't an alpha threshold on the branch (either on this vote
// or a past transitive vote), I should falter now.
for childID := range parentBlock.children {
// If we don't need to transitively falter and the child is going to
// have RecordPoll called on it, then there is no reason to reset
// the block's confidence
if !shouldTransitivelyFalter && childID == nextID {
continue
}
// If we finalized a child of the current block, then all other
// children will have been rejected and removed from the tree.
// Therefore, we need to make sure the child is still in the tree.
childBlock, notRejected := ts.blocks[childID]
if notRejected {
ts.ctx.Log.Verbo("defering confidence reset of child block",
zap.Stringer("childID", childID),
)
ts.ctx.Log.Verbo("voting for next block",
zap.Stringer("nextID", nextID),
)
// If the child is ever voted for positively, the confidence
// must be reset first.
childBlock.shouldFalter = true
}
}
}
if pollSuccessful {
ts.Polls.Successful()
} else {
ts.Polls.Failed()
}
return newPreferred, nil
}
// Accepts the preferred child of the provided snowman block. By accepting the
// preferred child, all other children will be rejected. When these children are
// rejected, all their descendants will be rejected.
//
// We accept a block once its parent's snowball instance has finalized
// with it as the preference.
func (ts *Topological) acceptPreferredChild(n *snowmanBlock) error {
// We are finalizing the block's child, so we need to get the preference
pref := n.sb.Preference()
// Get the child and accept it
child := n.children[pref]
// Notify anyone listening that this block was accepted.
bytes := child.Bytes()
// Note that DecisionAcceptor.Accept / ConsensusAcceptor.Accept must be
// called before child.Accept to honor Acceptor.Accept's invariant.
if err := ts.ctx.DecisionAcceptor.Accept(ts.ctx, pref, bytes); err != nil {
return err
}
if err := ts.ctx.ConsensusAcceptor.Accept(ts.ctx, pref, bytes); err != nil {
return err
}
ts.ctx.Log.Trace("accepting block",
zap.Stringer("blkID", pref),
)
if err := child.Accept(); err != nil {
return err
}
// Because this is the newest accepted block, this is the new head.
ts.head = pref
ts.height = child.Height()
// Remove the decided block from the set of processing IDs, as its status
// now implies its preferredness.
ts.preferredIDs.Remove(pref)
ts.Latency.Accepted(pref, ts.pollNumber)
ts.Height.Accepted(ts.height)
// Because ts.blocks contains the last accepted block, we don't delete the
// block from the blocks map here.
rejects := make([]ids.ID, 0, len(n.children)-1)
for childID, child := range n.children {
if childID == pref {
// don't reject the block we just accepted
continue
}
ts.ctx.Log.Trace("rejecting block",
zap.String("reason", "conflict with accepted block"),
zap.Stringer("rejectedID", childID),
zap.Stringer("conflictedID", pref),
)
if err := child.Reject(); err != nil {
return err
}
ts.Latency.Rejected(childID, ts.pollNumber)
// Track which blocks have been directly rejected
rejects = append(rejects, childID)
}
// reject all the descendants of the blocks we just rejected
return ts.rejectTransitively(rejects)
}
// Takes in a list of rejected ids and rejects all descendants of these IDs
func (ts *Topological) rejectTransitively(rejected []ids.ID) error {
// the rejected array is treated as a stack, with the next element at index
// 0 and the last element at the end of the slice.
for len(rejected) > 0 {
// pop the rejected ID off the stack
newRejectedSize := len(rejected) - 1
rejectedID := rejected[newRejectedSize]
rejected = rejected[:newRejectedSize]
// get the rejected node, and remove it from the tree
rejectedNode := ts.blocks[rejectedID]
delete(ts.blocks, rejectedID)
for childID, child := range rejectedNode.children {
if err := child.Reject(); err != nil {
return err
}
ts.Latency.Rejected(childID, ts.pollNumber)
// add the newly rejected block to the end of the stack
rejected = append(rejected, childID)
}
}
return nil
}