import gov.nasa.jpf.Config;
import gov.nasa.jpf.JPF;
import gov.nasa.jpf.ListenerAdapter;
+import gov.nasa.jpf.jvm.bytecode.INVOKEINTERFACE;
+import gov.nasa.jpf.jvm.bytecode.JVMFieldInstruction;
import gov.nasa.jpf.search.Search;
-import gov.nasa.jpf.jvm.bytecode.*;
import gov.nasa.jpf.vm.*;
import gov.nasa.jpf.vm.bytecode.ReadInstruction;
import gov.nasa.jpf.vm.bytecode.WriteInstruction;
import gov.nasa.jpf.vm.choice.IntIntervalGenerator;
import java.io.FileWriter;
+import java.io.IOException;
import java.io.PrintWriter;
import java.util.*;
import java.util.logging.Logger;
-import java.io.IOException;
-// TODO: Fix for Groovy's model-checking
-// TODO: This is a setter to change the values of the ChoiceGenerator to implement POR
/**
- * Simple tool to log state changes.
- *
- * This DPOR implementation is augmented by the algorithm presented in this SPIN paper:
- * http://spinroot.com/spin/symposia/ws08/spin2008_submission_33.pdf
- *
- * The algorithm is presented on page 11 of the paper. Basically, we have a graph G
- * (i.e., visible operation dependency graph).
- * This DPOR implementation actually fixes the algorithm in the SPIN paper that does not
- * consider cases where a state could be matched early. In this new algorithm/implementation,
- * each run is terminated iff:
+ * This a DPOR implementation for event-driven applications with loops that create cycles of state matching
+ * In this new DPOR algorithm/implementation, each run is terminated iff:
* - we find a state that matches a state in a previous run, or
* - we have a matched state in the current run that consists of cycles that contain all choices/events.
*/
private int choiceCounter;
private int maxEventChoice;
// Data structure to track the events seen by each state to track cycles (containing all events) for termination
- private HashSet<Integer> currVisitedStates; // States being visited in the current execution
- private HashSet<Integer> justVisitedStates; // States just visited in the previous choice/event
- private HashSet<Integer> prevVisitedStates; // States visited in the previous execution
+ private HashMap<Integer,Integer> currVisitedStates; // States visited in the current execution (maps to frequency)
+ private HashSet<Integer> justVisitedStates; // States just visited in the previous choice/event
+ private HashSet<Integer> prevVisitedStates; // States visited in the previous execution
+ private HashSet<ClassInfo> nonRelevantClasses;// Class info objects of non-relevant classes
+ private HashSet<FieldInfo> nonRelevantFields; // Field info objects of non-relevant fields
+ private HashSet<FieldInfo> relevantFields; // Field info objects of relevant fields
private HashMap<Integer, HashSet<Integer>> stateToEventMap;
// Data structure to analyze field Read/Write accesses and conflicts
- private HashMap<Integer, LinkedList<Integer[]>> backtrackMap; // Track created backtracking points
+ private HashMap<Integer, LinkedList<BacktrackExecution>> backtrackMap; // Track created backtracking points
private PriorityQueue<Integer> backtrackStateQ; // Heap that returns the latest state
- private ArrayList<BacktrackPoint> backtrackPointList; // Record backtrack points (CG, state Id, and choice)
- private HashMap<Integer, HashSet<Integer>> conflictPairMap; // Record conflicting events
- private HashSet<String> doneBacktrackSet; // Record state ID and trace already constructed
- private HashMap<Integer, ReadWriteSet> readWriteFieldsMap; // Record fields that are accessed
+ private Execution currentExecution; // Holds the information about the current execution
+ private HashMap<Integer, HashSet<Integer>> doneBacktrackMap; // Record state ID and trace already constructed
private HashMap<Integer, RestorableVMState> restorableStateMap; // Maps state IDs to the restorable state object
- private HashMap<Integer, Integer> stateToChoiceCounterMap; // Maps state IDs to the choice counter
- private HashMap<Integer, ReachabilityGraph> stateToRGraph; // Maps state IDs to a ReachabilityGraph
+ private RGraph rGraph; // R-Graph for past executions
// Boolean states
private boolean isBooleanCGFlipped;
private boolean isEndOfExecution;
// Statistics
- private int numOfConflicts;
private int numOfTransitions;
-
+
public DPORStateReducer(Config config, JPF jpf) {
verboseMode = config.getBoolean("printout_state_transition", false);
stateReductionMode = config.getBoolean("activate_state_reduction", true);
}
}
isBooleanCGFlipped = false;
- numOfConflicts = 0;
numOfTransitions = 0;
+ nonRelevantClasses = new HashSet<>();
+ nonRelevantFields = new HashSet<>();
+ relevantFields = new HashSet<>();
restorableStateMap = new HashMap<>();
initializeStatesVariables();
}
@Override
public void searchFinished(Search search) {
- if (stateReductionMode) {
- // Number of conflicts = first trace + subsequent backtrack points
- numOfConflicts += 1 + doneBacktrackSet.size();
- }
if (verboseMode) {
out.println("\n==> DEBUG: ----------------------------------- search finished");
out.println("\n==> DEBUG: State reduction mode : " + stateReductionMode);
- out.println("\n==> DEBUG: Number of conflicts : " + numOfConflicts);
out.println("\n==> DEBUG: Number of transitions : " + numOfTransitions);
out.println("\n==> DEBUG: ----------------------------------- search finished" + "\n");
fileWriter.println("==> DEBUG: State reduction mode : " + stateReductionMode);
- fileWriter.println("==> DEBUG: Number of conflicts : " + numOfConflicts);
fileWriter.println("==> DEBUG: Number of transitions : " + numOfTransitions);
fileWriter.println();
fileWriter.close();
// Initialize with necessary information from the CG
if (nextCG instanceof IntChoiceFromSet) {
IntChoiceFromSet icsCG = (IntChoiceFromSet) nextCG;
+ // Tell JPF that we are performing DPOR
+ icsCG.setDpor();
if (!isEndOfExecution) {
// Check if CG has been initialized, otherwise initialize it
Integer[] cgChoices = icsCG.getAllChoices();
@Override
public void choiceGeneratorAdvanced(VM vm, ChoiceGenerator<?> currentCG) {
-
if (stateReductionMode) {
// Check the boolean CG and if it is flipped, we are resetting the analysis
if (currentCG instanceof BooleanChoiceGenerator) {
if (!isBooleanCGFlipped) {
isBooleanCGFlipped = true;
} else {
- // Number of conflicts = first trace + subsequent backtrack points
- numOfConflicts = 1 + doneBacktrackSet.size();
// Allocate new objects for data structure when the boolean is flipped from "false" to "true"
initializeStatesVariables();
}
// If this is a new CG then we need to update data structures
resetStatesForNewExecution(icsCG, vm);
// If we don't see a fair scheduling of events/choices then we have to enforce it
- fairSchedulingAndBacktrackPoint(icsCG, vm);
- // Explore the next backtrack point:
+ ensureFairSchedulingAndSetupTransition(icsCG, vm);
+ // Update backtrack set of an executed event (transition): one transition before this one
+ updateBacktrackSet(currentExecution, choiceCounter - 1);
+ // Explore the next backtrack point:
// 1) if we have seen this state or this state contains cycles that involve all events, and
// 2) after the current CG is advanced at least once
if (terminateCurrentExecution() && choiceCounter > 0) {
- saveExecutionInfo();
exploreNextBacktrackPoints(vm, icsCG);
} else {
numOfTransitions++;
currentChoice = checkAndAdjustChoice(currentChoice, vm);
// Record accesses from executed instructions
if (executedInsn instanceof JVMFieldInstruction) {
- // Analyze only after being initialized
- String fieldClass = ((JVMFieldInstruction) executedInsn).getFieldInfo().getFullName();
// We don't care about libraries
- if (!isFieldExcluded(fieldClass)) {
- analyzeReadWriteAccesses(executedInsn, fieldClass, currentChoice);
+ if (!isFieldExcluded(executedInsn)) {
+ analyzeReadWriteAccesses(executedInsn, currentChoice);
}
} else if (executedInsn instanceof INVOKEINTERFACE) {
// Handle the read/write accesses that occur through iterators
analyzeReadWriteAccesses(executedInsn, ti, currentChoice);
}
- // Analyze conflicts from next instructions
- if (nextInsn instanceof JVMFieldInstruction) {
- // Skip the constructor because it is called once and does not have shared access with other objects
- if (!nextInsn.getMethodInfo().getName().equals("<init>")) {
- String fieldClass = ((JVMFieldInstruction) nextInsn).getFieldInfo().getFullName();
- if (!isFieldExcluded(fieldClass)) {
- // Check for conflict (go backward from current choice and get the first conflict)
- for (int eventCounter = currentChoice - 1; eventCounter >= 0; eventCounter--) {
- // Check for conflicts with Write fields for both Read and Write instructions
- // Check and record a backtrack set for just once!
- if (isConflictFound(nextInsn, eventCounter, currentChoice, fieldClass) &&
- isNewConflict(currentChoice, eventCounter)) {
- createBacktrackingPoint(currentChoice, eventCounter);
- }
- }
- }
- }
- }
}
}
}
// -- INNER CLASSES
+ // This class compactly stores backtrack execution:
+ // 1) backtrack choice list, and
+ // 2) first backtrack point (linking with predecessor execution)
+ private class BacktrackExecution {
+ private Integer[] choiceList;
+ private TransitionEvent firstTransition;
+
+ public BacktrackExecution(Integer[] choList, TransitionEvent fTransition) {
+ choiceList = choList;
+ firstTransition = fTransition;
+ }
+
+ public Integer[] getChoiceList() {
+ return choiceList;
+ }
+
+ public TransitionEvent getFirstTransition() {
+ return firstTransition;
+ }
+ }
+
+ // This class stores a representation of an execution
+ // TODO: We can modify this class to implement some optimization (e.g., clock-vector)
+ // TODO: We basically need to keep track of:
+ // TODO: (1) last read/write access to each memory location
+ // TODO: (2) last state with two or more incoming events/transitions
+ private class Execution {
+ private HashMap<IntChoiceFromSet, Integer> cgToChoiceMap; // Map between CG to choice numbers for O(1) access
+ private ArrayList<TransitionEvent> executionTrace; // The BacktrackPoint objects of this execution
+ private boolean isNew; // Track if this is the first time it is accessed
+ private HashMap<Integer, ReadWriteSet> readWriteFieldsMap; // Record fields that are accessed
+
+ public Execution() {
+ cgToChoiceMap = new HashMap<>();
+ executionTrace = new ArrayList<>();
+ isNew = true;
+ readWriteFieldsMap = new HashMap<>();
+ }
+
+ public void addTransition(TransitionEvent newBacktrackPoint) {
+ executionTrace.add(newBacktrackPoint);
+ }
+
+ public void clearCGToChoiceMap() {
+ cgToChoiceMap = null;
+ }
+
+ public int getChoiceFromCG(IntChoiceFromSet icsCG) {
+ return cgToChoiceMap.get(icsCG);
+ }
+
+ public ArrayList<TransitionEvent> getExecutionTrace() {
+ return executionTrace;
+ }
+
+ public TransitionEvent getFirstTransition() {
+ return executionTrace.get(0);
+ }
+
+ public TransitionEvent getLastTransition() {
+ return executionTrace.get(executionTrace.size() - 1);
+ }
+
+ public HashMap<Integer, ReadWriteSet> getReadWriteFieldsMap() {
+ return readWriteFieldsMap;
+ }
+
+ public boolean isNew() {
+ if (isNew) {
+ // Right after this is accessed, it is no longer new
+ isNew = false;
+ return true;
+ }
+ return false;
+ }
+
+ public void mapCGToChoice(IntChoiceFromSet icsCG, int choice) {
+ cgToChoiceMap.put(icsCG, choice);
+ }
+ }
+
+ // This class compactly stores a predecessor
+ // 1) a predecessor execution
+ // 2) the predecessor choice in that predecessor execution
+ private class Predecessor {
+ private int choice; // Predecessor choice
+ private Execution execution; // Predecessor execution
+
+ public Predecessor(int predChoice, Execution predExec) {
+ choice = predChoice;
+ execution = predExec;
+ }
+
+ public int getChoice() {
+ return choice;
+ }
+
+ public Execution getExecution() {
+ return execution;
+ }
+ }
+
+ // This class represents a R-Graph (in the paper it is a state transition graph R)
+ // This implementation stores reachable transitions from and connects with past executions
+ private class RGraph {
+ private int hiStateId; // Maximum state Id
+ private HashMap<Integer, HashSet<TransitionEvent>> graph; // Reachable transitions from past executions
+
+ public RGraph() {
+ hiStateId = 0;
+ graph = new HashMap<>();
+ }
+
+ public void addReachableTransition(int stateId, TransitionEvent transition) {
+ HashSet<TransitionEvent> transitionSet;
+ if (graph.containsKey(stateId)) {
+ transitionSet = graph.get(stateId);
+ } else {
+ transitionSet = new HashSet<>();
+ graph.put(stateId, transitionSet);
+ }
+ // Insert into the set if it does not contain it yet
+ if (!transitionSet.contains(transition)) {
+ transitionSet.add(transition);
+ }
+ // Update highest state ID
+ if (hiStateId < stateId) {
+ hiStateId = stateId;
+ }
+ }
+
+ public HashSet<TransitionEvent> getReachableTransitionsAtState(int stateId) {
+ if (!graph.containsKey(stateId)) {
+ // This is a loop from a transition to itself, so just return the current transition
+ HashSet<TransitionEvent> transitionSet = new HashSet<>();
+ transitionSet.add(currentExecution.getLastTransition());
+ return transitionSet;
+ }
+ return graph.get(stateId);
+ }
+
+ public HashSet<TransitionEvent> getReachableTransitions(int stateId) {
+ HashSet<TransitionEvent> reachableTransitions = new HashSet<>();
+ // All transitions from states higher than the given state ID (until the highest state ID) are reachable
+ for(int stId = stateId; stId <= hiStateId; stId++) {
+ // We might encounter state IDs from the first round of Boolean CG
+ // The second round of Boolean CG should consider these new states
+ if (graph.containsKey(stId)) {
+ reachableTransitions.addAll(graph.get(stId));
+ }
+ }
+ return reachableTransitions;
+ }
+ }
+
// This class compactly stores Read and Write field sets
// We store the field name and its object ID
// Sharing the same field means the same field name and object ID
private class ReadWriteSet {
- private HashMap<String, Integer> readSet;
- private HashMap<String, Integer> writeSet;
+ private HashMap<String, Integer> readMap;
+ private HashMap<String, Integer> writeMap;
public ReadWriteSet() {
- readSet = new HashMap<>();
- writeSet = new HashMap<>();
+ readMap = new HashMap<>();
+ writeMap = new HashMap<>();
}
public void addReadField(String field, int objectId) {
- readSet.put(field, objectId);
+ readMap.put(field, objectId);
}
public void addWriteField(String field, int objectId) {
- writeSet.put(field, objectId);
+ writeMap.put(field, objectId);
+ }
+
+ public void removeReadField(String field) {
+ readMap.remove(field);
+ }
+
+ public void removeWriteField(String field) {
+ writeMap.remove(field);
+ }
+
+ public boolean isEmpty() {
+ return readMap.isEmpty() && writeMap.isEmpty();
+ }
+
+ public ReadWriteSet getCopy() {
+ ReadWriteSet copyRWSet = new ReadWriteSet();
+ // Copy the maps in the set into the new object copy
+ copyRWSet.setReadMap(new HashMap<>(this.getReadMap()));
+ copyRWSet.setWriteMap(new HashMap<>(this.getWriteMap()));
+ return copyRWSet;
}
public Set<String> getReadSet() {
- return readSet.keySet();
+ return readMap.keySet();
}
public Set<String> getWriteSet() {
- return writeSet.keySet();
+ return writeMap.keySet();
}
public boolean readFieldExists(String field) {
- return readSet.containsKey(field);
+ return readMap.containsKey(field);
}
public boolean writeFieldExists(String field) {
- return writeSet.containsKey(field);
+ return writeMap.containsKey(field);
}
public int readFieldObjectId(String field) {
- return readSet.get(field);
+ return readMap.get(field);
}
public int writeFieldObjectId(String field) {
- return writeSet.get(field);
+ return writeMap.get(field);
+ }
+
+ private HashMap<String, Integer> getReadMap() {
+ return readMap;
+ }
+
+ private HashMap<String, Integer> getWriteMap() {
+ return writeMap;
+ }
+
+ private void setReadMap(HashMap<String, Integer> rMap) {
+ readMap = rMap;
+ }
+
+ private void setWriteMap(HashMap<String, Integer> wMap) {
+ writeMap = wMap;
}
}
- // This class compactly stores backtrack points: 1) backtrack state ID, and 2) backtracking choices
- private class BacktrackPoint {
- private IntChoiceFromSet backtrackCG; // CG at this backtrack point
- private int stateId; // State at this backtrack point
- private int choice; // Choice chosen at this backtrack point
+ // This class compactly stores transitions:
+ // 1) CG,
+ // 2) state ID,
+ // 3) choice,
+ // 4) predecessors (for backward DFS).
+ private class TransitionEvent {
+ private int choice; // Choice chosen at this transition
+ private int choiceCounter; // Choice counter at this transition
+ private Execution execution; // The execution where this transition belongs
+ private HashSet<Predecessor> predecessors; // Maps incoming events/transitions (execution and choice)
+ private HashMap<Execution, HashSet<Integer>> recordedPredecessors;
+ // Memorize event and choice number to not record them twice
+ private int stateId; // State at this transition
+ private IntChoiceFromSet transitionCG; // CG at this transition
+
+ public TransitionEvent() {
+ choice = 0;
+ choiceCounter = 0;
+ execution = null;
+ predecessors = new HashSet<>();
+ recordedPredecessors = new HashMap<>();
+ stateId = 0;
+ transitionCG = null;
+ }
- public BacktrackPoint(IntChoiceFromSet cg, int stId, int cho) {
- backtrackCG = cg;
- stateId = stId;
- choice = cho;
+ public int getChoice() {
+ return choice;
}
- public IntChoiceFromSet getBacktrackCG() { return backtrackCG; }
+ public int getChoiceCounter() {
+ return choiceCounter;
+ }
+
+ public Execution getExecution() {
+ return execution;
+ }
+
+ public HashSet<Predecessor> getPredecessors() {
+ return predecessors;
+ }
public int getStateId() {
return stateId;
}
- public int getChoice() {
- return choice;
+ public IntChoiceFromSet getTransitionCG() { return transitionCG; }
+
+ private boolean isRecordedPredecessor(Execution execution, int choice) {
+ // See if we have recorded this predecessor earlier
+ HashSet<Integer> recordedChoices;
+ if (recordedPredecessors.containsKey(execution)) {
+ recordedChoices = recordedPredecessors.get(execution);
+ if (recordedChoices.contains(choice)) {
+ return true;
+ }
+ } else {
+ recordedChoices = new HashSet<>();
+ recordedPredecessors.put(execution, recordedChoices);
+ }
+ // Record the choice if we haven't seen it
+ recordedChoices.add(choice);
+
+ return false;
}
- }
- // This class stores a compact representation of a reachability graph for past executions
- private class ReachabilityGraph {
- private ArrayList<BacktrackPoint> pastBacktrackPointList;
- private HashMap<Integer, ReadWriteSet> pastReadWriteFieldsMap;
+ public void recordPredecessor(Execution execution, int choice) {
+ if (!isRecordedPredecessor(execution, choice)) {
+ predecessors.add(new Predecessor(choice, execution));
+ }
+ }
- public ReachabilityGraph(ArrayList<BacktrackPoint> btrackPointList,
- HashMap<Integer, ReadWriteSet> rwFieldsMap) {
- pastBacktrackPointList = btrackPointList;
- pastReadWriteFieldsMap = rwFieldsMap;
+ public void setChoice(int cho) {
+ choice = cho;
}
- public ArrayList<BacktrackPoint> getPastBacktrackPointList() {
- return pastBacktrackPointList;
+ public void setChoiceCounter(int choCounter) {
+ choiceCounter = choCounter;
}
- public HashMap<Integer, ReadWriteSet> getPastReadWriteFieldsMap() {
- return pastReadWriteFieldsMap;
+ public void setExecution(Execution exec) {
+ execution = exec;
+ }
+
+ public void setPredecessors(HashSet<Predecessor> preds) {
+ predecessors = new HashSet<>(preds);
+ }
+
+ public void setStateId(int stId) {
+ stateId = stId;
+ }
+
+ public void setTransitionCG(IntChoiceFromSet cg) {
+ transitionCG = cg;
}
}
private final static String JAVA_STRING_LIB = "java.lang.String";
// -- FUNCTIONS
- private void fairSchedulingAndBacktrackPoint(IntChoiceFromSet icsCG, VM vm) {
+ private Integer[] copyChoices(Integer[] choicesToCopy) {
+
+ Integer[] copyOfChoices = new Integer[choicesToCopy.length];
+ System.arraycopy(choicesToCopy, 0, copyOfChoices, 0, choicesToCopy.length);
+ return copyOfChoices;
+ }
+
+ private void ensureFairSchedulingAndSetupTransition(IntChoiceFromSet icsCG, VM vm) {
// Check the next choice and if the value is not the same as the expected then force the expected value
int choiceIndex = choiceCounter % refChoices.length;
int nextChoice = icsCG.getNextChoice();
icsCG.setChoice(currCGIndex, expectedChoice);
}
}
- // Record state ID and choice/event as backtrack point
+ // Get state ID and associate it with this transition
int stateId = vm.getStateId();
- backtrackPointList.add(new BacktrackPoint(icsCG, stateId, refChoices[choiceIndex]));
+ TransitionEvent transition = setupTransition(icsCG, stateId, choiceIndex);
+ // Add new transition to the current execution and map it in R-Graph
+ for (Integer stId : justVisitedStates) { // Map this transition to all the previously passed states
+ rGraph.addReachableTransition(stId, transition);
+ }
+ currentExecution.mapCGToChoice(icsCG, choiceCounter);
// Store restorable state object for this state (always store the latest)
- RestorableVMState restorableState = vm.getRestorableState();
- restorableStateMap.put(stateId, restorableState);
+ if (!restorableStateMap.containsKey(stateId)) {
+ RestorableVMState restorableState = vm.getRestorableState();
+ restorableStateMap.put(stateId, restorableState);
+ }
}
- private Integer[] copyChoices(Integer[] choicesToCopy) {
+ private TransitionEvent setupTransition(IntChoiceFromSet icsCG, int stateId, int choiceIndex) {
+ // Get a new transition
+ TransitionEvent transition;
+ if (currentExecution.isNew()) {
+ // We need to handle the first transition differently because this has a predecessor execution
+ transition = currentExecution.getFirstTransition();
+ } else {
+ transition = new TransitionEvent();
+ currentExecution.addTransition(transition);
+ transition.recordPredecessor(currentExecution, choiceCounter - 1);
+ // We have to check if there is a transition whose source state ID is the same
+ // If such exists, then we need to add its predecessors to the predecessor set of the current transition
+ for (TransitionEvent trans : rGraph.getReachableTransitionsAtState(stateId)) {
+ for (Predecessor pred : trans.getPredecessors()) {
+ transition.recordPredecessor(pred.getExecution(), pred.getChoice());
+ }
+ }
+ }
+ transition.setExecution(currentExecution);
+ transition.setTransitionCG(icsCG);
+ transition.setStateId(stateId);
+ transition.setChoice(refChoices[choiceIndex]);
+ transition.setChoiceCounter(choiceCounter);
- Integer[] copyOfChoices = new Integer[choicesToCopy.length];
- System.arraycopy(choicesToCopy, 0, copyOfChoices, 0, choicesToCopy.length);
- return copyOfChoices;
+ return transition;
}
- // --- Functions related to cycle detection
+ // --- Functions related to cycle detection and reachability graph
// Detect cycles in the current execution/trace
// We terminate the execution iff:
// (2) the state has one or more cycles that involve all the events
// With simple approach we only need to check for a re-visited state.
// Basically, we have to check that we have executed all events between two occurrences of such state.
- private boolean containsCyclesWithAllEvents(int stId) {
-
+ private boolean completeFullCycle(int stId) {
// False if the state ID hasn't been recorded
if (!stateToEventMap.containsKey(stId)) {
return false;
choiceCounter = 0;
maxEventChoice = 0;
// Cycle tracking
- currVisitedStates = new HashSet<>();
+ currVisitedStates = new HashMap<>();
justVisitedStates = new HashSet<>();
prevVisitedStates = new HashSet<>();
stateToEventMap = new HashMap<>();
// Backtracking
backtrackMap = new HashMap<>();
backtrackStateQ = new PriorityQueue<>(Collections.reverseOrder());
- backtrackPointList = new ArrayList<>();
- conflictPairMap = new HashMap<>();
- doneBacktrackSet = new HashSet<>();
- readWriteFieldsMap = new HashMap<>();
- stateToChoiceCounterMap = new HashMap<>();
- stateToRGraph = new HashMap<>();
+ currentExecution = new Execution();
+ currentExecution.addTransition(new TransitionEvent()); // Always start with 1 backtrack point
+ doneBacktrackMap = new HashMap<>();
+ rGraph = new RGraph();
// Booleans
isEndOfExecution = false;
}
private boolean terminateCurrentExecution() {
// We need to check all the states that have just been visited
// Often a transition (choice/event) can result into forwarding/backtracking to a number of states
+ boolean terminate = false;
for(Integer stateId : justVisitedStates) {
- if (prevVisitedStates.contains(stateId) || containsCyclesWithAllEvents(stateId)) {
- return true;
+ // We perform updates on backtrack sets for every
+ if (prevVisitedStates.contains(stateId) || completeFullCycle(stateId)) {
+ updateBacktrackSetsFromGraph(stateId);
+ terminate = true;
+ }
+ // If frequency > 1 then this means we have visited this stateId more than once
+ if (currVisitedStates.containsKey(stateId) && currVisitedStates.get(stateId) > 1) {
+ updateBacktrackSetsFromGraph(stateId);
}
}
- return false;
+ return terminate;
}
private void updateStateInfo(Search search) {
// Update the state variables
- // Line 19 in the paper page 11 (see the heading note above)
int stateId = search.getStateId();
// Insert state ID into the map if it is new
if (!stateToEventMap.containsKey(stateId)) {
HashSet<Integer> eventSet = new HashSet<>();
stateToEventMap.put(stateId, eventSet);
}
- stateToChoiceCounterMap.put(stateId, choiceCounter);
- analyzeReachabilityAndCreateBacktrackPoints(search.getVM(), stateId);
+ addPredecessorToRevisitedState(search.getVM(), stateId);
justVisitedStates.add(stateId);
- currVisitedStates.add(stateId);
+ if (!prevVisitedStates.contains(stateId)) {
+ // It is a currently visited states if the state has not been seen in previous executions
+ int frequency = 0;
+ if (currVisitedStates.containsKey(stateId)) {
+ frequency = currVisitedStates.get(stateId);
+ }
+ currVisitedStates.put(stateId, frequency + 1); // Increment frequency counter
+ }
}
// --- Functions related to Read/Write access analysis on shared fields
- private void addNewBacktrackPoint(int stateId, Integer[] newChoiceList) {
+ private void addNewBacktrackPoint(int stateId, Integer[] newChoiceList, TransitionEvent conflictTransition) {
// Insert backtrack point to the right state ID
- LinkedList<Integer[]> backtrackList;
+ LinkedList<BacktrackExecution> backtrackExecList;
if (backtrackMap.containsKey(stateId)) {
- backtrackList = backtrackMap.get(stateId);
+ backtrackExecList = backtrackMap.get(stateId);
} else {
- backtrackList = new LinkedList<>();
- backtrackMap.put(stateId, backtrackList);
+ backtrackExecList = new LinkedList<>();
+ backtrackMap.put(stateId, backtrackExecList);
}
- backtrackList.addFirst(newChoiceList);
+ // Add the new backtrack execution object
+ TransitionEvent backtrackTransition = new TransitionEvent();
+ backtrackTransition.setPredecessors(conflictTransition.getPredecessors());
+ backtrackExecList.addFirst(new BacktrackExecution(newChoiceList, backtrackTransition));
// Add to priority queue
if (!backtrackStateQ.contains(stateId)) {
backtrackStateQ.add(stateId);
}
// Analyze Read/Write accesses that are directly invoked on fields
- private void analyzeReadWriteAccesses(Instruction executedInsn, String fieldClass, int currentChoice) {
+ private void analyzeReadWriteAccesses(Instruction executedInsn, int currentChoice) {
+ // Get the field info
+ FieldInfo fieldInfo = ((JVMFieldInstruction) executedInsn).getFieldInfo();
+ // Analyze only after being initialized
+ String fieldClass = fieldInfo.getFullName();
// Do the analysis to get Read and Write accesses to fields
ReadWriteSet rwSet = getReadWriteSet(currentChoice);
- int objectId = ((JVMFieldInstruction) executedInsn).getFieldInfo().getClassInfo().getClassObjectRef();
+ int objectId = fieldInfo.getClassInfo().getClassObjectRef();
// Record the field in the map
if (executedInsn instanceof WriteInstruction) {
- // Exclude certain field writes because of infrastructure needs, e.g., Event class field writes
- for (String str : EXCLUDED_FIELDS_READ_WRITE_INSTRUCTIONS_STARTS_WITH_LIST) {
- if (fieldClass.startsWith(str)) {
- return;
+ // We first check the non-relevant fields set
+ if (!nonRelevantFields.contains(fieldInfo)) {
+ // Exclude certain field writes because of infrastructure needs, e.g., Event class field writes
+ for (String str : EXCLUDED_FIELDS_READ_WRITE_INSTRUCTIONS_STARTS_WITH_LIST) {
+ if (fieldClass.startsWith(str)) {
+ nonRelevantFields.add(fieldInfo);
+ return;
+ }
}
+ } else {
+ // If we have this field in the non-relevant fields set then we return right away
+ return;
}
rwSet.addWriteField(fieldClass, objectId);
} else if (executedInsn instanceof ReadInstruction) {
return;
}
// We exclude library classes (they start with java, org, etc.) and some more
- String objClassName = eiAccessObj.getClassInfo().getName();
- if (excludeThisForItStartsWith(EXCLUDED_FIELDS_STARTS_WITH_LIST, objClassName) ||
- excludeThisForItStartsWith(EXCLUDED_FIELDS_READ_WRITE_INSTRUCTIONS_STARTS_WITH_LIST, objClassName)) {
+ ClassInfo classInfo = eiAccessObj.getClassInfo();
+ String objClassName = classInfo.getName();
+ // Check if this class info is part of the non-relevant classes set already
+ if (!nonRelevantClasses.contains(classInfo)) {
+ if (excludeThisForItStartsWith(EXCLUDED_FIELDS_READ_WRITE_INSTRUCTIONS_STARTS_WITH_LIST, objClassName) ||
+ excludeThisForItStartsWith(EXCLUDED_FIELDS_STARTS_WITH_LIST, objClassName)) {
+ nonRelevantClasses.add(classInfo);
+ return;
+ }
+ } else {
+ // If it is part of the non-relevant classes set then return immediately
return;
}
// Extract fields from this object and put them into the read write
private int checkAndAdjustChoice(int currentChoice, VM vm) {
// If current choice is not the same, then this is caused by the firing of IntIntervalGenerator
// for certain method calls in the infrastructure, e.g., eventSince()
- int currChoiceInd = currentChoice % refChoices.length;
- int currChoiceFromCG = currChoiceInd;
ChoiceGenerator<?> currentCG = vm.getChoiceGenerator();
// This is the main event CG
if (currentCG instanceof IntIntervalGenerator) {
while (!(parentCG instanceof IntChoiceFromSet)) {
parentCG = ((IntIntervalGenerator) parentCG).getPreviousChoiceGenerator();
}
- int actualEvtNum = ((IntChoiceFromSet) parentCG).getNextChoice();
- // Find the index of the event/choice in refChoices
- for (int i = 0; i<refChoices.length; i++) {
- if (actualEvtNum == refChoices[i]) {
- currChoiceFromCG = i;
- break;
- }
- }
- }
- if (currChoiceInd != currChoiceFromCG) {
- currentChoice = (currentChoice - currChoiceInd) + currChoiceFromCG;
+ // Find the choice related to the IntIntervalGenerator CG from the map
+ currentChoice = currentExecution.getChoiceFromCG((IntChoiceFromSet) parentCG);
}
return currentChoice;
}
- private void createBacktrackingPoint(int currentChoice, int confEvtNum) {
-
+ private void createBacktrackingPoint(Execution execution, int currentChoice,
+ Execution conflictExecution, int conflictChoice) {
// Create a new list of choices for backtrack based on the current choice and conflicting event number
// E.g. if we have a conflict between 1 and 3, then we create the list {3, 1, 0, 2}
// for the original set {0, 1, 2, 3}
+
+ // execution/currentChoice represent the event/transaction that will be put into the backtracking set of
+ // conflictExecution/conflictChoice
Integer[] newChoiceList = new Integer[refChoices.length];
+ ArrayList<TransitionEvent> currentTrace = execution.getExecutionTrace();
+ ArrayList<TransitionEvent> conflictTrace = conflictExecution.getExecutionTrace();
+ int currChoice = currentTrace.get(currentChoice).getChoice();
+ int stateId = conflictTrace.get(conflictChoice).getStateId();
+ // Check if this trace has been done from this state
+ if (isTraceAlreadyConstructed(currChoice, stateId)) {
+ return;
+ }
// Put the conflicting event numbers first and reverse the order
- // We use the actual choices here in case they have been modified/adjusted by the fair scheduling method
- newChoiceList[0] = backtrackPointList.get(currentChoice).getChoice();
- newChoiceList[1] = backtrackPointList.get(confEvtNum).getChoice();
+ newChoiceList[0] = currChoice;
// Put the rest of the event numbers into the array starting from the minimum to the upper bound
- for (int i = 0, j = 2; i < refChoices.length; i++) {
- if (refChoices[i] != newChoiceList[0] && refChoices[i] != newChoiceList[1]) {
+ for (int i = 0, j = 1; i < refChoices.length; i++) {
+ if (refChoices[i] != newChoiceList[0]) {
newChoiceList[j] = refChoices[i];
j++;
}
}
- // Get the backtrack CG for this backtrack point
- int stateId = backtrackPointList.get(confEvtNum).getStateId();
- // Check if this trace has been done starting from this state
- if (isTraceAlreadyConstructed(newChoiceList, stateId)) {
- return;
- }
- addNewBacktrackPoint(stateId, newChoiceList);
+ // Predecessor of the new backtrack point is the same as the conflict point's
+ addNewBacktrackPoint(stateId, newChoiceList, conflictTrace.get(conflictChoice));
}
private boolean excludeThisForItContains(String[] excludedStrings, String className) {
}
private void exploreNextBacktrackPoints(VM vm, IntChoiceFromSet icsCG) {
-
// Check if we are reaching the end of our execution: no more backtracking points to explore
// cgMap, backtrackMap, backtrackStateQ are updated simultaneously (checking backtrackStateQ is enough)
if (!backtrackStateQ.isEmpty()) {
// Set done all the other backtrack points
- for (BacktrackPoint backtrackPoint : backtrackPointList) {
- backtrackPoint.getBacktrackCG().setDone();
+ for (TransitionEvent backtrackTransition : currentExecution.getExecutionTrace()) {
+ backtrackTransition.getTransitionCG().setDone();
}
// Reset the next backtrack point with the latest state
int hiStateId = backtrackStateQ.peek();
icsCG.setDone();
}
// Save all the visited states when starting a new execution of trace
- prevVisitedStates.addAll(currVisitedStates);
- currVisitedStates.clear();
+ prevVisitedStates.addAll(currVisitedStates.keySet());
// This marks a transitional period to the new CG
isEndOfExecution = true;
}
- private ReadWriteSet getReadWriteSet(int currentChoice) {
- // Do the analysis to get Read and Write accesses to fields
- ReadWriteSet rwSet;
- // We already have an entry
- if (readWriteFieldsMap.containsKey(currentChoice)) {
- rwSet = readWriteFieldsMap.get(currentChoice);
- } else { // We need to create a new entry
- rwSet = new ReadWriteSet();
- readWriteFieldsMap.put(currentChoice, rwSet);
- }
- return rwSet;
- }
-
- private boolean isConflictFound(int eventCounter, int currentChoice) {
-
+ private boolean isConflictFound(Execution execution, int reachableChoice, Execution conflictExecution, int conflictChoice,
+ ReadWriteSet currRWSet) {
+ // conflictExecution/conflictChoice represent a predecessor event/transaction that can potentially have a conflict
+ ArrayList<TransitionEvent> executionTrace = execution.getExecutionTrace();
+ ArrayList<TransitionEvent> conflictTrace = conflictExecution.getExecutionTrace();
+ HashMap<Integer, ReadWriteSet> confRWFieldsMap = conflictExecution.getReadWriteFieldsMap();
// Skip if this event does not have any Read/Write set or the two events are basically the same event (number)
- if (!readWriteFieldsMap.containsKey(eventCounter) ||
- backtrackPointList.get(currentChoice).getChoice() == backtrackPointList.get(eventCounter).getChoice()) {
+ if (!confRWFieldsMap.containsKey(conflictChoice) ||
+ executionTrace.get(reachableChoice).getChoice() == conflictTrace.get(conflictChoice).getChoice()) {
return false;
}
- // Current R/W set
- ReadWriteSet currRWSet = readWriteFieldsMap.get(currentChoice);
// R/W set of choice/event that may have a potential conflict
- ReadWriteSet evtRWSet = readWriteFieldsMap.get(eventCounter);
+ ReadWriteSet confRWSet = confRWFieldsMap.get(conflictChoice);
// Check for conflicts with Read and Write fields for Write instructions
Set<String> currWriteSet = currRWSet.getWriteSet();
for(String writeField : currWriteSet) {
int currObjId = currRWSet.writeFieldObjectId(writeField);
- if ((evtRWSet.readFieldExists(writeField) && evtRWSet.readFieldObjectId(writeField) == currObjId) ||
- (evtRWSet.writeFieldExists(writeField) && evtRWSet.writeFieldObjectId(writeField) == currObjId)) {
+ if ((confRWSet.readFieldExists(writeField) && confRWSet.readFieldObjectId(writeField) == currObjId) ||
+ (confRWSet.writeFieldExists(writeField) && confRWSet.writeFieldObjectId(writeField) == currObjId)) {
+ // Remove this from the write set as we are tracking per memory location
+ currRWSet.removeWriteField(writeField);
return true;
}
}
Set<String> currReadSet = currRWSet.getReadSet();
for(String readField : currReadSet) {
int currObjId = currRWSet.readFieldObjectId(readField);
- if (evtRWSet.writeFieldExists(readField) && evtRWSet.writeFieldObjectId(readField) == currObjId) {
+ if (confRWSet.writeFieldExists(readField) && confRWSet.writeFieldObjectId(readField) == currObjId) {
+ // Remove this from the read set as we are tracking per memory location
+ currRWSet.removeReadField(readField);
return true;
}
}
return false;
}
- private boolean isConflictFound(Instruction nextInsn, int eventCounter, int currentChoice, String fieldClass) {
-
- int actualCurrCho = currentChoice % refChoices.length;
- // Skip if this event does not have any Read/Write set or the two events are basically the same event (number)
- if (!readWriteFieldsMap.containsKey(eventCounter) ||
- choices[actualCurrCho] == backtrackPointList.get(eventCounter).getChoice()) {
- return false;
- }
- ReadWriteSet rwSet = readWriteFieldsMap.get(eventCounter);
- int currObjId = ((JVMFieldInstruction) nextInsn).getFieldInfo().getClassInfo().getClassObjectRef();
- // Check for conflicts with Write fields for both Read and Write instructions
- if (((nextInsn instanceof WriteInstruction || nextInsn instanceof ReadInstruction) &&
- rwSet.writeFieldExists(fieldClass) && rwSet.writeFieldObjectId(fieldClass) == currObjId) ||
- (nextInsn instanceof WriteInstruction && rwSet.readFieldExists(fieldClass) &&
- rwSet.readFieldObjectId(fieldClass) == currObjId)) {
- return true;
+ private ReadWriteSet getReadWriteSet(int currentChoice) {
+ // Do the analysis to get Read and Write accesses to fields
+ ReadWriteSet rwSet;
+ // We already have an entry
+ HashMap<Integer, ReadWriteSet> currReadWriteFieldsMap = currentExecution.getReadWriteFieldsMap();
+ if (currReadWriteFieldsMap.containsKey(currentChoice)) {
+ rwSet = currReadWriteFieldsMap.get(currentChoice);
+ } else { // We need to create a new entry
+ rwSet = new ReadWriteSet();
+ currReadWriteFieldsMap.put(currentChoice, rwSet);
}
- return false;
+ return rwSet;
}
- private boolean isFieldExcluded(String field) {
+ private boolean isFieldExcluded(Instruction executedInsn) {
+ // Get the field info
+ FieldInfo fieldInfo = ((JVMFieldInstruction) executedInsn).getFieldInfo();
+ // Check if the non-relevant fields set already has it
+ if (nonRelevantFields.contains(fieldInfo)) {
+ return true;
+ }
+ // Check if the relevant fields set already has it
+ if (relevantFields.contains(fieldInfo)) {
+ return false;
+ }
+ // Analyze only after being initialized
+ String field = fieldInfo.getFullName();
// Check against "starts-with", "ends-with", and "contains" list
if (excludeThisForItStartsWith(EXCLUDED_FIELDS_STARTS_WITH_LIST, field) ||
excludeThisForItEndsWith(EXCLUDED_FIELDS_ENDS_WITH_LIST, field) ||
excludeThisForItContains(EXCLUDED_FIELDS_CONTAINS_LIST, field)) {
+ nonRelevantFields.add(fieldInfo);
return true;
}
-
+ relevantFields.add(fieldInfo);
return false;
}
- private boolean isNewConflict(int currentEvent, int eventNumber) {
- HashSet<Integer> conflictSet;
- if (!conflictPairMap.containsKey(currentEvent)) {
- conflictSet = new HashSet<>();
- conflictPairMap.put(currentEvent, conflictSet);
- } else {
- conflictSet = conflictPairMap.get(currentEvent);
- }
- // If this conflict has been recorded before, we return false because
- // we don't want to save this backtrack point twice
- if (conflictSet.contains(eventNumber)) {
- return false;
- }
- // If it hasn't been recorded, then do otherwise
- conflictSet.add(eventNumber);
- return true;
- }
-
- private boolean isTraceAlreadyConstructed(Integer[] choiceList, int stateId) {
+ // Check if this trace is already constructed
+ private boolean isTraceAlreadyConstructed(int firstChoice, int stateId) {
// Concatenate state ID and only the first event in the string, e.g., "1:1 for the trace 10234 at state 1"
- // TODO: THIS IS AN OPTIMIZATION!
- // This is the optimized version because after we execute, e.g., the trace 1:10234, we don't need to try
- // another trace that starts with event 1 at state 1, e.g., the trace 1:13024
- // The second time this event 1 is explored, it will generate the same state as the first one
- StringBuilder sb = new StringBuilder();
- sb.append(stateId);
- sb.append(':');
- sb.append(choiceList[0]);
// Check if the trace has been constructed as a backtrack point for this state
- if (doneBacktrackSet.contains(sb.toString())) {
- return true;
+ // TODO: THIS IS AN OPTIMIZATION!
+ HashSet<Integer> choiceSet;
+ if (doneBacktrackMap.containsKey(stateId)) {
+ choiceSet = doneBacktrackMap.get(stateId);
+ if (choiceSet.contains(firstChoice)) {
+ return true;
+ }
+ } else {
+ choiceSet = new HashSet<>();
+ doneBacktrackMap.put(stateId, choiceSet);
}
- doneBacktrackSet.add(sb.toString());
+ choiceSet.add(firstChoice);
+
return false;
}
+ // Reset data structure for each new execution
private void resetStatesForNewExecution(IntChoiceFromSet icsCG, VM vm) {
if (choices == null || choices != icsCG.getAllChoices()) {
// Reset state variables
choices = icsCG.getAllChoices();
refChoices = copyChoices(choices);
// Clear data structures
- backtrackPointList = new ArrayList<>();
- conflictPairMap = new HashMap<>();
- readWriteFieldsMap = new HashMap<>();
- stateToChoiceCounterMap = new HashMap<>();
+ currVisitedStates = new HashMap<>();
stateToEventMap = new HashMap<>();
isEndOfExecution = false;
}
}
+ // Set a backtrack point for a particular state
private void setBacktrackCG(int stateId, IntChoiceFromSet backtrackCG) {
// Set a backtrack CG based on a state ID
- LinkedList<Integer[]> backtrackChoices = backtrackMap.get(stateId);
- backtrackCG.setNewValues(backtrackChoices.removeLast()); // Get the last from the queue
+ LinkedList<BacktrackExecution> backtrackExecutions = backtrackMap.get(stateId);
+ BacktrackExecution backtrackExecution = backtrackExecutions.removeLast();
+ backtrackCG.setNewValues(backtrackExecution.getChoiceList()); // Get the last from the queue
backtrackCG.setStateId(stateId);
backtrackCG.reset();
+ // Update current execution with this new execution
+ Execution newExecution = new Execution();
+ TransitionEvent firstTransition = backtrackExecution.getFirstTransition();
+ newExecution.addTransition(firstTransition);
+ // Try to free some memory since this map is only used for the current execution
+ currentExecution.clearCGToChoiceMap();
+ currentExecution = newExecution;
// Remove from the queue if we don't have more backtrack points for that state
- if (backtrackChoices.isEmpty()) {
+ if (backtrackExecutions.isEmpty()) {
backtrackMap.remove(stateId);
backtrackStateQ.remove(stateId);
}
}
+ // Update backtrack sets
+ // 1) recursively, and
+ // 2) track accesses per memory location (per shared variable/field)
+ private void updateBacktrackSet(Execution execution, int currentChoice) {
+ // Copy ReadWriteSet object
+ HashMap<Integer, ReadWriteSet> currRWFieldsMap = execution.getReadWriteFieldsMap();
+ ReadWriteSet currRWSet = currRWFieldsMap.get(currentChoice);
+ if (currRWSet == null) {
+ return;
+ }
+ currRWSet = currRWSet.getCopy();
+ // Memorize visited TransitionEvent object while performing backward DFS to avoid getting caught up in a cycle
+ HashSet<TransitionEvent> visited = new HashSet<>();
+ // Update backtrack set recursively
+ updateBacktrackSetRecursive(execution, currentChoice, execution, currentChoice, currRWSet, visited);
+ }
+
+ private void updateBacktrackSetRecursive(Execution execution, int currentChoice,
+ Execution conflictExecution, int conflictChoice,
+ ReadWriteSet currRWSet, HashSet<TransitionEvent> visited) {
+ // Halt when we have found the first read/write conflicts for all memory locations
+ if (currRWSet.isEmpty()) {
+ return;
+ }
+ TransitionEvent currTrans = execution.getExecutionTrace().get(currentChoice);
+ // Halt when we have visited this transition (in a cycle)
+ if (visited.contains(currTrans)) {
+ return;
+ }
+ visited.add(currTrans);
+ // Explore all predecessors
+ for (Predecessor predecessor : currTrans.getPredecessors()) {
+ // Get the predecessor (previous conflict choice)
+ int predecessorChoice = predecessor.getChoice();
+ Execution predecessorExecution = predecessor.getExecution();
+ // Push up one happens-before transition
+ int newConflictChoice = conflictChoice;
+ Execution newConflictExecution = conflictExecution;
+ // Check if a conflict is found
+ ReadWriteSet newCurrRWSet = currRWSet.getCopy();
+ if (isConflictFound(conflictExecution, conflictChoice, predecessorExecution, predecessorChoice, newCurrRWSet)) {
+ createBacktrackingPoint(conflictExecution, conflictChoice, predecessorExecution, predecessorChoice);
+ newConflictChoice = predecessorChoice;
+ newConflictExecution = predecessorExecution;
+ }
+ // Continue performing DFS if conflict is not found
+ updateBacktrackSetRecursive(predecessorExecution, predecessorChoice, newConflictExecution, newConflictChoice,
+ newCurrRWSet, visited);
+ }
+ }
+
// --- Functions related to the reachability analysis when there is a state match
- // We use backtrackPointsList to analyze the reachable states/events when there is a state match:
- // 1) Whenever there is state match, there is a cycle of events
- // 2) We need to analyze and find conflicts for the reachable choices/events in the cycle
- // 3) Then we create a new backtrack point for every new conflict
- private void analyzeReachabilityAndCreateBacktrackPoints(VM vm, int stateId) {
+ private void addPredecessorToRevisitedState(VM vm, int stateId) {
// Perform this analysis only when:
- // 1) there is a state match,
- // 2) this is not during a switch to a new execution,
- // 3) at least 2 choices/events have been explored (choiceCounter > 1),
- // 4) the matched state has been encountered in the current execution, and
- // 5) state > 0 (state 0 is for boolean CG)
- if (!vm.isNewState() && !isEndOfExecution && choiceCounter > 1 && (stateId > 0)) {
- if (currVisitedStates.contains(stateId)) {
- // Update the backtrack sets in the cycle
- updateBacktrackSetsInCycle(stateId);
- } else if (prevVisitedStates.contains(stateId)) { // We visit a state in a previous execution
- // Update the backtrack sets in a previous execution
- updateBacktrackSetsInPreviousExecution(stateId);
- }
- }
- }
-
- // Save the information from this execution for future reachability analysis
- private void saveExecutionInfo() {
- Set<Integer> states = stateToChoiceCounterMap.keySet();
- ReachabilityGraph reachabilityGraph = new
- ReachabilityGraph(backtrackPointList, readWriteFieldsMap);
- // Map all the states visited in this execution to the same ReachabilityGraph object for fast access
- for(Integer state : states) {
- if (!prevVisitedStates.contains(state)) {
- stateToRGraph.put(state, reachabilityGraph);
- }
- }
- }
-
- // Update the backtrack sets in the cycle
- private void updateBacktrackSetsInCycle(int stateId) {
- // Find the choice/event that marks the start of this cycle: first choice we explore for conflicts
- int conflictChoice = stateToChoiceCounterMap.get(stateId);
- int currentChoice = choiceCounter - 1;
- // Find conflicts between choices/events in this cycle (we scan forward in the cycle, not backward)
- while (conflictChoice < currentChoice) {
- for (int eventCounter = conflictChoice + 1; eventCounter <= currentChoice; eventCounter++) {
- if (isConflictFound(eventCounter, conflictChoice) && isNewConflict(conflictChoice, eventCounter)) {
- createBacktrackingPoint(conflictChoice, eventCounter);
- }
- }
- conflictChoice++;
- }
- }
-
- private int getPastConflictChoice(int stateId, ArrayList<BacktrackPoint> pastBacktrackPointList) {
- // Iterate and find the first occurrence of the state ID
- // It is guaranteed that a choice should be found because the state ID is in the list
- int pastConfChoice = 0;
- for(int i = 0; i<pastBacktrackPointList.size(); i++) {
- BacktrackPoint backtrackPoint = pastBacktrackPointList.get(i);
- int stId = backtrackPoint.getStateId();
- if (stId == stateId) {
- pastConfChoice = i;
- break;
- }
- }
- return pastConfChoice;
- }
-
- // Update the backtrack sets in a previous execution
- private void updateBacktrackSetsInPreviousExecution(int stateId) {
- // Find the right ReachabilityGraph object that contains the stateId
- ReachabilityGraph rGraph = stateToRGraph.get(stateId);
- // Find the choice/event that marks the start of the subtrace from the previous execution
- ArrayList<BacktrackPoint> pastBacktrackPointList = rGraph.getPastBacktrackPointList();
- HashMap<Integer, ReadWriteSet> pastReadWriteFieldsMap = rGraph.getPastReadWriteFieldsMap();
- int pastConfChoice = getPastConflictChoice(stateId, pastBacktrackPointList);
- int conflictChoice = choiceCounter;
- // Iterate from the starting point until the end of the past execution trace
- while (pastConfChoice < pastBacktrackPointList.size() - 1) { // BacktrackPoint list always has a surplus of 1
- // Get the info of the event from the past execution trace
- BacktrackPoint confBtrackPoint = pastBacktrackPointList.get(pastConfChoice);
- ReadWriteSet rwSet = pastReadWriteFieldsMap.get(pastConfChoice);
- // Append this event to the current list and map
- backtrackPointList.add(confBtrackPoint);
- readWriteFieldsMap.put(choiceCounter, rwSet);
- for (int eventCounter = conflictChoice - 1; eventCounter >= 0; eventCounter--) {
- if (isConflictFound(eventCounter, conflictChoice) && isNewConflict(conflictChoice, eventCounter)) {
- createBacktrackingPoint(conflictChoice, eventCounter);
+ // 1) this is not during a switch to a new execution,
+ // 2) at least 2 choices/events have been explored (choiceCounter > 1),
+ // 3) state > 0 (state 0 is for boolean CG)
+ if (!isEndOfExecution && choiceCounter > 1 && stateId > 0) {
+ if ((currVisitedStates.containsKey(stateId) && currVisitedStates.get(stateId) > 1) ||
+ prevVisitedStates.contains(stateId)) {
+ // Update reachable transitions in the graph with a predecessor
+ HashSet<TransitionEvent> reachableTransitions = rGraph.getReachableTransitionsAtState(stateId);
+ for (TransitionEvent transition : reachableTransitions) {
+ transition.recordPredecessor(currentExecution, choiceCounter - 1);
}
}
- // Remove this event to replace it with a new one
- backtrackPointList.remove(backtrackPointList.size() - 1);
- readWriteFieldsMap.remove(choiceCounter);
- pastConfChoice++;
+ }
+ }
+
+ // Update the backtrack sets from previous executions
+ private void updateBacktrackSetsFromGraph(int stateId) {
+ // Collect all the reachable transitions from R-Graph
+ HashSet<TransitionEvent> reachableTransitions = rGraph.getReachableTransitions(stateId);
+ for(TransitionEvent transition : reachableTransitions) {
+ Execution execution = transition.getExecution();
+ int currentChoice = transition.getChoiceCounter();
+ updateBacktrackSet(execution, currentChoice);
}
}
}