// nolint:unused package v2 import ( "fmt" "math" "math/rand" "time" "github.com/tendermint/tendermint/p2p" ) type blockState int const ( blockStateUnknown blockState = iota blockStateNew blockStatePending blockStateReceived blockStateProcessed ) func (e blockState) String() string { switch e { case blockStateUnknown: return "Unknown" case blockStateNew: return "New" case blockStatePending: return "Pending" case blockStateReceived: return "Received" case blockStateProcessed: return "Processed" default: return fmt.Sprintf("unknown blockState: %d", e) } } type peerState int const ( peerStateNew = iota peerStateReady peerStateRemoved ) func (e peerState) String() string { switch e { case peerStateNew: return "New" case peerStateReady: return "Ready" case peerStateRemoved: return "Removed" default: return fmt.Sprintf("unknown peerState: %d", e) } } type scPeer struct { peerID p2p.ID state peerState height int64 lastTouched time.Time lastRate int64 } func newScPeer(peerID p2p.ID) *scPeer { return &scPeer{ peerID: peerID, state: peerStateNew, height: -1, lastTouched: time.Time{}, } } // The schedule is a composite data structure which allows a scheduler to keep // track of which blocks have been scheduled into which state. type schedule struct { initHeight int64 // a list of blocks in which blockState blockStates map[int64]blockState // a map of peerID to schedule specific peer struct `scPeer` used to keep // track of peer specific state peers map[p2p.ID]*scPeer // a map of heights to the peer we are waiting for a response from pendingBlocks map[int64]p2p.ID // the time at which a block was put in blockStatePending pendingTime map[int64]time.Time // the peerID of the peer which put the block in blockStateReceived receivedBlocks map[int64]p2p.ID } func newSchedule(initHeight int64) *schedule { sc := schedule{ initHeight: initHeight, blockStates: make(map[int64]blockState), peers: make(map[p2p.ID]*scPeer), pendingBlocks: make(map[int64]p2p.ID), pendingTime: make(map[int64]time.Time), receivedBlocks: make(map[int64]p2p.ID), } sc.setStateAtHeight(initHeight, blockStateNew) return &sc } func (sc *schedule) addPeer(peerID p2p.ID) error { if _, ok := sc.peers[peerID]; ok { return fmt.Errorf("Cannot add duplicate peer %s", peerID) } sc.peers[peerID] = newScPeer(peerID) return nil } func (sc *schedule) touchPeer(peerID p2p.ID, time time.Time) error { peer, ok := sc.peers[peerID] if !ok { return fmt.Errorf("Couldn't find peer %s", peerID) } if peer.state == peerStateRemoved { return fmt.Errorf("Tried to touch peer in peerStateRemoved") } peer.lastTouched = time return nil } func (sc *schedule) removePeer(peerID p2p.ID) error { peer, ok := sc.peers[peerID] if !ok { return fmt.Errorf("Couldn't find peer %s", peerID) } if peer.state == peerStateRemoved { return fmt.Errorf("Tried to remove peer %s in peerStateRemoved", peerID) } for height, pendingPeerID := range sc.pendingBlocks { if pendingPeerID == peerID { sc.setStateAtHeight(height, blockStateNew) delete(sc.pendingTime, height) delete(sc.pendingBlocks, height) } } for height, rcvPeerID := range sc.receivedBlocks { if rcvPeerID == peerID { sc.setStateAtHeight(height, blockStateNew) delete(sc.receivedBlocks, height) } } peer.state = peerStateRemoved return nil } func (sc *schedule) setPeerHeight(peerID p2p.ID, height int64) error { peer, ok := sc.peers[peerID] if !ok { return fmt.Errorf("Can't find peer %s", peerID) } if peer.state == peerStateRemoved { return fmt.Errorf("Cannot set peer height for a peer in peerStateRemoved") } if height < peer.height { return fmt.Errorf("Cannot move peer height lower. from %d to %d", peer.height, height) } peer.height = height peer.state = peerStateReady for i := sc.minHeight(); i <= height; i++ { if sc.getStateAtHeight(i) == blockStateUnknown { sc.setStateAtHeight(i, blockStateNew) } } return nil } func (sc *schedule) getStateAtHeight(height int64) blockState { if height < sc.initHeight { return blockStateProcessed } else if state, ok := sc.blockStates[height]; ok { return state } else { return blockStateUnknown } } func (sc *schedule) getPeersAtHeight(height int64) []*scPeer { peers := []*scPeer{} for _, peer := range sc.peers { if peer.height >= height { peers = append(peers, peer) } } return peers } func (sc *schedule) peersInactiveSince(duration time.Duration, now time.Time) []p2p.ID { peers := []p2p.ID{} for _, peer := range sc.peers { if now.Sub(peer.lastTouched) > duration { peers = append(peers, peer.peerID) } } return peers } func (sc *schedule) peersSlowerThan(minSpeed int64) []p2p.ID { peers := []p2p.ID{} for _, peer := range sc.peers { if peer.lastRate < minSpeed { peers = append(peers, peer.peerID) } } return peers } func (sc *schedule) setStateAtHeight(height int64, state blockState) { sc.blockStates[height] = state } func (sc *schedule) markReceived(peerID p2p.ID, height int64, size int64, now time.Time) error { peer, ok := sc.peers[peerID] if !ok { return fmt.Errorf("Can't find peer %s", peerID) } if peer.state == peerStateRemoved { return fmt.Errorf("Cannot receive blocks from removed peer %s", peerID) } if state := sc.getStateAtHeight(height); state != blockStatePending || sc.pendingBlocks[height] != peerID { return fmt.Errorf("Received block %d from peer %s without being requested", height, peerID) } pendingTime, ok := sc.pendingTime[height] if !ok || now.Sub(pendingTime) <= 0 { return fmt.Errorf("Clock error. Block %d received at %s but requested at %s", height, pendingTime, now) } peer.lastRate = size / int64(now.Sub(pendingTime).Seconds()) sc.setStateAtHeight(height, blockStateReceived) delete(sc.pendingBlocks, height) delete(sc.pendingTime, height) sc.receivedBlocks[height] = peerID return nil } func (sc *schedule) markPending(peerID p2p.ID, height int64, time time.Time) error { peer, ok := sc.peers[peerID] if !ok { return fmt.Errorf("Can't find peer %s", peerID) } state := sc.getStateAtHeight(height) if state != blockStateNew { return fmt.Errorf("Block %d should be in blockStateNew but was %s", height, state) } if peer.state != peerStateReady { return fmt.Errorf("Cannot schedule %d from %s in %s", height, peerID, peer.state) } if height > peer.height { return fmt.Errorf("Cannot request height %d from peer %s who is at height %d", height, peerID, peer.height) } sc.setStateAtHeight(height, blockStatePending) sc.pendingBlocks[height] = peerID // XXX: to make this more accurate we can introduce a message from // the IO routine which indicates the time the request was put on the wire sc.pendingTime[height] = time return nil } func (sc *schedule) markProcessed(height int64) error { state := sc.getStateAtHeight(height) if state != blockStateReceived { return fmt.Errorf("Can't mark height %d received from block state %s", height, state) } delete(sc.receivedBlocks, height) sc.setStateAtHeight(height, blockStateProcessed) return nil } // allBlockProcessed returns true if all blocks are in blockStateProcessed and // determines if the schedule has been completed func (sc *schedule) allBlocksProcessed() bool { for _, state := range sc.blockStates { if state != blockStateProcessed { return false } } return true } // highest block | state == blockStateNew func (sc *schedule) maxHeight() int64 { var max int64 = 0 for height, state := range sc.blockStates { if state == blockStateNew && height > max { max = height } } return max } // lowest block | state == blockStateNew func (sc *schedule) minHeight() int64 { var min int64 = math.MaxInt64 for height, state := range sc.blockStates { if state == blockStateNew && height < min { min = height } } return min } func (sc *schedule) pendingFrom(peerID p2p.ID) []int64 { heights := []int64{} for height, pendingPeerID := range sc.pendingBlocks { if pendingPeerID == peerID { heights = append(heights, height) } } return heights } func (sc *schedule) selectPeer(peers []*scPeer) *scPeer { // FIXME: properPeerSelector s := rand.NewSource(time.Now().Unix()) r := rand.New(s) return peers[r.Intn(len(peers))] } // XXX: this duplicates the logic of peersInactiveSince and peersSlowerThan func (sc *schedule) prunablePeers(peerTimout time.Duration, minRecvRate int64, now time.Time) []p2p.ID { prunable := []p2p.ID{} for peerID, peer := range sc.peers { if now.Sub(peer.lastTouched) > peerTimout || peer.lastRate < minRecvRate { prunable = append(prunable, peerID) } } return prunable } func (sc *schedule) numBlockInState(targetState blockState) uint32 { var num uint32 = 0 for _, state := range sc.blockStates { if state == targetState { num++ } } return num }