+package iotcloud;
+
+import java.util.Iterator;
+import java.util.Random;
+import java.util.Arrays;
+import java.util.Map;
+import java.util.Set;
+import java.util.List;
+import java.util.Vector;
+import java.util.HashMap;
+import java.util.HashSet;
+import java.util.ArrayList;
+import java.util.Collections;
+import java.nio.ByteBuffer;
+import android.content.*;
+
+/**
+ * IoTTable data structure. Provides client interface.
+ * @author Brian Demsky
+ * @version 1.0
+ */
+
+final public class Table {
+
+ /* Constants */
+ static final int FREE_SLOTS = 10; // Number of slots that should be kept free
+ static final int SKIP_THRESHOLD = 10;
+ static final double RESIZE_MULTIPLE = 1.2;
+ static final double RESIZE_THRESHOLD = 0.75;
+ static final int REJECTED_THRESHOLD = 5;
+
+ /* Helper Objects */
+ private SlotBuffer buffer = null;
+ private CloudComm cloud = null;
+ private Random random = null;
+ private TableStatus liveTableStatus = null;
+ private PendingTransaction pendingTransactionBuilder = null; // Pending Transaction used in building a Pending Transaction
+ private Transaction lastPendingTransactionSpeculatedOn = null; // Last transaction that was speculated on from the pending transaction
+ private Transaction firstPendingTransaction = null; // first transaction in the pending transaction list
+
+ /* Variables */
+ private int numberOfSlots = 0; // Number of slots stored in buffer
+ private int bufferResizeThreshold = 0; // Threshold on the number of live slots before a resize is needed
+ private long liveSlotCount = 0; // Number of currently live slots
+ private long oldestLiveSlotSequenceNumver = 0; // Smallest sequence number of the slot with a live entry
+ private long localMachineId = 0; // Machine ID of this client device
+ private long sequenceNumber = 0; // Largest sequence number a client has received
+ // private int smallestTableStatusSeen = -1; // Smallest Table Status that was seen in the latest slots sent from the server
+ // private int largestTableStatusSeen = -1; // Largest Table Status that was seen in the latest slots sent from the server
+ private long localTransactionSequenceNumber = 0; // Local sequence number counter for transactions
+ private long lastTransactionSequenceNumberSpeculatedOn = -1; // the last transaction that was speculated on
+ private long oldestTransactionSequenceNumberSpeculatedOn = -1; // the oldest transaction that was speculated on
+ private long localArbitrationSequenceNumber = 0;
+ private boolean hadPartialSendToServer = false;
+ private boolean attemptedToSendToServer = false;
+ private long expectedsize;
+ private boolean didFindTableStatus = false;
+ private long currMaxSize = 0;
+
+ private Slot lastSlotAttemptedToSend = null;
+ private boolean lastIsNewKey = false;
+ private int lastNewSize = 0;
+ private Map<Transaction, List<Integer>> lastTransactionPartsSent = null;
+ private List<Entry> lastPendingSendArbitrationEntriesToDelete = null;
+ private NewKey lastNewKey = null;
+
+
+ /* Data Structures */
+ private Map<IoTString, KeyValue> committedKeyValueTable = null; // Table of committed key value pairs
+ private Map<IoTString, KeyValue> speculatedKeyValueTable = null; // Table of speculated key value pairs, if there is a speculative value
+ private Map<IoTString, KeyValue> pendingTransactionSpeculatedKeyValueTable = null; // Table of speculated key value pairs, if there is a speculative value from the pending transactions
+ private Map<IoTString, NewKey> liveNewKeyTable = null; // Table of live new keys
+ private HashMap<Long, Pair<Long, Liveness>> lastMessageTable = null; // Last message sent by a client machine id -> (Seq Num, Slot or LastMessage);
+ private HashMap<Long, HashSet<RejectedMessage>> rejectedMessageWatchListTable = null; // Table of machine Ids and the set of rejected messages they have not seen yet
+ private Map<IoTString, Long> arbitratorTable = null; // Table of keys and their arbitrators
+ private Map<Pair<Long, Long>, Abort> liveAbortTable = null; // Table live abort messages
+ private Map<Long, Map<Pair<Long, Integer>, TransactionPart>> newTransactionParts = null; // transaction parts that are seen in this latest round of slots from the server
+ private Map<Long, Map<Pair<Long, Integer>, CommitPart>> newCommitParts = null; // commit parts that are seen in this latest round of slots from the server
+ private Map<Long, Long> lastArbitratedTransactionNumberByArbitratorTable = null; // Last transaction sequence number that an arbitrator arbitrated on
+ private Map<Long, Transaction> liveTransactionBySequenceNumberTable = null; // live transaction grouped by the sequence number
+ private Map<Pair<Long, Long>, Transaction> liveTransactionByTransactionIdTable = null; // live transaction grouped by the transaction ID
+ private Map<Long, Map<Long, Commit>> liveCommitsTable = null;
+ private Map<IoTString, Commit> liveCommitsByKeyTable = null;
+ private Map<Long, Long> lastCommitSeenSequenceNumberByArbitratorTable = null;
+ private Vector<Long> rejectedSlotList = null; // List of rejected slots that have yet to be sent to the server
+ private List<Transaction> pendingTransactionQueue = null;
+ private List<ArbitrationRound> pendingSendArbitrationRounds = null;
+ private List<Entry> pendingSendArbitrationEntriesToDelete = null;
+ private Map<Transaction, List<Integer>> transactionPartsSent = null;
+ private Map<Long, TransactionStatus> outstandingTransactionStatus = null;
+ private Map<Long, Abort> liveAbortsGeneratedByLocal = null;
+ private Set<Pair<Long, Long>> offlineTransactionsCommittedAndAtServer = null;
+ private Map<Long, Pair<String, Integer>> localCommunicationTable = null;
+ private Map<Long, Long> lastTransactionSeenFromMachineFromServer = null;
+ private Map<Long, Long> lastArbitrationDataLocalSequenceNumberSeenFromArbitrator = null;
+
+
+ public Table(String baseurl, String password, long _localMachineId, int listeningPort, Context context) {
+ localMachineId = _localMachineId;
+ cloud = new CloudComm(this, baseurl, password, listeningPort, context);
+
+ init();
+ }
+
+ public Table(CloudComm _cloud, long _localMachineId) {
+ localMachineId = _localMachineId;
+ cloud = _cloud;
+
+ init();
+ }
+
+ /**
+ * Init all the stuff needed for for table usage
+ */
+ private void init() {
+
+ // Init helper objects
+ random = new Random();
+ buffer = new SlotBuffer();
+
+ // Set Variables
+ oldestLiveSlotSequenceNumver = 1;
+
+ // init data structs
+ committedKeyValueTable = new HashMap<IoTString, KeyValue>();
+ speculatedKeyValueTable = new HashMap<IoTString, KeyValue>();
+ pendingTransactionSpeculatedKeyValueTable = new HashMap<IoTString, KeyValue>();
+ liveNewKeyTable = new HashMap<IoTString, NewKey>();
+ lastMessageTable = new HashMap<Long, Pair<Long, Liveness>>();
+ rejectedMessageWatchListTable = new HashMap<Long, HashSet<RejectedMessage>>();
+ arbitratorTable = new HashMap<IoTString, Long>();
+ liveAbortTable = new HashMap<Pair<Long, Long>, Abort>();
+ newTransactionParts = new HashMap<Long, Map<Pair<Long, Integer>, TransactionPart>>();
+ newCommitParts = new HashMap<Long, Map<Pair<Long, Integer>, CommitPart>>();
+ lastArbitratedTransactionNumberByArbitratorTable = new HashMap<Long, Long>();
+ liveTransactionBySequenceNumberTable = new HashMap<Long, Transaction>();
+ liveTransactionByTransactionIdTable = new HashMap<Pair<Long, Long>, Transaction>();
+ liveCommitsTable = new HashMap<Long, Map<Long, Commit>>();
+ liveCommitsByKeyTable = new HashMap<IoTString, Commit>();
+ lastCommitSeenSequenceNumberByArbitratorTable = new HashMap<Long, Long>();
+ rejectedSlotList = new Vector<Long>();
+ pendingTransactionQueue = new ArrayList<Transaction>();
+ pendingSendArbitrationEntriesToDelete = new ArrayList<Entry>();
+ transactionPartsSent = new HashMap<Transaction, List<Integer>>();
+ outstandingTransactionStatus = new HashMap<Long, TransactionStatus>();
+ liveAbortsGeneratedByLocal = new HashMap<Long, Abort>();
+ offlineTransactionsCommittedAndAtServer = new HashSet<Pair<Long, Long>>();
+ localCommunicationTable = new HashMap<Long, Pair<String, Integer>>();
+ lastTransactionSeenFromMachineFromServer = new HashMap<Long, Long>();
+ pendingSendArbitrationRounds = new ArrayList<ArbitrationRound>();
+ lastArbitrationDataLocalSequenceNumberSeenFromArbitrator = new HashMap<Long, Long>();
+
+
+ // Other init stuff
+ numberOfSlots = buffer.capacity();
+ setResizeThreshold();
+ }
+
+ // TODO: delete method
+ public synchronized void printSlots() {
+ long o = buffer.getOldestSeqNum();
+ long n = buffer.getNewestSeqNum();
+
+ int[] types = new int[10];
+
+ int num = 0;
+
+ int livec = 0;
+ int deadc = 0;
+ for (long i = o; i < (n + 1); i++) {
+ Slot s = buffer.getSlot(i);
+
+ Vector<Entry> entries = s.getEntries();
+
+ for (Entry e : entries) {
+ if (e.isLive()) {
+ int type = e.getType();
+ types[type] = types[type] + 1;
+ num++;
+ livec++;
+ } else {
+ deadc++;
+ }
+ }
+ }
+
+ for (int i = 0; i < 10; i++) {
+ System.out.println(i + " " + types[i]);
+ }
+ System.out.println("Live count: " + livec);
+ System.out.println("Dead count: " + deadc);
+ System.out.println("Old: " + o);
+ System.out.println("New: " + n);
+ System.out.println("Size: " + buffer.size());
+ // System.out.println("Commits: " + liveCommitsTable.size());
+ System.out.println("pendingTrans: " + pendingTransactionQueue.size());
+ System.out.println("Trans Status Out: " + outstandingTransactionStatus.size());
+
+ for (Long k : lastArbitratedTransactionNumberByArbitratorTable.keySet()) {
+ System.out.println(k + ": " + lastArbitratedTransactionNumberByArbitratorTable.get(k));
+ }
+
+
+ for (Long a : liveCommitsTable.keySet()) {
+ for (Long b : liveCommitsTable.get(a).keySet()) {
+ for (KeyValue kv : liveCommitsTable.get(a).get(b).getKeyValueUpdateSet()) {
+ System.out.print(kv + " ");
+ }
+ System.out.print("|| ");
+ }
+ System.out.println();
+ }
+
+ }
+
+ /**
+ * Initialize the table by inserting a table status as the first entry into the table status
+ * also initialize the crypto stuff.
+ */
+ public synchronized void initTable() throws ServerException {
+ cloud.initSecurity();
+
+ // Create the first insertion into the block chain which is the table status
+ Slot s = new Slot(this, 1, localMachineId);
+ TableStatus status = new TableStatus(s, numberOfSlots);
+ s.addEntry(status);
+ Slot[] array = cloud.putSlot(s, numberOfSlots);
+
+ if (array == null) {
+ array = new Slot[] {s};
+ // update local block chain
+ validateAndUpdate(array, true);
+ } else if (array.length == 1) {
+ // in case we did push the slot BUT we failed to init it
+ validateAndUpdate(array, true);
+ } else {
+ throw new Error("Error on initialization");
+ }
+ }
+
+ /**
+ * Rebuild the table from scratch by pulling the latest block chain from the server.
+ */
+ public synchronized void rebuild() throws ServerException {
+ // Just pull the latest slots from the server
+ Slot[] newslots = cloud.getSlots(sequenceNumber + 1);
+ validateAndUpdate(newslots, true);
+ }
+
+ // public String toString() {
+ // String retString = " Committed Table: \n";
+ // retString += "---------------------------\n";
+ // retString += commitedTable.toString();
+
+ // retString += "\n\n";
+
+ // retString += " Speculative Table: \n";
+ // retString += "---------------------------\n";
+ // retString += speculativeTable.toString();
+
+ // return retString;
+ // }
+
+ public synchronized void addLocalCommunication(long arbitrator, String hostName, int portNumber) {
+ localCommunicationTable.put(arbitrator, new Pair<String, Integer>(hostName, portNumber));
+ }
+
+ public synchronized Long getArbitrator(IoTString key) {
+ return arbitratorTable.get(key);
+ }
+
+ public synchronized void close() {
+ cloud.close();
+ }
+
+ public synchronized IoTString getCommitted(IoTString key) {
+ KeyValue kv = committedKeyValueTable.get(key);
+
+ if (kv != null) {
+ return kv.getValue();
+ } else {
+ return null;
+ }
+ }
+
+ public synchronized IoTString getSpeculative(IoTString key) {
+ KeyValue kv = pendingTransactionSpeculatedKeyValueTable.get(key);
+
+ if (kv == null) {
+ kv = speculatedKeyValueTable.get(key);
+ }
+
+ if (kv == null) {
+ kv = committedKeyValueTable.get(key);
+ }
+
+ if (kv != null) {
+ return kv.getValue();
+ } else {
+ return null;
+ }
+ }
+
+ public synchronized IoTString getCommittedAtomic(IoTString key) {
+ KeyValue kv = committedKeyValueTable.get(key);
+
+ if (arbitratorTable.get(key) == null) {
+ throw new Error("Key not Found.");
+ }
+
+ // Make sure new key value pair matches the current arbitrator
+ if (!pendingTransactionBuilder.checkArbitrator(arbitratorTable.get(key))) {
+ // TODO: Maybe not throw en error
+ throw new Error("Not all Key Values Match Arbitrator.");
+ }
+
+ if (kv != null) {
+ pendingTransactionBuilder.addKVGuard(new KeyValue(key, kv.getValue()));
+ return kv.getValue();
+ } else {
+ pendingTransactionBuilder.addKVGuard(new KeyValue(key, null));
+ return null;
+ }
+ }
+
+ public synchronized IoTString getSpeculativeAtomic(IoTString key) {
+ if (arbitratorTable.get(key) == null) {
+ throw new Error("Key not Found.");
+ }
+
+ // Make sure new key value pair matches the current arbitrator
+ if (!pendingTransactionBuilder.checkArbitrator(arbitratorTable.get(key))) {
+ // TODO: Maybe not throw en error
+ throw new Error("Not all Key Values Match Arbitrator.");
+ }
+
+ KeyValue kv = pendingTransactionSpeculatedKeyValueTable.get(key);
+
+ if (kv == null) {
+ kv = speculatedKeyValueTable.get(key);
+ }
+
+ if (kv == null) {
+ kv = committedKeyValueTable.get(key);
+ }
+
+ if (kv != null) {
+ pendingTransactionBuilder.addKVGuard(new KeyValue(key, kv.getValue()));
+ return kv.getValue();
+ } else {
+ pendingTransactionBuilder.addKVGuard(new KeyValue(key, null));
+ return null;
+ }
+ }
+
+ public synchronized boolean update() {
+ try {
+ Slot[] newSlots = cloud.getSlots(sequenceNumber + 1);
+ validateAndUpdate(newSlots, false);
+ sendToServer(null);
+
+
+ updateLiveTransactionsAndStatus();
+
+ return true;
+ } catch (Exception e) {
+ // e.printStackTrace();
+
+ for (Long m : localCommunicationTable.keySet()) {
+ updateFromLocal(m);
+ }
+ }
+
+ return false;
+ }
+
+ public synchronized boolean createNewKey(IoTString keyName, long machineId) throws ServerException {
+ while (true) {
+ if (arbitratorTable.get(keyName) != null) {
+ // There is already an arbitrator
+ return false;
+ }
+
+ NewKey newKey = new NewKey(null, keyName, machineId);
+ if (sendToServer(newKey)) {
+ // If successfully inserted
+ return true;
+ }
+ }
+ }
+
+ public synchronized void startTransaction() {
+ // Create a new transaction, invalidates any old pending transactions.
+ pendingTransactionBuilder = new PendingTransaction(localMachineId);
+ }
+
+ public synchronized void addKV(IoTString key, IoTString value) {
+
+ // Make sure it is a valid key
+ if (arbitratorTable.get(key) == null) {
+ throw new Error("Key not Found.");
+ }
+
+ // Make sure new key value pair matches the current arbitrator
+ if (!pendingTransactionBuilder.checkArbitrator(arbitratorTable.get(key))) {
+ // TODO: Maybe not throw en error
+ throw new Error("Not all Key Values Match Arbitrator.");
+ }
+
+ // Add the key value to this transaction
+ KeyValue kv = new KeyValue(key, value);
+ pendingTransactionBuilder.addKV(kv);
+ }
+
+ public synchronized TransactionStatus commitTransaction() {
+
+ if (pendingTransactionBuilder.getKVUpdates().size() == 0) {
+ // transaction with no updates will have no effect on the system
+ return new TransactionStatus(TransactionStatus.StatusNoEffect, -1);
+ }
+
+ // Set the local transaction sequence number and increment
+ pendingTransactionBuilder.setClientLocalSequenceNumber(localTransactionSequenceNumber);
+ localTransactionSequenceNumber++;
+
+ // Create the transaction status
+ TransactionStatus transactionStatus = new TransactionStatus(TransactionStatus.StatusPending, pendingTransactionBuilder.getArbitrator());
+
+ // Create the new transaction
+ Transaction newTransaction = pendingTransactionBuilder.createTransaction();
+ newTransaction.setTransactionStatus(transactionStatus);
+
+ if (pendingTransactionBuilder.getArbitrator() != localMachineId) {
+ // Add it to the queue and invalidate the builder for safety
+ pendingTransactionQueue.add(newTransaction);
+ } else {
+ arbitrateOnLocalTransaction(newTransaction);
+ updateLiveStateFromLocal();
+ }
+
+ pendingTransactionBuilder = new PendingTransaction(localMachineId);
+
+ try {
+ sendToServer(null);
+ } catch (ServerException e) {
+
+ Set<Long> arbitratorTriedAndFailed = new HashSet<Long>();
+ for (Iterator<Transaction> iter = pendingTransactionQueue.iterator(); iter.hasNext(); ) {
+ Transaction transaction = iter.next();
+
+ if (arbitratorTriedAndFailed.contains(transaction.getArbitrator())) {
+ // Already contacted this client so ignore all attempts to contact this client
+ // to preserve ordering for arbitrator
+ continue;
+ }
+
+ Pair<Boolean, Boolean> sendReturn = sendTransactionToLocal(transaction);
+
+ if (sendReturn.getFirst()) {
+ // Failed to contact over local
+ arbitratorTriedAndFailed.add(transaction.getArbitrator());
+ } else {
+ // Successful contact or should not contact
+
+ if (sendReturn.getSecond()) {
+ // did arbitrate
+ iter.remove();
+ }
+ }
+ }
+ }
+
+ updateLiveStateFromLocal();
+
+ return transactionStatus;
+ }
+
+ /**
+ * Get the machine ID for this client
+ */
+ public long getMachineId() {
+ return localMachineId;
+ }
+
+ /**
+ * Decrement the number of live slots that we currently have
+ */
+ public void decrementLiveCount() {
+ liveSlotCount--;
+ }
+
+ /**
+ * Recalculate the new resize threshold
+ */
+ private void setResizeThreshold() {
+ int resizeLower = (int) (RESIZE_THRESHOLD * numberOfSlots);
+ bufferResizeThreshold = resizeLower - 1 + random.nextInt(numberOfSlots - resizeLower);
+ }
+
+
+ boolean lastInsertedNewKey = false;
+
+ private boolean sendToServer(NewKey newKey) throws ServerException {
+
+ boolean fromRetry = false;
+
+ try {
+ if (hadPartialSendToServer) {
+ Slot[] newSlots = cloud.getSlots(sequenceNumber + 1);
+ if (newSlots.length == 0) {
+ fromRetry = true;
+ ThreeTuple<Boolean, Boolean, Slot[]> sendSlotsReturn = sendSlotsToServer(lastSlotAttemptedToSend, lastNewSize, lastIsNewKey);
+
+ if (sendSlotsReturn.getFirst()) {
+ if (newKey != null) {
+ if (lastInsertedNewKey && (lastNewKey.getKey() == newKey.getKey()) && (lastNewKey.getMachineID() == newKey.getMachineID())) {
+ newKey = null;
+ }
+ }
+
+ for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ transaction.resetServerFailure();
+
+ // Update which transactions parts still need to be sent
+ transaction.removeSentParts(lastTransactionPartsSent.get(transaction));
+
+ // Add the transaction status to the outstanding list
+ outstandingTransactionStatus.put(transaction.getSequenceNumber(), transaction.getTransactionStatus());
+
+ // Update the transaction status
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentPartial);
+
+ // Check if all the transaction parts were successfully sent and if so then remove it from pending
+ if (transaction.didSendAllParts()) {
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentFully);
+ pendingTransactionQueue.remove(transaction);
+ }
+ }
+ } else {
+
+ newSlots = sendSlotsReturn.getThird();
+
+ boolean isInserted = false;
+ for (Slot s : newSlots) {
+ if ((s.getSequenceNumber() == lastSlotAttemptedToSend.getSequenceNumber()) && (s.getMachineID() == localMachineId)) {
+ isInserted = true;
+ break;
+ }
+ }
+
+ for (Slot s : newSlots) {
+ if (isInserted) {
+ break;
+ }
+
+ // Process each entry in the slot
+ for (Entry entry : s.getEntries()) {
+
+ if (entry.getType() == Entry.TypeLastMessage) {
+ LastMessage lastMessage = (LastMessage)entry;
+ if ((lastMessage.getMachineID() == localMachineId) && (lastMessage.getSequenceNumber() == lastSlotAttemptedToSend.getSequenceNumber())) {
+ isInserted = true;
+ break;
+ }
+ }
+ }
+ }
+
+ if (isInserted) {
+ if (newKey != null) {
+ if (lastInsertedNewKey && (lastNewKey.getKey() == newKey.getKey()) && (lastNewKey.getMachineID() == newKey.getMachineID())) {
+ newKey = null;
+ }
+ }
+
+ for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ transaction.resetServerFailure();
+
+ // Update which transactions parts still need to be sent
+ transaction.removeSentParts(lastTransactionPartsSent.get(transaction));
+
+ // Add the transaction status to the outstanding list
+ outstandingTransactionStatus.put(transaction.getSequenceNumber(), transaction.getTransactionStatus());
+
+ // Update the transaction status
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentPartial);
+
+ // Check if all the transaction parts were successfully sent and if so then remove it from pending
+ if (transaction.didSendAllParts()) {
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentFully);
+ pendingTransactionQueue.remove(transaction);
+ } else {
+ transaction.resetServerFailure();
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+ }
+ }
+ }
+
+ for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ transaction.resetServerFailure();
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+
+ if (sendSlotsReturn.getThird().length != 0) {
+ // insert into the local block chain
+ validateAndUpdate(sendSlotsReturn.getThird(), true);
+ }
+ // continue;
+ } else {
+ boolean isInserted = false;
+ for (Slot s : newSlots) {
+ if ((s.getSequenceNumber() == lastSlotAttemptedToSend.getSequenceNumber()) && (s.getMachineID() == localMachineId)) {
+ isInserted = true;
+ break;
+ }
+ }
+
+ for (Slot s : newSlots) {
+ if (isInserted) {
+ break;
+ }
+
+ // Process each entry in the slot
+ for (Entry entry : s.getEntries()) {
+
+ if (entry.getType() == Entry.TypeLastMessage) {
+ LastMessage lastMessage = (LastMessage)entry;
+ if ((lastMessage.getMachineID() == localMachineId) && (lastMessage.getSequenceNumber() == lastSlotAttemptedToSend.getSequenceNumber())) {
+ isInserted = true;
+ break;
+ }
+ }
+ }
+ }
+
+ if (isInserted) {
+ if (newKey != null) {
+ if (lastInsertedNewKey && (lastNewKey.getKey() == newKey.getKey()) && (lastNewKey.getMachineID() == newKey.getMachineID())) {
+ newKey = null;
+ }
+ }
+
+ for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ transaction.resetServerFailure();
+
+ // Update which transactions parts still need to be sent
+ transaction.removeSentParts(lastTransactionPartsSent.get(transaction));
+
+ // Add the transaction status to the outstanding list
+ outstandingTransactionStatus.put(transaction.getSequenceNumber(), transaction.getTransactionStatus());
+
+ // Update the transaction status
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentPartial);
+
+ // Check if all the transaction parts were successfully sent and if so then remove it from pending
+ if (transaction.didSendAllParts()) {
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentFully);
+ pendingTransactionQueue.remove(transaction);
+ } else {
+ transaction.resetServerFailure();
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+ }
+ } else {
+ for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ transaction.resetServerFailure();
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+ }
+
+ // insert into the local block chain
+ validateAndUpdate(newSlots, true);
+ }
+ }
+ } catch (ServerException e) {
+ throw e;
+ }
+
+
+ try {
+ // While we have stuff that needs inserting into the block chain
+ while ((pendingTransactionQueue.size() > 0) || (pendingSendArbitrationRounds.size() > 0) || (newKey != null)) {
+ fromRetry = false;
+
+ if (hadPartialSendToServer) {
+ throw new Error("Should Be error free");
+ }
+
+
+
+ // If there is a new key with same name then end
+ if ((newKey != null) && (arbitratorTable.get(newKey.getKey()) != null)) {
+ return false;
+ }
+
+ // Create the slot
+ Slot slot = new Slot(this, sequenceNumber + 1, localMachineId, buffer.getSlot(sequenceNumber).getHMAC());
+
+ // Try to fill the slot with data
+ ThreeTuple<Boolean, Integer, Boolean> fillSlotsReturn = fillSlot(slot, false, newKey);
+ boolean needsResize = fillSlotsReturn.getFirst();
+ int newSize = fillSlotsReturn.getSecond();
+ Boolean insertedNewKey = fillSlotsReturn.getThird();
+
+ if (needsResize) {
+ // Reset which transaction to send
+ for (Transaction transaction : transactionPartsSent.keySet()) {
+ transaction.resetNextPartToSend();
+
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer() && !transaction.getServerFailure()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+
+ // Clear the sent data since we are trying again
+ pendingSendArbitrationEntriesToDelete.clear();
+ transactionPartsSent.clear();
+
+ // We needed a resize so try again
+ fillSlot(slot, true, newKey);
+ }
+
+ lastSlotAttemptedToSend = slot;
+ lastIsNewKey = (newKey != null);
+ lastInsertedNewKey = insertedNewKey;
+ lastNewSize = newSize;
+ lastNewKey = newKey;
+ lastTransactionPartsSent = new HashMap<Transaction, List<Integer>>(transactionPartsSent);
+ lastPendingSendArbitrationEntriesToDelete = new ArrayList<Entry>(pendingSendArbitrationEntriesToDelete);
+
+
+ ThreeTuple<Boolean, Boolean, Slot[]> sendSlotsReturn = sendSlotsToServer(slot, newSize, newKey != null);
+
+ if (sendSlotsReturn.getFirst()) {
+
+ // Did insert into the block chain
+
+ if (insertedNewKey) {
+ // This slot was what was inserted not a previous slot
+
+ // New Key was successfully inserted into the block chain so dont want to insert it again
+ newKey = null;
+ }
+
+ // Remove the aborts and commit parts that were sent from the pending to send queue
+ for (Iterator<ArbitrationRound> iter = pendingSendArbitrationRounds.iterator(); iter.hasNext(); ) {
+ ArbitrationRound round = iter.next();
+ round.removeParts(pendingSendArbitrationEntriesToDelete);
+
+ if (round.isDoneSending()) {
+ // Sent all the parts
+ iter.remove();
+ }
+ }
+
+ for (Transaction transaction : transactionPartsSent.keySet()) {
+ transaction.resetServerFailure();
+
+ // Update which transactions parts still need to be sent
+ transaction.removeSentParts(transactionPartsSent.get(transaction));
+
+ // Add the transaction status to the outstanding list
+ outstandingTransactionStatus.put(transaction.getSequenceNumber(), transaction.getTransactionStatus());
+
+ // Update the transaction status
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentPartial);
+
+ // Check if all the transaction parts were successfully sent and if so then remove it from pending
+ if (transaction.didSendAllParts()) {
+ transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentFully);
+ pendingTransactionQueue.remove(transaction);
+ }
+ }
+ } else {
+
+ // if (!sendSlotsReturn.getSecond()) {
+ // for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ // transaction.resetServerFailure();
+ // }
+ // } else {
+ // for (Transaction transaction : lastTransactionPartsSent.keySet()) {
+ // transaction.resetServerFailure();
+
+ // // Update which transactions parts still need to be sent
+ // transaction.removeSentParts(transactionPartsSent.get(transaction));
+
+ // // Add the transaction status to the outstanding list
+ // outstandingTransactionStatus.put(transaction.getSequenceNumber(), transaction.getTransactionStatus());
+
+ // // Update the transaction status
+ // transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentPartial);
+
+ // // Check if all the transaction parts were successfully sent and if so then remove it from pending
+ // if (transaction.didSendAllParts()) {
+ // transaction.getTransactionStatus().setStatus(TransactionStatus.StatusSentFully);
+ // pendingTransactionQueue.remove(transaction);
+
+ // for (KeyValue kv : transaction.getKeyValueUpdateSet()) {
+ // System.out.println("Sent: " + kv + " from: " + localMachineId + " Slot:" + lastSlotAttemptedToSend.getSequenceNumber() + " Claimed:" + transaction.getSequenceNumber());
+ // }
+ // }
+ // }
+ // }
+
+ // Reset which transaction to send
+ for (Transaction transaction : transactionPartsSent.keySet()) {
+ transaction.resetNextPartToSend();
+ // transaction.resetNextPartToSend();
+
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer() && !transaction.getServerFailure()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+ }
+
+ // Clear the sent data in preparation for next send
+ pendingSendArbitrationEntriesToDelete.clear();
+ transactionPartsSent.clear();
+
+ if (sendSlotsReturn.getThird().length != 0) {
+ // insert into the local block chain
+ validateAndUpdate(sendSlotsReturn.getThird(), true);
+ }
+ }
+
+ } catch (ServerException e) {
+
+ if (e.getType() != ServerException.TypeInputTimeout) {
+ // e.printStackTrace();
+
+ // Nothing was able to be sent to the server so just clear these data structures
+ for (Transaction transaction : transactionPartsSent.keySet()) {
+ transaction.resetNextPartToSend();
+
+ // Set the transaction sequence number back to nothing
+ if (!transaction.didSendAPartToServer() && !transaction.getServerFailure()) {
+ transaction.setSequenceNumber(-1);
+ }
+ }
+ } else {
+ // There was a partial send to the server
+ hadPartialSendToServer = true;
+
+
+ // if (!fromRetry) {
+ // lastTransactionPartsSent = new HashMap<Transaction, List<Integer>>(transactionPartsSent);
+ // lastPendingSendArbitrationEntriesToDelete = new ArrayList<Entry>(pendingSendArbitrationEntriesToDelete);
+ // }
+
+ // Nothing was able to be sent to the server so just clear these data structures
+ for (Transaction transaction : transactionPartsSent.keySet()) {
+ transaction.resetNextPartToSend();
+ transaction.setServerFailure();
+ }
+ }
+
+ pendingSendArbitrationEntriesToDelete.clear();
+ transactionPartsSent.clear();
+
+ throw e;
+ }
+
+ return newKey == null;
+ }
+
+ private synchronized boolean updateFromLocal(long machineId) {
+ Pair<String, Integer> localCommunicationInformation = localCommunicationTable.get(machineId);
+ if (localCommunicationInformation == null) {
+ // Cant talk to that device locally so do nothing
+ return false;
+ }
+
+ // Get the size of the send data
+ //int sendDataSize = Integer.BYTES + Long.BYTES;
+ int sendDataSize = (Integer.SIZE + Long.SIZE)/8;
+
+ Long lastArbitrationDataLocalSequenceNumber = (long) - 1;
+ if (lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(machineId) != null) {
+ lastArbitrationDataLocalSequenceNumber = lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(machineId);
+ }
+
+ byte[] sendData = new byte[sendDataSize];
+ ByteBuffer bbEncode = ByteBuffer.wrap(sendData);
+
+ // Encode the data
+ bbEncode.putLong(lastArbitrationDataLocalSequenceNumber);
+ bbEncode.putInt(0);
+
+ // Send by local
+ byte[] returnData = cloud.sendLocalData(sendData, localCommunicationInformation.getFirst(), localCommunicationInformation.getSecond());
+
+ if (returnData == null) {
+ // Could not contact server
+ return false;
+ }
+
+ // Decode the data
+ ByteBuffer bbDecode = ByteBuffer.wrap(returnData);
+ int numberOfEntries = bbDecode.getInt();
+
+ for (int i = 0; i < numberOfEntries; i++) {
+ byte type = bbDecode.get();
+ if (type == Entry.TypeAbort) {
+ Abort abort = (Abort)Abort.decode(null, bbDecode);
+ processEntry(abort);
+ } else if (type == Entry.TypeCommitPart) {
+ CommitPart commitPart = (CommitPart)CommitPart.decode(null, bbDecode);
+ processEntry(commitPart);
+ }
+ }
+
+ updateLiveStateFromLocal();
+
+ return true;
+ }
+
+ private Pair<Boolean, Boolean> sendTransactionToLocal(Transaction transaction) {
+
+ // Get the devices local communications
+ Pair<String, Integer> localCommunicationInformation = localCommunicationTable.get(transaction.getArbitrator());
+
+ if (localCommunicationInformation == null) {
+ // Cant talk to that device locally so do nothing
+ return new Pair<Boolean, Boolean>(true, false);
+ }
+
+ // Get the size of the send data
+ //int sendDataSize = Integer.BYTES + Long.BYTES;
+ int sendDataSize = (Integer.SIZE + Long.SIZE)/8;
+ for (TransactionPart part : transaction.getParts().values()) {
+ sendDataSize += part.getSize();
+ }
+
+ Long lastArbitrationDataLocalSequenceNumber = (long) - 1;
+ if (lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(transaction.getArbitrator()) != null) {
+ lastArbitrationDataLocalSequenceNumber = lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(transaction.getArbitrator());
+ }
+
+ // Make the send data size
+ byte[] sendData = new byte[sendDataSize];
+ ByteBuffer bbEncode = ByteBuffer.wrap(sendData);
+
+ // Encode the data
+ bbEncode.putLong(lastArbitrationDataLocalSequenceNumber);
+ bbEncode.putInt(transaction.getParts().size());
+ for (TransactionPart part : transaction.getParts().values()) {
+ part.encode(bbEncode);
+ }
+
+
+ // Send by local
+ byte[] returnData = cloud.sendLocalData(sendData, localCommunicationInformation.getFirst(), localCommunicationInformation.getSecond());
+
+ if (returnData == null) {
+ // Could not contact server
+ return new Pair<Boolean, Boolean>(true, false);
+ }
+
+ // Decode the data
+ ByteBuffer bbDecode = ByteBuffer.wrap(returnData);
+ boolean didCommit = bbDecode.get() == 1;
+ boolean couldArbitrate = bbDecode.get() == 1;
+ int numberOfEntries = bbDecode.getInt();
+ boolean foundAbort = false;
+
+ for (int i = 0; i < numberOfEntries; i++) {
+ byte type = bbDecode.get();
+ if (type == Entry.TypeAbort) {
+ Abort abort = (Abort)Abort.decode(null, bbDecode);
+
+ if ((abort.getTransactionMachineId() == localMachineId) && (abort.getTransactionClientLocalSequenceNumber() == transaction.getClientLocalSequenceNumber())) {
+ foundAbort = true;
+ }
+
+ processEntry(abort);
+ } else if (type == Entry.TypeCommitPart) {
+ CommitPart commitPart = (CommitPart)CommitPart.decode(null, bbDecode);
+ processEntry(commitPart);
+ }
+ }
+
+ updateLiveStateFromLocal();
+
+ if (couldArbitrate) {
+ TransactionStatus status = transaction.getTransactionStatus();
+ if (didCommit) {
+ status.setStatus(TransactionStatus.StatusCommitted);
+ } else {
+ status.setStatus(TransactionStatus.StatusAborted);
+ }
+ } else {
+ TransactionStatus status = transaction.getTransactionStatus();
+ if (foundAbort) {
+ status.setStatus(TransactionStatus.StatusAborted);
+ } else {
+ status.setStatus(TransactionStatus.StatusCommitted);
+ }
+ }
+
+ return new Pair<Boolean, Boolean>(false, true);
+ }
+
+ public synchronized byte[] acceptDataFromLocal(byte[] data) {
+
+ // Decode the data
+ ByteBuffer bbDecode = ByteBuffer.wrap(data);
+ long lastArbitratedSequenceNumberSeen = bbDecode.getLong();
+ int numberOfParts = bbDecode.getInt();
+
+ // If we did commit a transaction or not
+ boolean didCommit = false;
+ boolean couldArbitrate = false;
+
+ if (numberOfParts != 0) {
+
+ // decode the transaction
+ Transaction transaction = new Transaction();
+ for (int i = 0; i < numberOfParts; i++) {
+ bbDecode.get();
+ TransactionPart newPart = (TransactionPart)TransactionPart.decode(null, bbDecode);
+ transaction.addPartDecode(newPart);
+ }
+
+ // Arbitrate on transaction and pull relevant return data
+ Pair<Boolean, Boolean> localArbitrateReturn = arbitrateOnLocalTransaction(transaction);
+ couldArbitrate = localArbitrateReturn.getFirst();
+ didCommit = localArbitrateReturn.getSecond();
+
+ updateLiveStateFromLocal();
+
+ // Transaction was sent to the server so keep track of it to prevent double commit
+ if (transaction.getSequenceNumber() != -1) {
+ offlineTransactionsCommittedAndAtServer.add(transaction.getId());
+ }
+ }
+
+ // The data to send back
+ int returnDataSize = 0;
+ List<Entry> unseenArbitrations = new ArrayList<Entry>();
+
+ // Get the aborts to send back
+ List<Long> abortLocalSequenceNumbers = new ArrayList<Long >(liveAbortsGeneratedByLocal.keySet());
+ Collections.sort(abortLocalSequenceNumbers);
+ for (Long localSequenceNumber : abortLocalSequenceNumbers) {
+ if (localSequenceNumber <= lastArbitratedSequenceNumberSeen) {
+ continue;
+ }
+
+ Abort abort = liveAbortsGeneratedByLocal.get(localSequenceNumber);
+ unseenArbitrations.add(abort);
+ returnDataSize += abort.getSize();
+ }
+
+ // Get the commits to send back
+ Map<Long, Commit> commitForClientTable = liveCommitsTable.get(localMachineId);
+ if (commitForClientTable != null) {
+ List<Long> commitLocalSequenceNumbers = new ArrayList<Long>(commitForClientTable.keySet());
+ Collections.sort(commitLocalSequenceNumbers);
+
+ for (Long localSequenceNumber : commitLocalSequenceNumbers) {
+ Commit commit = commitForClientTable.get(localSequenceNumber);
+
+ if (localSequenceNumber <= lastArbitratedSequenceNumberSeen) {
+ continue;
+ }
+
+ unseenArbitrations.addAll(commit.getParts().values());
+
+ for (CommitPart commitPart : commit.getParts().values()) {
+ returnDataSize += commitPart.getSize();
+ }
+ }
+ }
+
+ // Number of arbitration entries to decode
+ //returnDataSize += 2 * Integer.BYTES;
+ returnDataSize += 2 * Integer.SIZE/8;
+
+ // Boolean of did commit or not
+ if (numberOfParts != 0) {
+ //returnDataSize += Byte.BYTES;
+ returnDataSize += Byte.SIZE/8;
+ }
+
+ // Data to send Back
+ byte[] returnData = new byte[returnDataSize];
+ ByteBuffer bbEncode = ByteBuffer.wrap(returnData);
+
+ if (numberOfParts != 0) {
+ if (didCommit) {
+ bbEncode.put((byte)1);
+ } else {
+ bbEncode.put((byte)0);
+ }
+ if (couldArbitrate) {
+ bbEncode.put((byte)1);
+ } else {
+ bbEncode.put((byte)0);
+ }
+ }
+
+ bbEncode.putInt(unseenArbitrations.size());
+ for (Entry entry : unseenArbitrations) {
+ entry.encode(bbEncode);
+ }
+
+ return returnData;
+ }
+
+ private ThreeTuple<Boolean, Boolean, Slot[]> sendSlotsToServer(Slot slot, int newSize, boolean isNewKey) throws ServerException {
+
+ boolean attemptedToSendToServerTmp = attemptedToSendToServer;
+ attemptedToSendToServer = true;
+
+ boolean inserted = false;
+ boolean lastTryInserted = false;
+
+ Slot[] array = cloud.putSlot(slot, newSize);
+ if (array == null) {
+ array = new Slot[] {slot};
+ rejectedSlotList.clear();
+ inserted = true;
+ } else {
+ if (array.length == 0) {
+ throw new Error("Server Error: Did not send any slots");
+ }
+
+ // if (attemptedToSendToServerTmp) {
+ if (hadPartialSendToServer) {
+
+ boolean isInserted = false;
+ for (Slot s : array) {
+ if ((s.getSequenceNumber() == slot.getSequenceNumber()) && (s.getMachineID() == localMachineId)) {
+ isInserted = true;
+ break;
+ }
+ }
+
+ for (Slot s : array) {
+ if (isInserted) {
+ break;
+ }
+
+ // Process each entry in the slot
+ for (Entry entry : s.getEntries()) {
+
+ if (entry.getType() == Entry.TypeLastMessage) {
+ LastMessage lastMessage = (LastMessage)entry;
+
+ if ((lastMessage.getMachineID() == localMachineId) && (lastMessage.getSequenceNumber() == slot.getSequenceNumber())) {
+ isInserted = true;
+ break;
+ }
+ }
+ }
+ }
+
+ if (!isInserted) {
+ rejectedSlotList.add(slot.getSequenceNumber());
+ lastTryInserted = false;
+ } else {
+ lastTryInserted = true;
+ }
+ } else {
+ rejectedSlotList.add(slot.getSequenceNumber());
+ lastTryInserted = false;
+ }
+ }
+
+ return new ThreeTuple<Boolean, Boolean, Slot[]>(inserted, lastTryInserted, array);
+ }
+
+ /**
+ * Returns false if a resize was needed
+ */
+ private ThreeTuple<Boolean, Integer, Boolean> fillSlot(Slot slot, boolean resize, NewKey newKeyEntry) {
+ int newSize = 0;
+ if (liveSlotCount > bufferResizeThreshold) {
+ resize = true; //Resize is forced
+ }
+
+ if (resize) {
+ newSize = (int) (numberOfSlots * RESIZE_MULTIPLE);
+ TableStatus status = new TableStatus(slot, newSize);
+ slot.addEntry(status);
+ }
+
+ // Fill with rejected slots first before doing anything else
+ doRejectedMessages(slot);
+
+ // Do mandatory rescue of entries
+ ThreeTuple<Boolean, Boolean, Long> mandatoryRescueReturn = doMandatoryResuce(slot, resize);
+
+ // Extract working variables
+ boolean needsResize = mandatoryRescueReturn.getFirst();
+ boolean seenLiveSlot = mandatoryRescueReturn.getSecond();
+ long currentRescueSequenceNumber = mandatoryRescueReturn.getThird();
+
+ if (needsResize && !resize) {
+ // We need to resize but we are not resizing so return false
+ return new ThreeTuple<Boolean, Integer, Boolean>(true, null, null);
+ }
+
+ boolean inserted = false;
+ if (newKeyEntry != null) {
+ newKeyEntry.setSlot(slot);
+ if (slot.hasSpace(newKeyEntry)) {
+ slot.addEntry(newKeyEntry);
+ inserted = true;
+ }
+ }
+
+ // Clear the transactions, aborts and commits that were sent previously
+ transactionPartsSent.clear();
+ pendingSendArbitrationEntriesToDelete.clear();
+
+ for (ArbitrationRound round : pendingSendArbitrationRounds) {
+ boolean isFull = false;
+ round.generateParts();
+ List<Entry> parts = round.getParts();
+
+ // Insert pending arbitration data
+ for (Entry arbitrationData : parts) {
+
+ // If it is an abort then we need to set some information
+ if (arbitrationData instanceof Abort) {
+ ((Abort)arbitrationData).setSequenceNumber(slot.getSequenceNumber());
+ }
+
+ if (!slot.hasSpace(arbitrationData)) {
+ // No space so cant do anything else with these data entries
+ isFull = true;
+ break;
+ }
+
+ // Add to this current slot and add it to entries to delete
+ slot.addEntry(arbitrationData);
+ pendingSendArbitrationEntriesToDelete.add(arbitrationData);
+ }
+
+ if (isFull) {
+ break;
+ }
+ }
+
+ if (pendingTransactionQueue.size() > 0) {
+
+ Transaction transaction = pendingTransactionQueue.get(0);
+
+ // Set the transaction sequence number if it has yet to be inserted into the block chain
+ // if ((!transaction.didSendAPartToServer() && !transaction.getServerFailure()) || (transaction.getSequenceNumber() == -1)) {
+ // transaction.setSequenceNumber(slot.getSequenceNumber());
+ // }
+
+ if ((!transaction.didSendAPartToServer()) || (transaction.getSequenceNumber() == -1)) {
+ transaction.setSequenceNumber(slot.getSequenceNumber());
+ }
+
+
+ while (true) {
+ TransactionPart part = transaction.getNextPartToSend();
+
+ if (part == null) {
+ // Ran out of parts to send for this transaction so move on
+ break;
+ }
+
+ if (slot.hasSpace(part)) {
+ slot.addEntry(part);
+ List<Integer> partsSent = transactionPartsSent.get(transaction);
+ if (partsSent == null) {
+ partsSent = new ArrayList<Integer>();
+ transactionPartsSent.put(transaction, partsSent);
+ }
+ partsSent.add(part.getPartNumber());
+ transactionPartsSent.put(transaction, partsSent);
+ } else {
+ break;
+ }
+ }
+ }
+
+ // Fill the remainder of the slot with rescue data
+ doOptionalRescue(slot, seenLiveSlot, currentRescueSequenceNumber, resize);
+
+ return new ThreeTuple<Boolean, Integer, Boolean>(false, newSize, inserted);
+ }
+
+ private void doRejectedMessages(Slot s) {
+ if (! rejectedSlotList.isEmpty()) {
+ /* TODO: We should avoid generating a rejected message entry if
+ * there is already a sufficient entry in the queue (e.g.,
+ * equalsto value of true and same sequence number). */
+
+ long old_seqn = rejectedSlotList.firstElement();
+ if (rejectedSlotList.size() > REJECTED_THRESHOLD) {
+ long new_seqn = rejectedSlotList.lastElement();
+ RejectedMessage rm = new RejectedMessage(s, s.getSequenceNumber(), localMachineId, old_seqn, new_seqn, false);
+ s.addEntry(rm);
+ } else {
+ long prev_seqn = -1;
+ int i = 0;
+ /* Go through list of missing messages */
+ for (; i < rejectedSlotList.size(); i++) {
+ long curr_seqn = rejectedSlotList.get(i);
+ Slot s_msg = buffer.getSlot(curr_seqn);
+ if (s_msg != null)
+ break;
+ prev_seqn = curr_seqn;
+ }
+ /* Generate rejected message entry for missing messages */
+ if (prev_seqn != -1) {
+ RejectedMessage rm = new RejectedMessage(s, s.getSequenceNumber(), localMachineId, old_seqn, prev_seqn, false);
+ s.addEntry(rm);
+ }
+ /* Generate rejected message entries for present messages */
+ for (; i < rejectedSlotList.size(); i++) {
+ long curr_seqn = rejectedSlotList.get(i);
+ Slot s_msg = buffer.getSlot(curr_seqn);
+ long machineid = s_msg.getMachineID();
+ RejectedMessage rm = new RejectedMessage(s, s.getSequenceNumber(), machineid, curr_seqn, curr_seqn, true);
+ s.addEntry(rm);
+ }
+ }
+ }
+ }
+
+ private ThreeTuple<Boolean, Boolean, Long> doMandatoryResuce(Slot slot, boolean resize) {
+ long newestSequenceNumber = buffer.getNewestSeqNum();
+ long oldestSequenceNumber = buffer.getOldestSeqNum();
+ if (oldestLiveSlotSequenceNumver < oldestSequenceNumber) {
+ oldestLiveSlotSequenceNumver = oldestSequenceNumber;
+ }
+
+ long currentSequenceNumber = oldestLiveSlotSequenceNumver;
+ boolean seenLiveSlot = false;
+ long firstIfFull = newestSequenceNumber + 1 - numberOfSlots; // smallest seq number in the buffer if it is full
+ long threshold = firstIfFull + FREE_SLOTS; // we want the buffer to be clear of live entries up to this point
+
+
+ // Mandatory Rescue
+ for (; currentSequenceNumber < threshold; currentSequenceNumber++) {
+ Slot previousSlot = buffer.getSlot(currentSequenceNumber);
+ // Push slot number forward
+ if (! seenLiveSlot) {
+ oldestLiveSlotSequenceNumver = currentSequenceNumber;
+ }
+
+ if (!previousSlot.isLive()) {
+ continue;
+ }
+
+ // We have seen a live slot
+ seenLiveSlot = true;
+
+ // Get all the live entries for a slot
+ Vector<Entry> liveEntries = previousSlot.getLiveEntries(resize);
+
+ // Iterate over all the live entries and try to rescue them
+ for (Entry liveEntry : liveEntries) {
+ if (slot.hasSpace(liveEntry)) {
+
+ // Enough space to rescue the entry
+ slot.addEntry(liveEntry);
+ } else if (currentSequenceNumber == firstIfFull) {
+ //if there's no space but the entry is about to fall off the queue
+ System.out.println("B"); //?
+ return new ThreeTuple<Boolean, Boolean, Long>(true, seenLiveSlot, currentSequenceNumber);
+
+ }
+ }
+ }
+
+ // Did not resize
+ return new ThreeTuple<Boolean, Boolean, Long>(false, seenLiveSlot, currentSequenceNumber);
+ }
+
+ private void doOptionalRescue(Slot s, boolean seenliveslot, long seqn, boolean resize) {
+ /* now go through live entries from least to greatest sequence number until
+ * either all live slots added, or the slot doesn't have enough room
+ * for SKIP_THRESHOLD consecutive entries*/
+ int skipcount = 0;
+ long newestseqnum = buffer.getNewestSeqNum();
+ search:
+ for (; seqn <= newestseqnum; seqn++) {
+ Slot prevslot = buffer.getSlot(seqn);
+ //Push slot number forward
+ if (!seenliveslot)
+ oldestLiveSlotSequenceNumver = seqn;
+
+ if (!prevslot.isLive())
+ continue;
+ seenliveslot = true;
+ Vector<Entry> liveentries = prevslot.getLiveEntries(resize);
+ for (Entry liveentry : liveentries) {
+ if (s.hasSpace(liveentry))
+ s.addEntry(liveentry);
+ else {
+ skipcount++;
+ if (skipcount > SKIP_THRESHOLD)
+ break search;
+ }
+ }
+ }
+ }
+
+ /**
+ * Checks for malicious activity and updates the local copy of the block chain.
+ */
+ private void validateAndUpdate(Slot[] newSlots, boolean acceptUpdatesToLocal) {
+
+ // The cloud communication layer has checked slot HMACs already before decoding
+ if (newSlots.length == 0) {
+ return;
+ }
+
+ // Make sure all slots are newer than the last largest slot this client has seen
+ long firstSeqNum = newSlots[0].getSequenceNumber();
+ if (firstSeqNum <= sequenceNumber) {
+ throw new Error("Server Error: Sent older slots!");
+ }
+
+ // Create an object that can access both new slots and slots in our local chain
+ // without committing slots to our local chain
+ SlotIndexer indexer = new SlotIndexer(newSlots, buffer);
+
+ // Check that the HMAC chain is not broken
+ checkHMACChain(indexer, newSlots);
+
+ // Set to keep track of messages from clients
+ HashSet<Long> machineSet = new HashSet<Long>(lastMessageTable.keySet());
+
+ // Process each slots data
+ for (Slot slot : newSlots) {
+ processSlot(indexer, slot, acceptUpdatesToLocal, machineSet);
+ updateExpectedSize();
+ }
+
+ // If there is a gap, check to see if the server sent us everything.
+ if (firstSeqNum != (sequenceNumber + 1)) {
+
+ // Check the size of the slots that were sent down by the server.
+ // Can only check the size if there was a gap
+ checkNumSlots(newSlots.length);
+
+ // Since there was a gap every machine must have pushed a slot or must have
+ // a last message message. If not then the server is hiding slots
+ if (!machineSet.isEmpty()) {
+ throw new Error("Missing record for machines: " + machineSet);
+ }
+ }
+
+ // Update the size of our local block chain.
+ commitNewMaxSize();
+
+ // Commit new to slots to the local block chain.
+ for (Slot slot : newSlots) {
+
+ // Insert this slot into our local block chain copy.
+ buffer.putSlot(slot);
+
+ // Keep track of how many slots are currently live (have live data in them).
+ liveSlotCount++;
+ }
+
+ // Get the sequence number of the latest slot in the system
+ sequenceNumber = newSlots[newSlots.length - 1].getSequenceNumber();
+
+ updateLiveStateFromServer();
+
+ // No Need to remember after we pulled from the server
+ offlineTransactionsCommittedAndAtServer.clear();
+
+ // This is invalidated now
+ hadPartialSendToServer = false;
+ }
+
+ private void updateLiveStateFromServer() {
+ // Process the new transaction parts
+ processNewTransactionParts();
+
+ // Do arbitration on new transactions that were received
+ arbitrateFromServer();
+
+ // Update all the committed keys
+ boolean didCommitOrSpeculate = updateCommittedTable();
+
+ // Delete the transactions that are now dead
+ updateLiveTransactionsAndStatus();
+
+ // Do speculations
+ didCommitOrSpeculate |= updateSpeculativeTable(didCommitOrSpeculate);
+ updatePendingTransactionSpeculativeTable(didCommitOrSpeculate);
+ }
+
+ private void updateLiveStateFromLocal() {
+ // Update all the committed keys
+ boolean didCommitOrSpeculate = updateCommittedTable();
+
+ // Delete the transactions that are now dead
+ updateLiveTransactionsAndStatus();
+
+ // Do speculations
+ didCommitOrSpeculate |= updateSpeculativeTable(didCommitOrSpeculate);
+ updatePendingTransactionSpeculativeTable(didCommitOrSpeculate);
+ }
+
+ private void initExpectedSize(long firstSequenceNumber, long numberOfSlots) {
+
+ long prevslots = firstSequenceNumber;
+ if (didFindTableStatus) {
+// expectedsize = (prevslots < ((long) numberOfSlots)) ? (int) prevslots : expectedsize;
+ } else {
+ expectedsize = (prevslots < ((long) numberOfSlots)) ? (int) prevslots : numberOfSlots;
+ }
+ didFindTableStatus = true;
+
+ currMaxSize = numberOfSlots;
+ }
+
+ private void updateExpectedSize() {
+ expectedsize++;
+ if (expectedsize > currMaxSize) {
+ expectedsize = currMaxSize;
+ }
+ }
+
+
+ /**
+ * Check the size of the block chain to make sure there are enough slots sent back by the server.
+ * This is only called when we have a gap between the slots that we have locally and the slots
+ * sent by the server therefore in the slots sent by the server there will be at least 1 Table
+ * status message
+ */
+ private void checkNumSlots(int numberOfSlots) {
+ if (numberOfSlots != expectedsize) {
+ throw new Error("Server Error: Server did not send all slots. Expected: " + expectedsize + " Received:" + numberOfSlots);
+ }
+ }
+
+ private void updateCurrMaxSize(int newmaxsize) {
+ currMaxSize = newmaxsize;
+ }
+
+
+ /**
+ * Update the size of of the local buffer if it is needed.
+ */
+ private void commitNewMaxSize() {
+ didFindTableStatus = false;
+
+ // Resize the local slot buffer
+ if (numberOfSlots != currMaxSize) {
+ buffer.resize((int)currMaxSize);
+ }
+
+ // Change the number of local slots to the new size
+ numberOfSlots = (int)currMaxSize;
+
+ // Recalculate the resize threshold since the size of the local buffer has changed
+ setResizeThreshold();
+ }
+
+ /**
+ * Process the new transaction parts from this latest round of slots received from the server
+ */
+ private void processNewTransactionParts() {
+
+ if (newTransactionParts.size() == 0) {
+ // Nothing new to process
+ return;
+ }
+
+ // Iterate through all the machine Ids that we received new parts for
+ for (Long machineId : newTransactionParts.keySet()) {
+ Map<Pair<Long, Integer>, TransactionPart> parts = newTransactionParts.get(machineId);
+
+ // Iterate through all the parts for that machine Id
+ for (Pair<Long, Integer> partId : parts.keySet()) {
+ TransactionPart part = parts.get(partId);
+
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(part.getArbitratorId());
+ if ((lastTransactionNumber != null) && (lastTransactionNumber >= part.getSequenceNumber())) {
+ // Set dead the transaction part
+ part.setDead();
+ continue;
+ }
+
+ // Get the transaction object for that sequence number
+ Transaction transaction = liveTransactionBySequenceNumberTable.get(part.getSequenceNumber());
+
+ if (transaction == null) {
+ // This is a new transaction that we dont have so make a new one
+ transaction = new Transaction();
+
+ // Insert this new transaction into the live tables
+ liveTransactionBySequenceNumberTable.put(part.getSequenceNumber(), transaction);
+ liveTransactionByTransactionIdTable.put(part.getTransactionId(), transaction);
+ }
+
+ // Add that part to the transaction
+ transaction.addPartDecode(part);
+ }
+ }
+
+ // Clear all the new transaction parts in preparation for the next time the server sends slots
+ newTransactionParts.clear();
+ }
+
+
+ private long lastSeqNumArbOn = 0;
+
+ private void arbitrateFromServer() {
+
+ if (liveTransactionBySequenceNumberTable.size() == 0) {
+ // Nothing to arbitrate on so move on
+ return;
+ }
+
+ // Get the transaction sequence numbers and sort from oldest to newest
+ List<Long> transactionSequenceNumbers = new ArrayList<Long>(liveTransactionBySequenceNumberTable.keySet());
+ Collections.sort(transactionSequenceNumbers);
+
+ // Collection of key value pairs that are
+ Map<IoTString, KeyValue> speculativeTableTmp = new HashMap<IoTString, KeyValue>();
+
+ // The last transaction arbitrated on
+ long lastTransactionCommitted = -1;
+ Set<Abort> generatedAborts = new HashSet<Abort>();
+
+ for (Long transactionSequenceNumber : transactionSequenceNumbers) {
+ Transaction transaction = liveTransactionBySequenceNumberTable.get(transactionSequenceNumber);
+
+
+
+ // Check if this machine arbitrates for this transaction if not then we cant arbitrate this transaction
+ if (transaction.getArbitrator() != localMachineId) {
+ continue;
+ }
+
+ if (transactionSequenceNumber < lastSeqNumArbOn) {
+ continue;
+ }
+
+ if (offlineTransactionsCommittedAndAtServer.contains(transaction.getId())) {
+ // We have seen this already locally so dont commit again
+ continue;
+ }
+
+
+ if (!transaction.isComplete()) {
+ // Will arbitrate in incorrect order if we continue so just break
+ // Most likely this
+ break;
+ }
+
+
+ // update the largest transaction seen by arbitrator from server
+ if (lastTransactionSeenFromMachineFromServer.get(transaction.getMachineId()) == null) {
+ lastTransactionSeenFromMachineFromServer.put(transaction.getMachineId(), transaction.getClientLocalSequenceNumber());
+ } else {
+ Long lastTransactionSeenFromMachine = lastTransactionSeenFromMachineFromServer.get(transaction.getMachineId());
+ if (transaction.getClientLocalSequenceNumber() > lastTransactionSeenFromMachine) {
+ lastTransactionSeenFromMachineFromServer.put(transaction.getMachineId(), transaction.getClientLocalSequenceNumber());
+ }
+ }
+
+ if (transaction.evaluateGuard(committedKeyValueTable, speculativeTableTmp, null)) {
+ // Guard evaluated as true
+
+ // Update the local changes so we can make the commit
+ for (KeyValue kv : transaction.getKeyValueUpdateSet()) {
+ speculativeTableTmp.put(kv.getKey(), kv);
+ }
+
+ // Update what the last transaction committed was for use in batch commit
+ lastTransactionCommitted = transactionSequenceNumber;
+ } else {
+ // Guard evaluated was false so create abort
+
+ // Create the abort
+ Abort newAbort = new Abort(null,
+ transaction.getClientLocalSequenceNumber(),
+ transaction.getSequenceNumber(),
+ transaction.getMachineId(),
+ transaction.getArbitrator(),
+ localArbitrationSequenceNumber);
+ localArbitrationSequenceNumber++;
+
+ generatedAborts.add(newAbort);
+
+ // Insert the abort so we can process
+ processEntry(newAbort);
+ }
+
+ lastSeqNumArbOn = transactionSequenceNumber;
+
+ // liveTransactionBySequenceNumberTable.remove(transactionSequenceNumber);
+ }
+
+ Commit newCommit = null;
+
+ // If there is something to commit
+ if (speculativeTableTmp.size() != 0) {
+
+ // Create the commit and increment the commit sequence number
+ newCommit = new Commit(localArbitrationSequenceNumber, localMachineId, lastTransactionCommitted);
+ localArbitrationSequenceNumber++;
+
+ // Add all the new keys to the commit
+ for (KeyValue kv : speculativeTableTmp.values()) {
+ newCommit.addKV(kv);
+ }
+
+ // create the commit parts
+ newCommit.createCommitParts();
+
+ // Append all the commit parts to the end of the pending queue waiting for sending to the server
+
+ // Insert the commit so we can process it
+ for (CommitPart commitPart : newCommit.getParts().values()) {
+ processEntry(commitPart);
+ }
+ }
+
+ if ((newCommit != null) || (generatedAborts.size() > 0)) {
+ ArbitrationRound arbitrationRound = new ArbitrationRound(newCommit, generatedAborts);
+ pendingSendArbitrationRounds.add(arbitrationRound);
+
+ if (compactArbitrationData()) {
+ ArbitrationRound newArbitrationRound = pendingSendArbitrationRounds.get(pendingSendArbitrationRounds.size() - 1);
+ if (newArbitrationRound.getCommit() != null) {
+ for (CommitPart commitPart : newArbitrationRound.getCommit().getParts().values()) {
+ processEntry(commitPart);
+ }
+ }
+ }
+ }
+ }
+
+ private Pair<Boolean, Boolean> arbitrateOnLocalTransaction(Transaction transaction) {
+
+ // Check if this machine arbitrates for this transaction if not then we cant arbitrate this transaction
+ if (transaction.getArbitrator() != localMachineId) {
+ return new Pair<Boolean, Boolean>(false, false);
+ }
+
+ if (!transaction.isComplete()) {
+ // Will arbitrate in incorrect order if we continue so just break
+ // Most likely this
+ return new Pair<Boolean, Boolean>(false, false);
+ }
+
+ if (transaction.getMachineId() != localMachineId) {
+ // dont do this check for local transactions
+ if (lastTransactionSeenFromMachineFromServer.get(transaction.getMachineId()) != null) {
+ if (lastTransactionSeenFromMachineFromServer.get(transaction.getMachineId()) > transaction.getClientLocalSequenceNumber()) {
+ // We've have already seen this from the server
+ return new Pair<Boolean, Boolean>(false, false);
+ }
+ }
+ }
+
+ if (transaction.evaluateGuard(committedKeyValueTable, null, null)) {
+ // Guard evaluated as true
+
+ // Create the commit and increment the commit sequence number
+ Commit newCommit = new Commit(localArbitrationSequenceNumber, localMachineId, -1);
+ localArbitrationSequenceNumber++;
+
+ // Update the local changes so we can make the commit
+ for (KeyValue kv : transaction.getKeyValueUpdateSet()) {
+ newCommit.addKV(kv);
+ }
+
+ // create the commit parts
+ newCommit.createCommitParts();
+
+ // Append all the commit parts to the end of the pending queue waiting for sending to the server
+ ArbitrationRound arbitrationRound = new ArbitrationRound(newCommit, new HashSet<Abort>());
+ pendingSendArbitrationRounds.add(arbitrationRound);
+
+ if (compactArbitrationData()) {
+ ArbitrationRound newArbitrationRound = pendingSendArbitrationRounds.get(pendingSendArbitrationRounds.size() - 1);
+ for (CommitPart commitPart : newArbitrationRound.getCommit().getParts().values()) {
+ processEntry(commitPart);
+ }
+ } else {
+ // Insert the commit so we can process it
+ for (CommitPart commitPart : newCommit.getParts().values()) {
+ processEntry(commitPart);
+ }
+ }
+
+ if (transaction.getMachineId() == localMachineId) {
+ TransactionStatus status = transaction.getTransactionStatus();
+ if (status != null) {
+ status.setStatus(TransactionStatus.StatusCommitted);
+ }
+ }
+
+ updateLiveStateFromLocal();
+ return new Pair<Boolean, Boolean>(true, true);
+ } else {
+
+ if (transaction.getMachineId() == localMachineId) {
+ // For locally created messages update the status
+
+ // Guard evaluated was false so create abort
+ TransactionStatus status = transaction.getTransactionStatus();
+ if (status != null) {
+ status.setStatus(TransactionStatus.StatusAborted);
+ }
+ } else {
+ Set addAbortSet = new HashSet<Abort>();
+
+
+ // Create the abort
+ Abort newAbort = new Abort(null,
+ transaction.getClientLocalSequenceNumber(),
+ -1,
+ transaction.getMachineId(),
+ transaction.getArbitrator(),
+ localArbitrationSequenceNumber);
+ localArbitrationSequenceNumber++;
+
+ addAbortSet.add(newAbort);
+
+
+ // Append all the commit parts to the end of the pending queue waiting for sending to the server
+ ArbitrationRound arbitrationRound = new ArbitrationRound(null, addAbortSet);
+ pendingSendArbitrationRounds.add(arbitrationRound);
+
+ if (compactArbitrationData()) {
+ ArbitrationRound newArbitrationRound = pendingSendArbitrationRounds.get(pendingSendArbitrationRounds.size() - 1);
+ for (CommitPart commitPart : newArbitrationRound.getCommit().getParts().values()) {
+ processEntry(commitPart);
+ }
+ }
+ }
+
+ updateLiveStateFromLocal();
+ return new Pair<Boolean, Boolean>(true, false);
+ }
+ }
+
+ /**
+ * Compacts the arbitration data my merging commits and aggregating aborts so that a single large push of commits can be done instead of many small updates
+ */
+ private boolean compactArbitrationData() {
+
+ if (pendingSendArbitrationRounds.size() < 2) {
+ // Nothing to compact so do nothing
+ return false;
+ }
+
+ ArbitrationRound lastRound = pendingSendArbitrationRounds.get(pendingSendArbitrationRounds.size() - 1);
+ if (lastRound.didSendPart()) {
+ return false;
+ }
+
+ boolean hadCommit = (lastRound.getCommit() == null);
+ boolean gotNewCommit = false;
+
+ int numberToDelete = 1;
+ while (numberToDelete < pendingSendArbitrationRounds.size()) {
+ ArbitrationRound round = pendingSendArbitrationRounds.get(pendingSendArbitrationRounds.size() - numberToDelete - 1);
+
+ if (round.isFull() || round.didSendPart()) {
+ // Stop since there is a part that cannot be compacted and we need to compact in order
+ break;
+ }
+
+ if (round.getCommit() == null) {
+
+ // Try compacting aborts only
+ int newSize = round.getCurrentSize() + lastRound.getAbortsCount();
+ if (newSize > ArbitrationRound.MAX_PARTS) {
+ // Cant compact since it would be too large
+ break;
+ }
+ lastRound.addAborts(round.getAborts());
+ } else {
+
+ // Create a new larger commit
+ Commit newCommit = Commit.merge(lastRound.getCommit(), round.getCommit(), localArbitrationSequenceNumber);
+ localArbitrationSequenceNumber++;
+
+ // Create the commit parts so that we can count them
+ newCommit.createCommitParts();
+
+ // Calculate the new size of the parts
+ int newSize = newCommit.getNumberOfParts();
+ newSize += lastRound.getAbortsCount();
+ newSize += round.getAbortsCount();
+
+ if (newSize > ArbitrationRound.MAX_PARTS) {
+ // Cant compact since it would be too large
+ break;
+ }
+
+ // Set the new compacted part
+ lastRound.setCommit(newCommit);
+ lastRound.addAborts(round.getAborts());
+ gotNewCommit = true;
+ }
+
+ numberToDelete++;
+ }
+
+ if (numberToDelete != 1) {
+ // If there is a compaction
+
+ // Delete the previous pieces that are now in the new compacted piece
+ if (numberToDelete == pendingSendArbitrationRounds.size()) {
+ pendingSendArbitrationRounds.clear();
+ } else {
+ for (int i = 0; i < numberToDelete; i++) {
+ pendingSendArbitrationRounds.remove(pendingSendArbitrationRounds.size() - 1);
+ }
+ }
+
+ // Add the new compacted into the pending to send list
+ pendingSendArbitrationRounds.add(lastRound);
+
+ // Should reinsert into the commit processor
+ if (hadCommit && gotNewCommit) {
+ return true;
+ }
+ }
+
+ return false;
+ }
+ // private boolean compactArbitrationData() {
+ // return false;
+ // }
+
+ /**
+ * Update all the commits and the committed tables, sets dead the dead transactions
+ */
+ private boolean updateCommittedTable() {
+
+ if (newCommitParts.size() == 0) {
+ // Nothing new to process
+ return false;
+ }
+
+ // Iterate through all the machine Ids that we received new parts for
+ for (Long machineId : newCommitParts.keySet()) {
+ Map<Pair<Long, Integer>, CommitPart> parts = newCommitParts.get(machineId);
+
+ // Iterate through all the parts for that machine Id
+ for (Pair<Long, Integer> partId : parts.keySet()) {
+ CommitPart part = parts.get(partId);
+
+ // Get the transaction object for that sequence number
+ Map<Long, Commit> commitForClientTable = liveCommitsTable.get(part.getMachineId());
+
+ if (commitForClientTable == null) {
+ // This is the first commit from this device
+ commitForClientTable = new HashMap<Long, Commit>();
+ liveCommitsTable.put(part.getMachineId(), commitForClientTable);
+ }
+
+ Commit commit = commitForClientTable.get(part.getSequenceNumber());
+
+ if (commit == null) {
+ // This is a new commit that we dont have so make a new one
+ commit = new Commit();
+
+ // Insert this new commit into the live tables
+ commitForClientTable.put(part.getSequenceNumber(), commit);
+ }
+
+ // Add that part to the commit
+ commit.addPartDecode(part);
+ }
+ }
+
+ // Clear all the new commits parts in preparation for the next time the server sends slots
+ newCommitParts.clear();
+
+ // If we process a new commit keep track of it for future use
+ boolean didProcessANewCommit = false;
+
+ // Process the commits one by one
+ for (Long arbitratorId : liveCommitsTable.keySet()) {
+
+ // Get all the commits for a specific arbitrator
+ Map<Long, Commit> commitForClientTable = liveCommitsTable.get(arbitratorId);
+
+ // Sort the commits in order
+ List<Long> commitSequenceNumbers = new ArrayList<Long>(commitForClientTable.keySet());
+ Collections.sort(commitSequenceNumbers);
+
+ // Get the last commit seen from this arbitrator
+ long lastCommitSeenSequenceNumber = -1;
+ if (lastCommitSeenSequenceNumberByArbitratorTable.get(arbitratorId) != null) {
+ lastCommitSeenSequenceNumber = lastCommitSeenSequenceNumberByArbitratorTable.get(arbitratorId);
+ }
+
+ // Go through each new commit one by one
+ for (int i = 0; i < commitSequenceNumbers.size(); i++) {
+ Long commitSequenceNumber = commitSequenceNumbers.get(i);
+ Commit commit = commitForClientTable.get(commitSequenceNumber);
+
+ // Special processing if a commit is not complete
+ if (!commit.isComplete()) {
+ if (i == (commitSequenceNumbers.size() - 1)) {
+ // If there is an incomplete commit and this commit is the latest one seen then this commit cannot be processed and there are no other commits
+ break;
+ } else {
+ // This is a commit that was already dead but parts of it are still in the block chain (not flushed out yet).
+ // Delete it and move on
+ commit.setDead();
+ commitForClientTable.remove(commit.getSequenceNumber());
+ continue;
+ }
+ }
+
+ // Update the last transaction that was updated if we can
+ if (commit.getTransactionSequenceNumber() != -1) {
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(commit.getMachineId());
+
+ // Update the last transaction sequence number that the arbitrator arbitrated on
+ if ((lastTransactionNumber == null) || (lastTransactionNumber < commit.getTransactionSequenceNumber())) {
+ lastArbitratedTransactionNumberByArbitratorTable.put(commit.getMachineId(), commit.getTransactionSequenceNumber());
+ }
+ }
+
+ // Update the last arbitration data that we have seen so far
+ if (lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(commit.getMachineId()) != null) {
+
+ long lastArbitrationSequenceNumber = lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(commit.getMachineId());
+ if (commit.getSequenceNumber() > lastArbitrationSequenceNumber) {
+ // Is larger
+ lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.put(commit.getMachineId(), commit.getSequenceNumber());
+ }
+ } else {
+ // Never seen any data from this arbitrator so record the first one
+ lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.put(commit.getMachineId(), commit.getSequenceNumber());
+ }
+
+ // We have already seen this commit before so need to do the full processing on this commit
+ if (commit.getSequenceNumber() <= lastCommitSeenSequenceNumber) {
+
+ // Update the last transaction that was updated if we can
+ if (commit.getTransactionSequenceNumber() != -1) {
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(commit.getMachineId());
+
+ // Update the last transaction sequence number that the arbitrator arbitrated on
+ if ((lastTransactionNumber == null) || (lastTransactionNumber < commit.getTransactionSequenceNumber())) {
+ lastArbitratedTransactionNumberByArbitratorTable.put(commit.getMachineId(), commit.getTransactionSequenceNumber());
+ }
+ }
+
+ continue;
+ }
+
+ // If we got here then this is a brand new commit and needs full processing
+
+ // Get what commits should be edited, these are the commits that have live values for their keys
+ Set<Commit> commitsToEdit = new HashSet<Commit>();
+ for (KeyValue kv : commit.getKeyValueUpdateSet()) {
+ commitsToEdit.add(liveCommitsByKeyTable.get(kv.getKey()));
+ }
+ commitsToEdit.remove(null); // remove null since it could be in this set
+
+ // Update each previous commit that needs to be updated
+ for (Commit previousCommit : commitsToEdit) {
+
+ // Only bother with live commits (TODO: Maybe remove this check)
+ if (previousCommit.isLive()) {
+
+ // Update which keys in the old commits are still live
+ for (KeyValue kv : commit.getKeyValueUpdateSet()) {
+ previousCommit.invalidateKey(kv.getKey());
+ }
+
+ // if the commit is now dead then remove it
+ if (!previousCommit.isLive()) {
+ commitForClientTable.remove(previousCommit);
+ }
+ }
+ }
+
+ // Update the last seen sequence number from this arbitrator
+ if (lastCommitSeenSequenceNumberByArbitratorTable.get(commit.getMachineId()) != null) {
+ if (commit.getSequenceNumber() > lastCommitSeenSequenceNumberByArbitratorTable.get(commit.getMachineId())) {
+ lastCommitSeenSequenceNumberByArbitratorTable.put(commit.getMachineId(), commit.getSequenceNumber());
+ }
+ } else {
+ lastCommitSeenSequenceNumberByArbitratorTable.put(commit.getMachineId(), commit.getSequenceNumber());
+ }
+
+ // We processed a new commit that we havent seen before
+ didProcessANewCommit = true;
+
+ // Update the committed table of keys and which commit is using which key
+ for (KeyValue kv : commit.getKeyValueUpdateSet()) {
+ committedKeyValueTable.put(kv.getKey(), kv);
+ liveCommitsByKeyTable.put(kv.getKey(), commit);
+ }
+ }
+ }
+
+ return didProcessANewCommit;
+ }
+
+ /**
+ * Create the speculative table from transactions that are still live and have come from the cloud
+ */
+ private boolean updateSpeculativeTable(boolean didProcessNewCommits) {
+ if (liveTransactionBySequenceNumberTable.keySet().size() == 0) {
+ // There is nothing to speculate on
+ return false;
+ }
+
+ // Create a list of the transaction sequence numbers and sort them from oldest to newest
+ List<Long> transactionSequenceNumbersSorted = new ArrayList<Long>(liveTransactionBySequenceNumberTable.keySet());
+ Collections.sort(transactionSequenceNumbersSorted);
+
+ boolean hasGapInTransactionSequenceNumbers = transactionSequenceNumbersSorted.get(0) != oldestTransactionSequenceNumberSpeculatedOn;
+
+
+ if (hasGapInTransactionSequenceNumbers || didProcessNewCommits) {
+ // If there is a gap in the transaction sequence numbers then there was a commit or an abort of a transaction
+ // OR there was a new commit (Could be from offline commit) so a redo the speculation from scratch
+
+ // Start from scratch
+ speculatedKeyValueTable.clear();
+ lastTransactionSequenceNumberSpeculatedOn = -1;
+ oldestTransactionSequenceNumberSpeculatedOn = -1;
+
+ }
+
+ // Remember the front of the transaction list
+ oldestTransactionSequenceNumberSpeculatedOn = transactionSequenceNumbersSorted.get(0);
+
+ // Find where to start arbitration from
+ int startIndex = transactionSequenceNumbersSorted.indexOf(lastTransactionSequenceNumberSpeculatedOn) + 1;
+
+ if (startIndex >= transactionSequenceNumbersSorted.size()) {
+ // Make sure we are not out of bounds
+ return false; // did not speculate
+ }
+
+ Set<Long> incompleteTransactionArbitrator = new HashSet<Long>();
+ boolean didSkip = true;
+
+ for (int i = startIndex; i < transactionSequenceNumbersSorted.size(); i++) {
+ long transactionSequenceNumber = transactionSequenceNumbersSorted.get(i);
+ Transaction transaction = liveTransactionBySequenceNumberTable.get(transactionSequenceNumber);
+
+ if (!transaction.isComplete()) {
+ // If there is an incomplete transaction then there is nothing we can do
+ // add this transactions arbitrator to the list of arbitrators we should ignore
+ incompleteTransactionArbitrator.add(transaction.getArbitrator());
+ didSkip = true;
+ continue;
+ }
+
+ if (incompleteTransactionArbitrator.contains(transaction.getArbitrator())) {
+ continue;
+ }
+
+ lastTransactionSequenceNumberSpeculatedOn = transactionSequenceNumber;
+
+ if (transaction.evaluateGuard(committedKeyValueTable, speculatedKeyValueTable, null)) {
+ // Guard evaluated to true so update the speculative table
+ for (KeyValue kv : transaction.getKeyValueUpdateSet()) {
+ speculatedKeyValueTable.put(kv.getKey(), kv);
+ }
+ }
+ }
+
+ if (didSkip) {
+ // Since there was a skip we need to redo the speculation next time around
+ lastTransactionSequenceNumberSpeculatedOn = -1;
+ oldestTransactionSequenceNumberSpeculatedOn = -1;
+ }
+
+ // We did some speculation
+ return true;
+ }
+
+ /**
+ * Create the pending transaction speculative table from transactions that are still in the pending transaction buffer
+ */
+ private void updatePendingTransactionSpeculativeTable(boolean didProcessNewCommitsOrSpeculate) {
+ if (pendingTransactionQueue.size() == 0) {
+ // There is nothing to speculate on
+ return;
+ }
+
+
+ if (didProcessNewCommitsOrSpeculate || (firstPendingTransaction != pendingTransactionQueue.get(0))) {
+ // need to reset on the pending speculation
+ lastPendingTransactionSpeculatedOn = null;
+ firstPendingTransaction = pendingTransactionQueue.get(0);
+ pendingTransactionSpeculatedKeyValueTable.clear();
+ }
+
+ // Find where to start arbitration from
+ int startIndex = pendingTransactionQueue.indexOf(firstPendingTransaction) + 1;
+
+ if (startIndex >= pendingTransactionQueue.size()) {
+ // Make sure we are not out of bounds
+ return;
+ }
+
+ for (int i = startIndex; i < pendingTransactionQueue.size(); i++) {
+ Transaction transaction = pendingTransactionQueue.get(i);
+
+ lastPendingTransactionSpeculatedOn = transaction;
+
+ if (transaction.evaluateGuard(committedKeyValueTable, speculatedKeyValueTable, pendingTransactionSpeculatedKeyValueTable)) {
+ // Guard evaluated to true so update the speculative table
+ for (KeyValue kv : transaction.getKeyValueUpdateSet()) {
+ pendingTransactionSpeculatedKeyValueTable.put(kv.getKey(), kv);
+ }
+ }
+ }
+ }
+
+ /**
+ * Set dead and remove from the live transaction tables the transactions that are dead
+ */
+ private void updateLiveTransactionsAndStatus() {
+
+ // Go through each of the transactions
+ for (Iterator<Map.Entry<Long, Transaction>> iter = liveTransactionBySequenceNumberTable.entrySet().iterator(); iter.hasNext();) {
+ Transaction transaction = iter.next().getValue();
+
+ // Check if the transaction is dead
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(transaction.getArbitrator());
+ if ((lastTransactionNumber != null) && (lastTransactionNumber >= transaction.getSequenceNumber())) {
+
+ // Set dead the transaction
+ transaction.setDead();
+
+ // Remove the transaction from the live table
+ iter.remove();
+ liveTransactionByTransactionIdTable.remove(transaction.getId());
+ }
+ }
+
+ // Go through each of the transactions
+ for (Iterator<Map.Entry<Long, TransactionStatus>> iter = outstandingTransactionStatus.entrySet().iterator(); iter.hasNext();) {
+ TransactionStatus status = iter.next().getValue();
+
+ // Check if the transaction is dead
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(status.getTransactionArbitrator());
+ if ((lastTransactionNumber != null) && (lastTransactionNumber >= status.getTransactionSequenceNumber())) {
+
+ // Set committed
+ status.setStatus(TransactionStatus.StatusCommitted);
+
+ // Remove
+ iter.remove();
+ }
+ }
+ }
+
+ /**
+ * Process this slot, entry by entry. Also update the latest message sent by slot
+ */
+ private void processSlot(SlotIndexer indexer, Slot slot, boolean acceptUpdatesToLocal, HashSet<Long> machineSet) {
+
+ // Update the last message seen
+ updateLastMessage(slot.getMachineID(), slot.getSequenceNumber(), slot, acceptUpdatesToLocal, machineSet);
+
+ // Process each entry in the slot
+ for (Entry entry : slot.getEntries()) {
+ switch (entry.getType()) {
+
+ case Entry.TypeCommitPart:
+ processEntry((CommitPart)entry);
+ break;
+
+ case Entry.TypeAbort:
+ processEntry((Abort)entry);
+ break;
+
+ case Entry.TypeTransactionPart:
+ processEntry((TransactionPart)entry);
+ break;
+
+ case Entry.TypeNewKey:
+ processEntry((NewKey)entry);
+ break;
+
+ case Entry.TypeLastMessage:
+ processEntry((LastMessage)entry, machineSet);
+ break;
+
+ case Entry.TypeRejectedMessage:
+ processEntry((RejectedMessage)entry, indexer);
+ break;
+
+ case Entry.TypeTableStatus:
+ processEntry((TableStatus)entry, slot.getSequenceNumber());
+ break;
+
+ default:
+ throw new Error("Unrecognized type: " + entry.getType());
+ }
+ }
+ }
+
+ /**
+ * Update the last message that was sent for a machine Id
+ */
+ private void processEntry(LastMessage entry, HashSet<Long> machineSet) {
+ // Update what the last message received by a machine was
+ updateLastMessage(entry.getMachineID(), entry.getSequenceNumber(), entry, false, machineSet);
+ }
+
+ /**
+ * Add the new key to the arbitrators table and update the set of live new keys (in case of a rescued new key message)
+ */
+ private void processEntry(NewKey entry) {
+
+ // Update the arbitrator table with the new key information
+ arbitratorTable.put(entry.getKey(), entry.getMachineID());
+
+ // Update what the latest live new key is
+ NewKey oldNewKey = liveNewKeyTable.put(entry.getKey(), entry);
+ if (oldNewKey != null) {
+ // Delete the old new key messages
+ oldNewKey.setDead();
+ }
+ }
+
+ /**
+ * Process new table status entries and set dead the old ones as new ones come in.
+ * keeps track of the largest and smallest table status seen in this current round
+ * of updating the local copy of the block chain
+ */
+ private void processEntry(TableStatus entry, long seq) {
+ int newNumSlots = entry.getMaxSlots();
+ updateCurrMaxSize(newNumSlots);
+
+ initExpectedSize(seq, newNumSlots);
+
+ if (liveTableStatus != null) {
+ // We have a larger table status so the old table status is no longer alive
+ liveTableStatus.setDead();
+ }
+
+ // Make this new table status the latest alive table status
+ liveTableStatus = entry;
+ }
+
+ /**
+ * Check old messages to see if there is a block chain violation. Also
+ */
+ private void processEntry(RejectedMessage entry, SlotIndexer indexer) {
+ long oldSeqNum = entry.getOldSeqNum();
+ long newSeqNum = entry.getNewSeqNum();
+ boolean isequal = entry.getEqual();
+ long machineId = entry.getMachineID();
+ long seq = entry.getSequenceNumber();
+
+
+ // Check if we have messages that were supposed to be rejected in our local block chain
+ for (long seqNum = oldSeqNum; seqNum <= newSeqNum; seqNum++) {
+
+ // Get the slot
+ Slot slot = indexer.getSlot(seqNum);
+
+ if (slot != null) {
+ // If we have this slot make sure that it was not supposed to be a rejected slot
+
+ long slotMachineId = slot.getMachineID();
+ if (isequal != (slotMachineId == machineId)) {
+ throw new Error("Server Error: Trying to insert rejected message for slot " + seqNum);
+ }
+ }
+ }
+
+
+ // Create a list of clients to watch until they see this rejected message entry.
+ HashSet<Long> deviceWatchSet = new HashSet<Long>();
+ for (Map.Entry<Long, Pair<Long, Liveness>> lastMessageEntry : lastMessageTable.entrySet()) {
+
+ // Machine ID for the last message entry
+ long lastMessageEntryMachineId = lastMessageEntry.getKey();
+
+ // We've seen it, don't need to continue to watch. Our next
+ // message will implicitly acknowledge it.
+ if (lastMessageEntryMachineId == localMachineId) {
+ continue;
+ }
+
+ Pair<Long, Liveness> lastMessageValue = lastMessageEntry.getValue();
+ long entrySequenceNumber = lastMessageValue.getFirst();
+
+ if (entrySequenceNumber < seq) {
+
+ // Add this rejected message to the set of messages that this machine ID did not see yet
+ addWatchList(lastMessageEntryMachineId, entry);
+
+ // This client did not see this rejected message yet so add it to the watch set to monitor
+ deviceWatchSet.add(lastMessageEntryMachineId);
+ }
+ }
+
+ if (deviceWatchSet.isEmpty()) {
+ // This rejected message has been seen by all the clients so
+ entry.setDead();
+ } else {
+ // We need to watch this rejected message
+ entry.setWatchSet(deviceWatchSet);
+ }
+ }
+
+ /**
+ * Check if this abort is live, if not then save it so we can kill it later.
+ * update the last transaction number that was arbitrated on.
+ */
+ private void processEntry(Abort entry) {
+
+
+ if (entry.getTransactionSequenceNumber() != -1) {
+ // update the transaction status if it was sent to the server
+ TransactionStatus status = outstandingTransactionStatus.remove(entry.getTransactionSequenceNumber());
+ if (status != null) {
+ status.setStatus(TransactionStatus.StatusAborted);
+ }
+ }
+
+ // Abort has not been seen by the client it is for yet so we need to keep track of it
+ Abort previouslySeenAbort = liveAbortTable.put(entry.getAbortId(), entry);
+ if (previouslySeenAbort != null) {
+ previouslySeenAbort.setDead(); // Delete old version of the abort since we got a rescued newer version
+ }
+
+ if (entry.getTransactionArbitrator() == localMachineId) {
+ liveAbortsGeneratedByLocal.put(entry.getArbitratorLocalSequenceNumber(), entry);
+ }
+
+ if ((entry.getSequenceNumber() != -1) && (lastMessageTable.get(entry.getTransactionMachineId()).getFirst() >= entry.getSequenceNumber())) {
+
+ // The machine already saw this so it is dead
+ entry.setDead();
+ liveAbortTable.remove(entry.getAbortId());
+
+ if (entry.getTransactionArbitrator() == localMachineId) {
+ liveAbortsGeneratedByLocal.remove(entry.getArbitratorLocalSequenceNumber());
+ }
+
+ return;
+ }
+
+
+
+
+ // Update the last arbitration data that we have seen so far
+ if (lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(entry.getTransactionArbitrator()) != null) {
+
+ long lastArbitrationSequenceNumber = lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.get(entry.getTransactionArbitrator());
+ if (entry.getSequenceNumber() > lastArbitrationSequenceNumber) {
+ // Is larger
+ lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.put(entry.getTransactionArbitrator(), entry.getSequenceNumber());
+ }
+ } else {
+ // Never seen any data from this arbitrator so record the first one
+ lastArbitrationDataLocalSequenceNumberSeenFromArbitrator.put(entry.getTransactionArbitrator(), entry.getSequenceNumber());
+ }
+
+
+ // Set dead a transaction if we can
+ Transaction transactionToSetDead = liveTransactionByTransactionIdTable.remove(new Pair<Long, Long>(entry.getTransactionMachineId(), entry.getTransactionClientLocalSequenceNumber()));
+ if (transactionToSetDead != null) {
+ liveTransactionBySequenceNumberTable.remove(transactionToSetDead.getSequenceNumber());
+ }
+
+ // Update the last transaction sequence number that the arbitrator arbitrated on
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(entry.getTransactionArbitrator());
+ if ((lastTransactionNumber == null) || (lastTransactionNumber < entry.getTransactionSequenceNumber())) {
+
+ // Is a valid one
+ if (entry.getTransactionSequenceNumber() != -1) {
+ lastArbitratedTransactionNumberByArbitratorTable.put(entry.getTransactionArbitrator(), entry.getTransactionSequenceNumber());
+ }
+ }
+ }
+
+ /**
+ * Set dead the transaction part if that transaction is dead and keep track of all new parts
+ */
+ private void processEntry(TransactionPart entry) {
+ // Check if we have already seen this transaction and set it dead OR if it is not alive
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(entry.getArbitratorId());
+ if ((lastTransactionNumber != null) && (lastTransactionNumber >= entry.getSequenceNumber())) {
+ // This transaction is dead, it was already committed or aborted
+ entry.setDead();
+ return;
+ }
+
+ // This part is still alive
+ Map<Pair<Long, Integer>, TransactionPart> transactionPart = newTransactionParts.get(entry.getMachineId());
+
+ if (transactionPart == null) {
+ // Dont have a table for this machine Id yet so make one
+ transactionPart = new HashMap<Pair<Long, Integer>, TransactionPart>();
+ newTransactionParts.put(entry.getMachineId(), transactionPart);
+ }
+
+ // Update the part and set dead ones we have already seen (got a rescued version)
+ TransactionPart previouslySeenPart = transactionPart.put(entry.getPartId(), entry);
+ if (previouslySeenPart != null) {
+ previouslySeenPart.setDead();
+ }
+ }
+
+ /**
+ * Process new commit entries and save them for future use. Delete duplicates
+ */
+ private void processEntry(CommitPart entry) {
+
+
+ // Update the last transaction that was updated if we can
+ if (entry.getTransactionSequenceNumber() != -1) {
+ Long lastTransactionNumber = lastArbitratedTransactionNumberByArbitratorTable.get(entry.getMachineId());
+
+ // Update the last transaction sequence number that the arbitrator arbitrated on
+ if ((lastTransactionNumber == null) || (lastTransactionNumber < entry.getTransactionSequenceNumber())) {
+ lastArbitratedTransactionNumberByArbitratorTable.put(entry.getMachineId(), entry.getTransactionSequenceNumber());
+ }
+ }
+
+
+
+
+ Map<Pair<Long, Integer>, CommitPart> commitPart = newCommitParts.get(entry.getMachineId());
+
+ if (commitPart == null) {
+ // Don't have a table for this machine Id yet so make one
+ commitPart = new HashMap<Pair<Long, Integer>, CommitPart>();
+ newCommitParts.put(entry.getMachineId(), commitPart);
+ }
+
+ // Update the part and set dead ones we have already seen (got a rescued version)
+ CommitPart previouslySeenPart = commitPart.put(entry.getPartId(), entry);
+ if (previouslySeenPart != null) {
+ previouslySeenPart.setDead();
+ }
+ }
+
+ /**
+ * Update the last message seen table. Update and set dead the appropriate RejectedMessages as clients see them.
+ * Updates the live aborts, removes those that are dead and sets them dead.
+ * Check that the last message seen is correct and that there is no mismatch of our own last message or that
+ * other clients have not had a rollback on the last message.
+ */
+ private void updateLastMessage(long machineId, long seqNum, Liveness liveness, boolean acceptUpdatesToLocal, HashSet<Long> machineSet) {
+
+ // We have seen this machine ID
+ machineSet.remove(machineId);
+
+ // Get the set of rejected messages that this machine Id is has not seen yet
+ HashSet<RejectedMessage> watchset = rejectedMessageWatchListTable.get(machineId);
+
+ // If there is a rejected message that this machine Id has not seen yet
+ if (watchset != null) {
+
+ // Go through each rejected message that this machine Id has not seen yet
+ for (Iterator<RejectedMessage> rmit = watchset.iterator(); rmit.hasNext(); ) {
+
+ RejectedMessage rm = rmit.next();
+
+ // If this machine Id has seen this rejected message...
+ if (rm.getSequenceNumber() <= seqNum) {
+
+ // Remove it from our watchlist
+ rmit.remove();
+
+ // Decrement machines that need to see this notification
+ rm.removeWatcher(machineId);
+ }
+ }
+ }
+
+ // Set dead the abort
+ for (Iterator<Map.Entry<Pair<Long, Long>, Abort>> i = liveAbortTable.entrySet().iterator(); i.hasNext();) {
+ Abort abort = i.next().getValue();
+
+ if ((abort.getTransactionMachineId() == machineId) && (abort.getSequenceNumber() <= seqNum)) {
+ abort.setDead();
+ i.remove();
+
+ if (abort.getTransactionArbitrator() == localMachineId) {
+ liveAbortsGeneratedByLocal.remove(abort.getArbitratorLocalSequenceNumber());
+ }
+ }
+ }
+
+
+
+ if (machineId == localMachineId) {
+ // Our own messages are immediately dead.
+ if (liveness instanceof LastMessage) {
+ ((LastMessage)liveness).setDead();
+ } else if (liveness instanceof Slot) {
+ ((Slot)liveness).setDead();
+ } else {
+ throw new Error("Unrecognized type");
+ }
+ }
+
+ // Get the old last message for this device
+ Pair<Long, Liveness> lastMessageEntry = lastMessageTable.put(machineId, new Pair<Long, Liveness>(seqNum, liveness));
+ if (lastMessageEntry == null) {
+ // If no last message then there is nothing else to process
+ return;
+ }
+
+ long lastMessageSeqNum = lastMessageEntry.getFirst();
+ Liveness lastEntry = lastMessageEntry.getSecond();
+
+ // If it is not our machine Id since we already set ours to dead
+ if (machineId != localMachineId) {
+ if (lastEntry instanceof LastMessage) {
+ ((LastMessage)lastEntry).setDead();
+ } else if (lastEntry instanceof Slot) {
+ ((Slot)lastEntry).setDead();
+ } else {
+ throw new Error("Unrecognized type");
+ }
+ }
+
+ // Make sure the server is not playing any games
+ if (machineId == localMachineId) {
+
+ if (hadPartialSendToServer) {
+ // We were not making any updates and we had a machine mismatch
+ if (lastMessageSeqNum > seqNum && !acceptUpdatesToLocal) {
+ throw new Error("Server Error: Mismatch on local machine sequence number, needed at least: " + lastMessageSeqNum + " got: " + seqNum);
+ }
+
+ } else {
+ // We were not making any updates and we had a machine mismatch
+ if (lastMessageSeqNum != seqNum && !acceptUpdatesToLocal) {
+ throw new Error("Server Error: Mismatch on local machine sequence number, needed: " + lastMessageSeqNum + " got: " + seqNum);
+ }
+ }
+ } else {
+ if (lastMessageSeqNum > seqNum) {
+ throw new Error("Server Error: Rollback on remote machine sequence number");
+ }
+ }
+ }
+
+ /**
+ * Add a rejected message entry to the watch set to keep track of which clients have seen that
+ * rejected message entry and which have not.
+ */
+ private void addWatchList(long machineId, RejectedMessage entry) {
+ HashSet<RejectedMessage> entries = rejectedMessageWatchListTable.get(machineId);
+ if (entries == null) {
+ // There is no set for this machine ID yet so create one
+ entries = new HashSet<RejectedMessage>();
+ rejectedMessageWatchListTable.put(machineId, entries);
+ }
+ entries.add(entry);
+ }
+
+ /**
+ * Check if the HMAC chain is not violated
+ */
+ private void checkHMACChain(SlotIndexer indexer, Slot[] newSlots) {
+ for (int i = 0; i < newSlots.length; i++) {
+ Slot currSlot = newSlots[i];
+ Slot prevSlot = indexer.getSlot(currSlot.getSequenceNumber() - 1);
+ if (prevSlot != null &&
+ !Arrays.equals(prevSlot.getHMAC(), currSlot.getPrevHMAC()))
+ throw new Error("Server Error: Invalid HMAC Chain" + currSlot + " " + prevSlot);
+ }
+ }
+}
\ No newline at end of file