prysm-pulse/beacon-chain/forkchoice/doubly-linked-tree/store.go
terencechain 78d49fda13
Minor cleanup to forkchoice pkg (#12078)
* Minor cleanup to forkchoice pkg

* Rm implementation

---------

Co-authored-by: prylabs-bulldozer[bot] <58059840+prylabs-bulldozer[bot]@users.noreply.github.com>
2023-03-06 17:01:36 +00:00

248 lines
7.7 KiB
Go

package doublylinkedtree
import (
"context"
"fmt"
"time"
"github.com/pkg/errors"
fieldparams "github.com/prysmaticlabs/prysm/v3/config/fieldparams"
"github.com/prysmaticlabs/prysm/v3/config/params"
"github.com/prysmaticlabs/prysm/v3/consensus-types/primitives"
"github.com/prysmaticlabs/prysm/v3/time/slots"
"go.opencensus.io/trace"
)
// head starts from justified root and then follows the best descendant links
// to find the best block for head.
func (s *Store) head(ctx context.Context) ([32]byte, error) {
ctx, span := trace.StartSpan(ctx, "doublyLinkedForkchoice.head")
defer span.End()
if err := ctx.Err(); err != nil {
return [32]byte{}, err
}
// JustifiedRoot has to be known
justifiedNode, ok := s.nodeByRoot[s.justifiedCheckpoint.Root]
if !ok || justifiedNode == nil {
// If the justifiedCheckpoint is from genesis, then the root is
// zeroHash. In this case it should be the root of forkchoice
// tree.
if s.justifiedCheckpoint.Epoch == params.BeaconConfig().GenesisEpoch {
justifiedNode = s.treeRootNode
} else {
return [32]byte{}, errors.WithMessage(errUnknownJustifiedRoot, fmt.Sprintf("%#x", s.justifiedCheckpoint.Root))
}
}
// If the justified node doesn't have a best descendant,
// the best node is itself.
bestDescendant := justifiedNode.bestDescendant
if bestDescendant == nil {
bestDescendant = justifiedNode
}
currentEpoch := slots.EpochsSinceGenesis(time.Unix(int64(s.genesisTime), 0))
if !bestDescendant.viableForHead(s.justifiedCheckpoint.Epoch, currentEpoch) {
s.allTipsAreInvalid = true
return [32]byte{}, fmt.Errorf("head at slot %d with weight %d is not eligible, finalizedEpoch, justified Epoch %d, %d != %d, %d",
bestDescendant.slot, bestDescendant.weight/10e9, bestDescendant.finalizedEpoch, bestDescendant.justifiedEpoch, s.finalizedCheckpoint.Epoch, s.justifiedCheckpoint.Epoch)
}
s.allTipsAreInvalid = false
// Update metrics.
if bestDescendant != s.headNode {
headChangesCount.Inc()
headSlotNumber.Set(float64(bestDescendant.slot))
s.headNode = bestDescendant
}
return bestDescendant.root, nil
}
// insert registers a new block node to the fork choice store's node list.
// It then updates the new node's parent with best child and descendant node.
func (s *Store) insert(ctx context.Context,
slot primitives.Slot,
root, parentRoot, payloadHash [fieldparams.RootLength]byte,
justifiedEpoch, finalizedEpoch primitives.Epoch) (*Node, error) {
ctx, span := trace.StartSpan(ctx, "doublyLinkedForkchoice.insert")
defer span.End()
// Return if the block has been inserted into Store before.
if n, ok := s.nodeByRoot[root]; ok {
return n, nil
}
parent := s.nodeByRoot[parentRoot]
n := &Node{
slot: slot,
root: root,
parent: parent,
justifiedEpoch: justifiedEpoch,
unrealizedJustifiedEpoch: justifiedEpoch,
finalizedEpoch: finalizedEpoch,
unrealizedFinalizedEpoch: finalizedEpoch,
optimistic: true,
payloadHash: payloadHash,
timestamp: uint64(time.Now().Unix()),
}
s.nodeByPayload[payloadHash] = n
s.nodeByRoot[root] = n
if parent == nil {
if s.treeRootNode == nil {
s.treeRootNode = n
s.headNode = n
s.highestReceivedNode = n
} else {
return n, errInvalidParentRoot
}
} else {
parent.children = append(parent.children, n)
// Apply proposer boost
timeNow := uint64(time.Now().Unix())
if timeNow < s.genesisTime {
return n, nil
}
secondsIntoSlot := (timeNow - s.genesisTime) % params.BeaconConfig().SecondsPerSlot
currentSlot := slots.CurrentSlot(s.genesisTime)
boostThreshold := params.BeaconConfig().SecondsPerSlot / params.BeaconConfig().IntervalsPerSlot
if currentSlot == slot && secondsIntoSlot < boostThreshold {
s.proposerBoostRoot = root
}
// Update best descendants
jEpoch := s.justifiedCheckpoint.Epoch
fEpoch := s.finalizedCheckpoint.Epoch
if err := s.treeRootNode.updateBestDescendant(ctx, jEpoch, fEpoch, slots.ToEpoch(currentSlot)); err != nil {
return n, err
}
}
// Update metrics.
processedBlockCount.Inc()
nodeCount.Set(float64(len(s.nodeByRoot)))
// Only update received block slot if it's within epoch from current time.
if slot+params.BeaconConfig().SlotsPerEpoch > slots.CurrentSlot(s.genesisTime) {
s.receivedBlocksLastEpoch[slot%params.BeaconConfig().SlotsPerEpoch] = slot
}
// Update highest slot tracking.
if slot > s.highestReceivedNode.slot {
s.highestReceivedNode = n
}
return n, nil
}
// pruneFinalizedNodeByRootMap prunes the `nodeByRoot` map
// starting from `node` down to the finalized Node or to a leaf of the Fork
// choice store.
func (s *Store) pruneFinalizedNodeByRootMap(ctx context.Context, node, finalizedNode *Node) error {
if ctx.Err() != nil {
return ctx.Err()
}
if node == finalizedNode {
return nil
}
for _, child := range node.children {
if err := s.pruneFinalizedNodeByRootMap(ctx, child, finalizedNode); err != nil {
return err
}
}
node.children = nil
delete(s.nodeByRoot, node.root)
delete(s.nodeByPayload, node.payloadHash)
return nil
}
// prune prunes the fork choice store. It removes all nodes that compete with the finalized root.
// This function does not prune for invalid optimistically synced nodes, it deals only with pruning upon finalization
func (s *Store) prune(ctx context.Context) error {
ctx, span := trace.StartSpan(ctx, "doublyLinkedForkchoice.Prune")
defer span.End()
finalizedRoot := s.finalizedCheckpoint.Root
finalizedEpoch := s.finalizedCheckpoint.Epoch
finalizedNode, ok := s.nodeByRoot[finalizedRoot]
if !ok || finalizedNode == nil {
return errors.WithMessage(errUnknownFinalizedRoot, fmt.Sprintf("%#x", finalizedRoot))
}
// return early if we haven't changed the finalized checkpoint
if finalizedNode.parent == nil {
return nil
}
// Prune nodeByRoot starting from root
if err := s.pruneFinalizedNodeByRootMap(ctx, s.treeRootNode, finalizedNode); err != nil {
return err
}
finalizedNode.parent = nil
s.treeRootNode = finalizedNode
prunedCount.Inc()
// Prune all children of the finalized checkpoint block that are incompatible with it
checkpointMaxSlot, err := slots.EpochStart(finalizedEpoch)
if err != nil {
return errors.Wrap(err, "could not compute epoch start")
}
if finalizedNode.slot == checkpointMaxSlot {
return nil
}
for _, child := range finalizedNode.children {
if child != nil && child.slot <= checkpointMaxSlot {
if err := s.pruneFinalizedNodeByRootMap(ctx, child, finalizedNode); err != nil {
return errors.Wrap(err, "could not prune incompatible finalized child")
}
}
}
return nil
}
// tips returns a list of possible heads from fork choice store, it returns the
// roots and the slots of the leaf nodes.
func (s *Store) tips() ([][32]byte, []primitives.Slot) {
var roots [][32]byte
var slots []primitives.Slot
for root, node := range s.nodeByRoot {
if len(node.children) == 0 {
roots = append(roots, root)
slots = append(slots, node.slot)
}
}
return roots, slots
}
// HighestReceivedBlockSlot returns the highest slot received by the forkchoice
func (f *ForkChoice) HighestReceivedBlockSlot() primitives.Slot {
if f.store.highestReceivedNode == nil {
return 0
}
return f.store.highestReceivedNode.slot
}
// ReceivedBlocksLastEpoch returns the number of blocks received in the last epoch
func (f *ForkChoice) ReceivedBlocksLastEpoch() (uint64, error) {
count := uint64(0)
lowerBound := slots.CurrentSlot(f.store.genesisTime)
var err error
if lowerBound > fieldparams.SlotsPerEpoch {
lowerBound, err = lowerBound.SafeSub(fieldparams.SlotsPerEpoch)
if err != nil {
return 0, err
}
}
for _, s := range f.store.receivedBlocksLastEpoch {
if s != 0 && lowerBound <= s {
count++
}
}
return count, nil
}