zolfa
/
tendermint


								package v2


								import (

									"fmt"


									"github.com/tendermint/tendermint/p2p"

									tmState "github.com/tendermint/tendermint/state"

									"github.com/tendermint/tendermint/types"

								)


								// Events generated by the processor:

								// block execution failure, event will indicate the peer(s) that caused the error

								type pcBlockVerificationFailure struct {

									priorityNormal

									height       int64

									firstPeerID  p2p.ID

									secondPeerID p2p.ID

								}


								// successful block execution

								type pcBlockProcessed struct {

									priorityNormal

									height int64

									peerID p2p.ID

								}


								// processor has finished

								type pcFinished struct {

									priorityNormal

									blocksSynced int

									tmState      tmState.State

								}


								func (p pcFinished) Error() string {

									return "finished"

								}


								type queueItem struct {

									block  *types.Block

									peerID p2p.ID

								}


								type blockQueue map[int64]queueItem


								type pcState struct {

									// blocks waiting to be processed

									queue blockQueue


									// draining indicates that the next rProcessBlock event with a queue miss constitutes completion

									draining bool


									// the number of blocks successfully synced by the processor

									blocksSynced int


									// the processorContext which contains the processor dependencies

									context processorContext

								}


								func (state *pcState) String() string {

									return fmt.Sprintf("height: %d queue length: %d draining: %v blocks synced: %d",

										state.height(), len(state.queue), state.draining, state.blocksSynced)

								}


								// newPcState returns a pcState initialized with the last verified block enqueued

								func newPcState(context processorContext) *pcState {

									return &pcState{

										queue:        blockQueue{},

										draining:     false,

										blocksSynced: 0,

										context:      context,

									}

								}


								// nextTwo returns the next two unverified blocks

								func (state *pcState) nextTwo() (queueItem, queueItem, error) {

									if first, ok := state.queue[state.height()+1]; ok {

										if second, ok := state.queue[state.height()+2]; ok {

											return first, second, nil

										}

									}

									return queueItem{}, queueItem{}, fmt.Errorf("not found")

								}


								// synced returns true when at most the last verified block remains in the queue

								func (state *pcState) synced() bool {

									return len(state.queue) <= 1

								}


								func (state *pcState) enqueue(peerID p2p.ID, block *types.Block, height int64) {

									if _, ok := state.queue[height]; ok {

										panic("duplicate block enqueued by processor")

									}

									state.queue[height] = queueItem{block: block, peerID: peerID}

								}


								func (state *pcState) height() int64 {

									return state.context.tmState().LastBlockHeight

								}


								// purgePeer moves all unprocessed blocks from the queue

								func (state *pcState) purgePeer(peerID p2p.ID) {

									// what if height is less than state.height?

									for height, item := range state.queue {

										if item.peerID == peerID {

											delete(state.queue, height)

										}

									}

								}


								// handle processes FSM events

								func (state *pcState) handle(event Event) (Event, error) {

									switch event := event.(type) {

									case bcResetState:

										state.context.setState(event.state)

										return noOp, nil


									case scFinishedEv:

										if state.synced() {

											return pcFinished{tmState: state.context.tmState(), blocksSynced: state.blocksSynced}, nil

										}

										state.draining = true

										return noOp, nil


									case scPeerError:

										state.purgePeer(event.peerID)

										return noOp, nil


									case scBlockReceived:

										if event.block == nil {

											return noOp, nil

										}


										// enqueue block if height is higher than state height, else ignore it

										if event.block.Height > state.height() {

											state.enqueue(event.peerID, event.block, event.block.Height)

										}

										return noOp, nil


									case rProcessBlock:

										tmState := state.context.tmState()

										firstItem, secondItem, err := state.nextTwo()

										if err != nil {

											if state.draining {

												return pcFinished{tmState: tmState, blocksSynced: state.blocksSynced}, nil

											}

											return noOp, nil

										}

										first, second := firstItem.block, secondItem.block


										firstParts := first.MakePartSet(types.BlockPartSizeBytes)

										firstPartSetHeader := firstParts.Header()

										firstID := types.BlockID{Hash: first.Hash(), PartSetHeader: firstPartSetHeader}


										err = state.context.verifyCommit(tmState.ChainID, firstID, first.Height, second.LastCommit)

										if err != nil {

											state.purgePeer(firstItem.peerID)

											state.purgePeer(secondItem.peerID)

											return pcBlockVerificationFailure{

													height: first.Height, firstPeerID: firstItem.peerID, secondPeerID: secondItem.peerID},

												nil

										}


										state.context.saveBlock(first, firstParts, second.LastCommit)


										if err := state.context.applyBlock(firstID, first); err != nil {

											panic(fmt.Sprintf("failed to process committed block (%d:%X): %v", first.Height, first.Hash(), err))

										}


										delete(state.queue, first.Height)

										state.blocksSynced++


										return pcBlockProcessed{height: first.Height, peerID: firstItem.peerID}, nil


									}


									return noOp, nil

								}