zolfa
/
tendermint

package evidence
import (	"context"	"fmt"	"runtime/debug"	"sync"	"time"
	clist "github.com/tendermint/tendermint/internal/libs/clist"	tmsync "github.com/tendermint/tendermint/internal/libs/sync"	"github.com/tendermint/tendermint/internal/p2p"	"github.com/tendermint/tendermint/libs/log"	"github.com/tendermint/tendermint/libs/service"	tmproto "github.com/tendermint/tendermint/proto/tendermint/types"	"github.com/tendermint/tendermint/types")
var _ service.Service = (*Reactor)(nil)
const (	EvidenceChannel = p2p.ChannelID(0x38)
	maxMsgSize = 1048576 // 1MB TODO make it configurable

	// broadcast all uncommitted evidence this often. This sets when the reactor
	// goes back to the start of the list and begins sending the evidence again.
	// Most evidence should be committed in the very next block that is why we wait
	// just over the block production rate before sending evidence again.
	broadcastEvidenceIntervalS = 10)
// GetChannelDescriptor produces an instance of a descriptor for this
// package's required channels.
func GetChannelDescriptor() *p2p.ChannelDescriptor {	return &p2p.ChannelDescriptor{		ID:                  EvidenceChannel,		MessageType:         new(tmproto.EvidenceList),		Priority:            6,		RecvMessageCapacity: maxMsgSize,		RecvBufferCapacity:  32,	}}
// Reactor handles evpool evidence broadcasting amongst peers.
type Reactor struct {	service.BaseService
	evpool      *Pool	evidenceCh  *p2p.Channel	peerUpdates *p2p.PeerUpdates	closeCh     chan struct{}
	peerWG sync.WaitGroup
	mtx          tmsync.Mutex	peerRoutines map[types.NodeID]*tmsync.Closer}
// NewReactor returns a reference to a new evidence reactor, which implements the
// service.Service interface. It accepts a p2p Channel dedicated for handling
// envelopes with EvidenceList messages.
func NewReactor(	logger log.Logger,	evidenceCh *p2p.Channel,	peerUpdates *p2p.PeerUpdates,	evpool *Pool,) *Reactor {	r := &Reactor{		evpool:       evpool,		evidenceCh:   evidenceCh,		peerUpdates:  peerUpdates,		closeCh:      make(chan struct{}),		peerRoutines: make(map[types.NodeID]*tmsync.Closer),	}
	r.BaseService = *service.NewBaseService(logger, "Evidence", r)	return r}
// OnStart starts separate go routines for each p2p Channel and listens for
// envelopes on each. In addition, it also listens for peer updates and handles
// messages on that p2p channel accordingly. The caller must be sure to execute
// OnStop to ensure the outbound p2p Channels are closed. No error is returned.
func (r *Reactor) OnStart(ctx context.Context) error {	go r.processEvidenceCh(ctx)	go r.processPeerUpdates(ctx)
	return nil}
// OnStop stops the reactor by signaling to all spawned goroutines to exit and
// blocking until they all exit.
func (r *Reactor) OnStop() {	r.mtx.Lock()	for _, c := range r.peerRoutines {		c.Close()	}	r.mtx.Unlock()
	// Wait for all spawned peer evidence broadcasting goroutines to gracefully
	// exit.
	r.peerWG.Wait()
	// Close closeCh to signal to all spawned goroutines to gracefully exit. All
	// p2p Channels should execute Close().
	close(r.closeCh)
	// Wait for all p2p Channels to be closed before returning. This ensures we
	// can easily reason about synchronization of all p2p Channels and ensure no
	// panics will occur.
	<-r.peerUpdates.Done()
	// Close the evidence db
	r.evpool.Close()}
// handleEvidenceMessage handles envelopes sent from peers on the EvidenceChannel.
// It returns an error only if the Envelope.Message is unknown for this channel
// or if the given evidence is invalid. This should never be called outside of
// handleMessage.
func (r *Reactor) handleEvidenceMessage(envelope p2p.Envelope) error {	logger := r.Logger.With("peer", envelope.From)
	switch msg := envelope.Message.(type) {	case *tmproto.EvidenceList:		// TODO: Refactor the Evidence type to not contain a list since we only ever
		// send and receive one piece of evidence at a time. Or potentially consider
		// batching evidence.
		//
		// see: https://github.com/tendermint/tendermint/issues/4729
		for i := 0; i < len(msg.Evidence); i++ {			ev, err := types.EvidenceFromProto(&msg.Evidence[i])			if err != nil {				logger.Error("failed to convert evidence", "err", err)				continue			}
			if err := r.evpool.AddEvidence(ev); err != nil {				// If we're given invalid evidence by the peer, notify the router that
				// we should remove this peer by returning an error.
				if _, ok := err.(*types.ErrInvalidEvidence); ok {					return err				}			}		}
	default:		return fmt.Errorf("received unknown message: %T", msg)	}
	return nil}
// handleMessage handles an Envelope sent from a peer on a specific p2p Channel.
// It will handle errors and any possible panics gracefully. A caller can handle
// any error returned by sending a PeerError on the respective channel.
func (r *Reactor) handleMessage(chID p2p.ChannelID, envelope p2p.Envelope) (err error) {	defer func() {		if e := recover(); e != nil {			err = fmt.Errorf("panic in processing message: %v", e)			r.Logger.Error(				"recovering from processing message panic",				"err", err,				"stack", string(debug.Stack()),			)		}	}()
	r.Logger.Debug("received message", "message", envelope.Message, "peer", envelope.From)
	switch chID {	case EvidenceChannel:		err = r.handleEvidenceMessage(envelope)
	default:		err = fmt.Errorf("unknown channel ID (%d) for envelope (%v)", chID, envelope)	}
	return err}
// processEvidenceCh implements a blocking event loop where we listen for p2p
// Envelope messages from the evidenceCh.
func (r *Reactor) processEvidenceCh(ctx context.Context) {	for {		select {		case <-ctx.Done():			return		case envelope := <-r.evidenceCh.In:			if err := r.handleMessage(r.evidenceCh.ID, envelope); err != nil {				r.Logger.Error("failed to process message", "ch_id", r.evidenceCh.ID, "envelope", envelope, "err", err)				r.evidenceCh.Error <- p2p.PeerError{					NodeID: envelope.From,					Err:    err,				}			}
		case <-r.closeCh:			r.Logger.Debug("stopped listening on evidence channel; closing...")			return		}	}}
// processPeerUpdate processes a PeerUpdate. For new or live peers it will check
// if an evidence broadcasting goroutine needs to be started. For down or
// removed peers, it will check if an evidence broadcasting goroutine
// exists and signal that it should exit.
//
// FIXME: The peer may be behind in which case it would simply ignore the
// evidence and treat it as invalid. This would cause the peer to disconnect.
// The peer may also receive the same piece of evidence multiple times if it
// connects/disconnects frequently from the broadcasting peer(s).
//
// REF: https://github.com/tendermint/tendermint/issues/4727
func (r *Reactor) processPeerUpdate(ctx context.Context, peerUpdate p2p.PeerUpdate) {	r.Logger.Debug("received peer update", "peer", peerUpdate.NodeID, "status", peerUpdate.Status)
	r.mtx.Lock()	defer r.mtx.Unlock()
	switch peerUpdate.Status {	case p2p.PeerStatusUp:		// Do not allow starting new evidence broadcast loops after reactor shutdown
		// has been initiated. This can happen after we've manually closed all
		// peer broadcast loops and closed r.closeCh, but the router still sends
		// in-flight peer updates.
		if !r.IsRunning() {			return		}
		// Check if we've already started a goroutine for this peer, if not we create
		// a new done channel so we can explicitly close the goroutine if the peer
		// is later removed, we increment the waitgroup so the reactor can stop
		// safely, and finally start the goroutine to broadcast evidence to that peer.
		_, ok := r.peerRoutines[peerUpdate.NodeID]		if !ok {			closer := tmsync.NewCloser()
			r.peerRoutines[peerUpdate.NodeID] = closer			r.peerWG.Add(1)			go r.broadcastEvidenceLoop(ctx, peerUpdate.NodeID, closer)		}
	case p2p.PeerStatusDown:		// Check if we've started an evidence broadcasting goroutine for this peer.
		// If we have, we signal to terminate the goroutine via the channel's closure.
		// This will internally decrement the peer waitgroup and remove the peer
		// from the map of peer evidence broadcasting goroutines.
		closer, ok := r.peerRoutines[peerUpdate.NodeID]		if ok {			closer.Close()		}	}}
// processPeerUpdates initiates a blocking process where we listen for and handle
// PeerUpdate messages. When the reactor is stopped, we will catch the signal and
// close the p2p PeerUpdatesCh gracefully.
func (r *Reactor) processPeerUpdates(ctx context.Context) {	defer r.peerUpdates.Close()
	for {		select {		case peerUpdate := <-r.peerUpdates.Updates():			r.processPeerUpdate(ctx, peerUpdate)		case <-ctx.Done():			return		case <-r.closeCh:			r.Logger.Debug("stopped listening on peer updates channel; closing...")			return		}	}}
// broadcastEvidenceLoop starts a blocking process that continuously reads pieces
// of evidence off of a linked-list and sends the evidence in a p2p Envelope to
// the given peer by ID. This should be invoked in a goroutine per unique peer
// ID via an appropriate PeerUpdate. The goroutine can be signaled to gracefully
// exit by either explicitly closing the provided doneCh or by the reactor
// signaling to stop.
//
// TODO: This should be refactored so that we do not blindly gossip evidence
// that the peer has already received or may not be ready for.
//
// REF: https://github.com/tendermint/tendermint/issues/4727
func (r *Reactor) broadcastEvidenceLoop(ctx context.Context, peerID types.NodeID, closer *tmsync.Closer) {	var next *clist.CElement
	defer func() {		r.mtx.Lock()		delete(r.peerRoutines, peerID)		r.mtx.Unlock()
		r.peerWG.Done()
		if e := recover(); e != nil {			r.Logger.Error(				"recovering from broadcasting evidence loop",				"err", e,				"stack", string(debug.Stack()),			)		}	}()
	for {		// This happens because the CElement we were looking at got garbage
		// collected (removed). That is, .NextWaitChan() returned nil. So we can go
		// ahead and start from the beginning.
		if next == nil {			select {			case <-r.evpool.EvidenceWaitChan(): // wait until next evidence is available
				if next = r.evpool.EvidenceFront(); next == nil {					continue				}
			case <-ctx.Done():				return			case <-closer.Done():				// The peer is marked for removal via a PeerUpdate as the doneCh was
				// explicitly closed to signal we should exit.
				return
			case <-r.closeCh:				// The reactor has signaled that we are stopped and thus we should
				// implicitly exit this peer's goroutine.
				return			}		}
		ev := next.Value.(types.Evidence)		evProto, err := types.EvidenceToProto(ev)		if err != nil {			panic(fmt.Errorf("failed to convert evidence: %w", err))		}
		// Send the evidence to the corresponding peer. Note, the peer may be behind
		// and thus would not be able to process the evidence correctly. Also, the
		// peer may receive this piece of evidence multiple times if it added and
		// removed frequently from the broadcasting peer.
		select {		case <-ctx.Done():			return		case r.evidenceCh.Out <- p2p.Envelope{			To: peerID,			Message: &tmproto.EvidenceList{				Evidence: []tmproto.Evidence{*evProto},			},		}:		}		r.Logger.Debug("gossiped evidence to peer", "evidence", ev, "peer", peerID)
		select {		case <-time.After(time.Second * broadcastEvidenceIntervalS):			// start from the beginning after broadcastEvidenceIntervalS seconds
			next = nil
		case <-next.NextWaitChan():			next = next.Next()
		case <-closer.Done():			// The peer is marked for removal via a PeerUpdate as the doneCh was
			// explicitly closed to signal we should exit.
			return
		case <-r.closeCh:			// The reactor has signaled that we are stopped and thus we should
			// implicitly exit this peer's goroutine.
			return		}	}}