---

DSpinTrans.java

package edu.ksu.cis.bandera.dspin;

/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
 * Bandera, a Java(TM) analysis and transformation toolkit           *
 * Copyright (C) 1998, 1999   James Corbett (corbett@hawaii.edu)     *
 * All rights reserved.                                              *
 *                                                                   *
 * This work was done as a project in the SAnToS Laboratory,         *
 * Department of Computing and Information Sciences, Kansas State    *
 * University, USA (http://www.cis.ksu.edu/santos).                  *
 * It is understood that any modification not identified as such is  *
 * not covered by the preceding statement.                           *
 *                                                                   *
 * This work is free software; you can redistribute it and/or        *
 * modify it under the terms of the GNU Library General Public       *
 * License as published by the Free Software Foundation; either      *
 * version 2 of the License, or (at your option) any later version.  *
 *                                                                   *
 * This work is distributed in the hope that it will be useful,      *
 * but WITHOUT ANY WARRANTY; without even the implied warranty of    *
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU *
 * Library General Public License for more details.                  *
 *                                                                   *
 * You should have received a copy of the GNU Library General Public *
 * License along with this toolkit; if not, write to the             *
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,      *
 * Boston, MA  02111-1307, USA.                                      *
 *                                                                   *
 * Java is a trademark of Sun Microsystems, Inc.                     *
 *                                                                   *
 * To submit a bug report, send a comment, or get the latest news on *
 * this project and other SAnToS projects, please visit the web-site *
 *                http://www.cis.ksu.edu/santos                      *
 * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
import Bandera;
import java.io.*;
import java.util.Properties;
import java.util.Vector;
import java.util.StringTokenizer;
import java.util.List;
import java.util.LinkedList;

import edu.ksu.cis.bandera.bir.*;
import edu.ksu.cis.bandera.spin.*;
import edu.ksu.cis.bandera.checker.*;

/**
 * DSpinTrans is the main class of the dSPIN translator, which generates
 * PROMELA source representing a transition system.
 * <p>
 * The dSPIN translator is invoked on a transition system as follows:
 * <pre>
 * // Parameters 
 * TransSystem system = ...;   // the transition system
 * DSpinOptions options = new DSpinOptions();   // SPIN options
 * options.setMemoryLimit(256);            // set various options
 * ...
 * DSpinTrans spin = DSpinTrans.translate(system,options); // invoke translator
 * spin.runSpin();                           // Run SPIN on generated PROMELA
 * BirTrace trace = spin.parseOutput();      // Parse output as BIR trace
 * </pre>
 */

public class DSpinTrans extends AbstractExprSwitch implements BirConstants, Checker
{
    TransSystem system;
    PrintWriter out;
    DSpinTypeName namer;
    int indentLevel = 0;
    boolean inDefine = false;
    boolean newLine = true;
    boolean resetTemp = false;
    boolean resetNew = false;
    Transformation currentTrans;
    int actionNum;
    DSpinOptions options;
    boolean ranVerifier = false;

    static String ccName = "gcc";
    static String includeDir = "";
    static Runtime runtime = Runtime.getRuntime();
    public static final String normal = "NORMAL_CASE";
    
    static final int BUFSIZE = 50000;
    static byte [] buffer = new byte[BUFSIZE];

    static {
        /*
        includeDir = Bandera.getProperty("dspin.include");
        */
    }
    DSpinTrans(TransSystem system, DSpinOptions options, PrintWriter out) {
    this.system = system;
    this.out = out;
    this.namer = new DSpinTypeName();
    this.options = (options == null) ? new DSpinOptions() : options;
    }
    String actionId() {
    int locNum = currentTrans.getFromLoc().getId();
    int transNum = 
        currentTrans.getFromLoc().getOutTrans().indexOf(currentTrans);
    return locNum + " " + transNum + " " + actionNum;
    }
    String actionIdWithCommas() {
    int locNum = currentTrans.getFromLoc().getId();
    int transNum = 
        currentTrans.getFromLoc().getOutTrans().indexOf(currentTrans);
    return locNum + "," + transNum + "," + actionNum;
    }
    CaseNode applyTo(Expr expr) {
    expr.apply(this);
    return (CaseNode) getResult();
    }
    public void caseAddExpr(AddExpr expr)
    {
    translateBinaryOp(expr.getOp1(), expr.getOp2(), " + ");
    }
    public void caseAndExpr(AndExpr expr)
    {
    translateBinaryOp(expr.getOp1(), expr.getOp2(), " && ");
    }
    public void caseArrayExpr(ArrayExpr expr)
    {
    String ref = "";  // Need extra deref for arrays of Refs
    if (expr.getType().isKind(REF))
        ref = ".ref";
    TreeNode arrayTree = applyTo(expr.getArray());
    TreeNode indexTree = applyTo(expr.getIndex());
    TreeNode result = arrayTree.compose(indexTree,null);
    Vector leafCases = result.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        leafCase.insertTrap(leaf.expr2 + " >= " + leaf.expr1 + ".length",
                "ArrayIndexOutOfBoundsException",true);
        leafCase.insertTrap(leaf.expr2 + " < 0",
                "ArrayIndexOutOfBoundsException",true);
        leaf.update(leaf.expr1 + ".elements[" + leaf.expr2 + "]" + ref);
    }
    setResult(result);
    }
    public void caseAssertAction(AssertAction assertAction) {
    CaseNode condTree = (CaseNode) applyTo(assertAction.getCondition());
    Vector leaves = condTree.getLeaves(new Vector());
    for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update("assert(" + leaf.expr1 + ");");
    }
    printStatement(condTree.getCase(normal));
    }
    public void caseAssignAction(AssignAction assign) 
    {
    TreeNode rhsTree = applyTo(assign.getRhs());
    TreeNode lhsTree = applyTo(assign.getLhs());
    CaseNode result = (CaseNode) lhsTree.compose(rhsTree,null);
    Vector leafCases = result.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        Type rhsType = assign.getRhs().getType();
        Type lhsType = assign.getLhs().getType();
        // Make run-time checks on assignment
        if (! rhsType.isSubtypeOf(lhsType)) {

        // Check subrange
        if (lhsType.isKind(RANGE)
            && ! lhsType.containsValue(assign.getRhs())) {
            Range range = (Range) lhsType;
            leafCase.insertTrap(leaf.expr2 + " < " 
                    + range.getFromVal(),
                    "RangeLimitException", false);
            leafCase.insertTrap(leaf.expr2 + " > " 
                    + range.getToVal(),
                    "RangeLimitException", false);
        }

        // Check ref assignment
        if (lhsType.isKind(REF)
            && ! (assign.getRhs() instanceof NullExpr)) {
            String trapDesc = "ClassCastException";
            StateVarVector lhsTargets = ((Ref)lhsType).getTargets();
            StateVarVector rhsTargets = ((Ref)rhsType).getTargets();
            for (int j = 0; j < rhsTargets.size(); j++) 
            if (! lhsTargets.contains(rhsTargets.elementAt(j))) {
                String check = leaf.expr2 + ".refIndex == " +
                refIndex(rhsTargets.elementAt(j));
                leafCase.insertTrap(check,
                        "ClassCastException",true);
            }
        }
        }
        leaf.update(leaf.expr1 + " = " + leaf.expr2 + ";");
    }       
    printStatement(result.getCase(normal));
    }
    public void caseBoolLit(BoolLit expr)
    {
    setResult(specialize("" + expr.getValue()));
    }
    public void caseChooseExpr(ChooseExpr expr)
    {
    Vector choices = expr.getChoices();
    println("if");
    for (int i = 0; i < choices.size(); i++) {
        Expr choice = (Expr) choices.elementAt(i);
        ExprNode leaf = (ExprNode) applyTo(choice).getCase(normal);
        println(":: _temp_ = " + leaf.expr1 + "; printf(\"BIR? " +
            actionNum + " " + i + "\\n\"); ");
    }
    println("fi;");
    resetTemp = true;
    setResult(specialize("_temp_"));        
    }
    public void caseConstant(Constant expr)
    {
    setResult(specialize(expr.getName()));
    }
    public void caseDerefExpr(DerefExpr expr)
    {
    TreeNode result = applyTo(expr.getTarget());
    StateVarVector targets = 
        ((Ref)expr.getTarget().getType()).getTargets();
    Vector leafCases = result.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        CaseNode caseNode = new CaseNode();
        String cond = "(" + leaf.expr1 + " != null)";
        caseNode.addCase(cond, leaf.expr1);
        cond = "(" + leaf.expr1 + " == null)";
        caseNode.addTrapCase(cond,"NullPointerException", true);
        leafCase.replace(caseNode);
    }
    setResult(result);
    }
    public void caseDivExpr(DivExpr expr)
    {   
    TreeNode e1Tree = applyTo(expr.getOp1());
    TreeNode e2Tree = applyTo(expr.getOp2());
    TreeNode result = e1Tree.compose(e2Tree,null);
    Vector leafCases = result.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        leafCase.insertTrap(leaf.expr2 + " == 0",
                "ArithmeticException",true);
        leaf.update("(" + leaf.expr1 + " / " + leaf.expr2 + ")");
    }
    setResult(result);
    }
    public void caseEqExpr(EqExpr expr)
    {
        translateBinaryOp(expr.getOp1(), expr.getOp2(), " == ");
    }
    public void caseInstanceOfExpr(InstanceOfExpr expr)
    {
    TreeNode result = applyTo(expr.getRefExpr());
    StateVarVector targets = expr.getRefType().getTargets();
    Vector leafCases = result.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        CaseNode caseNode = new CaseNode();
        String elseCond = "! (";
        for (int j = 0; j < targets.size(); j++) {
        StateVar target = targets.elementAt(j);
        String cond = "(" + leaf.expr1 + ".refIndex == " 
            + refIndex(target) + ")";
        caseNode.addCase(cond,"1");
        if (j > 0) elseCond += " || ";
        elseCond += cond;
        }
        elseCond += ")";
        caseNode.addCase(elseCond,"0");
        leafCase.replace(caseNode);
    }
    setResult(result);
    }
    public void caseIntLit(IntLit expr)
    {
    setResult(specialize("" + expr.getValue()));
    }
    public void caseLeExpr(LeExpr expr)
    {
        translateBinaryOp(expr.getOp1(), expr.getOp2(), " <= ");
    }
    public void caseLengthExpr(LengthExpr expr)
    {
    TreeNode result = applyTo(expr.getArray());
    Vector leaves = result.getLeaves(new Vector());
    for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update(leaf.expr1 + ".length");
    }
    setResult(result);
    }
    public void caseLockAction(LockAction lockAction) 
    {
    CaseNode lockTree = (CaseNode) applyTo(lockAction.getLockExpr());
    String opName = "_" +  
        LockAction.operationName(lockAction.getOperation());
    if (lockAction.isWait())
        opName += "_" + lockAction.getThread().getId();
    Lock lockType = (Lock) lockAction.getLockExpr().getType();
    if (lockType.isReentrant() 
        && ! lockAction.isLockAction(NOTIFY|NOTIFYALL))
        opName += "_R";
    Vector leaves = lockTree.getLeaves(new Vector());
    for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update(opName + "(" + leaf.expr1 + "," +
            actionIdWithCommas() + ");");
    }
    printStatement(lockTree.getCase(normal));
    }
    public void caseLockTest(LockTest lockTest) {
    TreeNode lockTree;
    Vector leaves;
    switch (lockTest.getOperation()) {
    case LOCK_AVAILABLE:
        String opName = "_lockAvailable";
        if (((Lock)lockTest.getLockExpr().getType()).isReentrant())
        opName += "_R";
        lockTree = applyTo(lockTest.getLockExpr());
        leaves = lockTree.getLeaves(new Vector());
        for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update(opName + "(" + leaf.expr1 + ")");
        }
        setResult(lockTree);
        return;
    case HAS_LOCK:
        setResult(specialize("true"));
        return;
    case WAS_NOTIFIED:
        lockTree = applyTo(lockTest.getLockExpr());
        leaves = lockTree.getLeaves(new Vector());
        for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update("_wasNotified_" + lockTest.getThread().getId() 
                + "(" + leaf.expr1 + ")");
        }
        setResult(lockTree);
        return;     
    }   
    }
    public void caseLtExpr(LtExpr expr)
    {
        translateBinaryOp(expr.getOp1(), expr.getOp2(), " < ");
    }
    public void caseMulExpr(MulExpr expr)
    {
    translateBinaryOp(expr.getOp1(), expr.getOp2(), " * ");
    }
    public void caseNeExpr(NeExpr expr)
    {
        translateBinaryOp(expr.getOp1(), expr.getOp2(), " != ");
    }
    public void caseNewArrayExpr(NewArrayExpr expr)
    {
    Collection colType =  (Collection)expr.getCollection().getType();
    Array arrayType = (Array)colType.getBaseType();
    String arrayTypeName = dSpinTypeName(arrayType,null);
    Type baseType = arrayType.getBaseType();
    String baseTypeName = dSpinTypeName(baseType,null);
    if (baseType.isKind(REF)) 
        baseTypeName = baseTypeName.substring(0,baseTypeName.length() - 4)
        + "_aref";
    int refIndex = refIndex(expr.getCollection());
    CaseNode setLength = applyTo(expr.getLength());
    Vector leafCases = setLength.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        leaf.update("_temp_ = " + leaf.expr1 + ";");
    }
    printStatement(setLength.getCase(normal));
    resetTemp = true;
    println("_new_ = new " + arrayTypeName + ";");
    println("_new_.refIndex = " + refIndex + ";");
    println("_new_.length = _temp_;");
    println("_new_.elements = new " + baseTypeName + "[_temp_];");
    println("printf(\"BIR? " + actionNum + " %d\\n\",_temp_); ");
    resetNew = true;
    setResult(specialize("_new_"));
    }
    public void caseNewExpr(NewExpr expr)
    {
    Type type = ((Collection)expr.getCollection().getType()).getBaseType();
    String typeName = dSpinTypeName(type,null);
    println("_new_ = new " + typeName + ";");
    println("_new_.refIndex = " + refIndex(expr.getCollection()) + ";");
    resetNew = true;
    setResult(specialize("_new_"));
    }
    public void caseNotExpr(NotExpr expr)
    {
    translateUnaryOp(expr.getOp(),"! ");
    }
    public void caseNullExpr(NullExpr expr)
    {
        setResult(specialize("null"));
    }
    public void caseOrExpr(OrExpr expr)
    {
    translateBinaryOp(expr.getOp1(), expr.getOp2(), " || ");
    }
    public void casePrintAction(PrintAction printAction) {
    // Perhaps remove this---get output from BIR trace instead
    if (printAction.getPrintItems().size() > 0) {
        String format = "BIR|";
        String params = "";
        Vector printItems = printAction.getPrintItems();
        for (int i = 0; i < printItems.size(); i++) {
        Object item = printItems.elementAt(i);
        if (item instanceof String)
            format += item;
        else {
            format += "%d";
            CaseNode varTree = (CaseNode) applyTo((Expr)item);
            params += "," + ((ExprNode)varTree.getCase(normal)).expr1;
        }
        }
        println("printf(\"" + format + "\\n\"" + params + "); ");
    }
    }
    public void caseRecordExpr(RecordExpr expr)
    {
    TreeNode result = applyTo(expr.getRecord());
    String field = expr.getField().getName();
    Vector leaves = result.getLeaves(new Vector());
    for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update(leaf.expr1 + "." + field);
    }
    setResult(result);
    }
    public void caseRefExpr(RefExpr expr)
    {
    setResult(specialize("& " + expr.getTarget().getName()));
    }
    public void caseRemExpr(RemExpr expr)
    {   
    TreeNode e1Tree = applyTo(expr.getOp1());
    TreeNode e2Tree = applyTo(expr.getOp2());
    TreeNode result = e1Tree.compose(e2Tree,null);
    Vector leafCases = result.getLeafCases(new Vector());
    for (int i = 0; i < leafCases.size(); i++) {
        Case leafCase = (Case) leafCases.elementAt(i);
        ExprNode leaf = (ExprNode) leafCase.node;
        leafCase.insertTrap(leaf.expr2 + " == 0",
                "ArithmeticException",true);
        leaf.update("(" + leaf.expr1 + " % " + leaf.expr2 + ")");
    }
    setResult(result);
    }
    public void caseStateVar(StateVar expr)
    {
    setResult(specialize(expr.getName()));
    }
    public void caseSubExpr(SubExpr expr)
    {
    translateBinaryOp(expr.getOp1(), expr.getOp2(), " - ");
    }
    public void caseThreadAction(ThreadAction threadAction) 
    {
    String opName = 
        ThreadAction.operationName(threadAction.getOperation());
    int threadId = threadAction.getThreadArg().getId();
    println("_" + opName + "Thread_" + threadId + ";");
    }
    public void caseThreadLocTest(ThreadLocTest threadLocTest) {
    String threadName = threadLocTest.getThread().getName();
    int threadId = 1 + threadLocTest.getThread().getId();
    String locLabel = locLabel(threadLocTest.getLocation());
    String test = threadName + "[" + threadId + "]@" + locLabel;
    setResult(specialize(test));
    }
    public void caseThreadTest(ThreadTest threadTest) {
    switch (threadTest.getOperation()) {
    case THREAD_TERMINATED:
        String opName = 
        ThreadTest.operationName(threadTest.getOperation());
        int threadId = threadTest.getThreadArg().getId();
        String test = "_" + opName + "_" + threadId;
        setResult(specialize(test));
        return;
    }   
    }
    public String check() { return runSpin(); }
    static String currentDir() { return System.getProperty("user.dir"); }
    public void defaultCase(Object obj)
    {
    throw new RuntimeException("Trans type not handled: " + obj);
    }
    void definitions() {
    Vector definitions = system.getDefinitions();
    for (int i = 0; i < definitions.size(); i++) {
        Definition def = (Definition) definitions.elementAt(i);
        if (def instanceof Constant) 
        println("#define " + def.getName() + " " + def.getDef());
    }
    Vector types = system.getTypes();
    for (int i = 0; i < types.size(); i++) {
        Type type = (Type) types.elementAt(i);
        if (type.isKind(BOOL|RANGE|LOCK|ENUMERATED|REF)) {
        println("/* " + type.typeName() + " = " + type + " */");
        print("#define " + type.typeName() + " ");
        println(dSpinTypeName(type,this));
        if (type.isKind(ENUMERATED)) {
            Enumerated enum = (Enumerated) type;
            for (int j = 0; j < enum.getEnumeratedSize(); j++) {
            String name = enum.getNameOf(enum.getFirstElement()+j);
            if (name != null)
                println("#define " + name + " " + 
                    (enum.getFirstElement()+j));
            }
        }
        println();
        }
        if (type.isKind(RECORD|ARRAY)) {
        println("typedef " + type.typeName() + ";");
        println();
        }
    }
    for (int i = 0; i < types.size(); i++) {
        Type type = (Type) types.elementAt(i);
        if (type.isKind(REF)) {
        String refRoot = 
            type.typeName().substring(0,type.typeName().length() - 4);
        println("typedef " + refRoot + "_aref { " +
            type.typeName() + " ref; }");
        println();
        }
    }
    for (int i = 0; i < types.size(); i++) {
        Type type = (Type) types.elementAt(i);
        if (! type.isKind(BOOL|RANGE|LOCK|ENUMERATED|REF|COLLECTION)) {
        println("/* " + type.typeName() + " = " + type + " */");
        print("typedef " + type.typeName() + " ");
        println(dSpinTypeName(type,this));
        println();
        }
    }
    println();
    }
    String dSpinTypeName(Type type, Object o) {
    type.apply(namer,o);
    return (String) namer.getResult();
    }
    String execAndWait(String command, boolean verbose) {
    try {
        if (verbose)
        System.out.println(command);
        Process p = runtime.exec(command);
        InputStream commandErr = p.getErrorStream();
        InputStream commandOut = p.getInputStream();
        int count = 0;       // total chars read
        int charsRead = 0;   // chars read on read
        int charsAvail = 0;  // chars available
        while ((count < BUFSIZE) && (charsRead >= 0)) {
        charsAvail = commandErr.available();
        if (charsAvail > 0) 
            count += commandErr.read(buffer,count,charsAvail);
        charsRead = commandOut.read(buffer,count,BUFSIZE - count);
        if (charsRead > 0)
            count += charsRead;
        }
        p.waitFor();
        String output = new String(buffer,0,count);
        if (verbose && count > 0)
        System.out.println(output);
        return output;
    }
    catch (Exception e) {
        throw new RuntimeException("exec of command '" + command
                       + "' was aborted: \n" + e);
    }
    }
/**
 * getCounterExample method comment.
 */
public List getCounterExample() {
    return null;
}
    public DSpinOptions getDSpinOptions() { return options; }
    String getSimpleResult() {
    TreeNode result = ((CaseNode)getResult()).getCase(normal);
    if (result instanceof ExprNode) 
        return ((ExprNode)result).expr1;
    else
        throw new RuntimeException("Result not simple: " + result);
    }
    boolean guardPresent(Transformation trans) {
    Expr guard = trans.getGuard();
    if (guard == null)
        return false;
    if (guard instanceof BoolLit)
        return ! ((BoolLit)guard).getValue();
    if ((guard instanceof LockTest) 
        && ((LockTest)guard).getOperation() == HAS_LOCK)
        return false;
    return true;
    }
    void header() {
    ThreadVector threadVector = system.getThreads();

    println("/*  (dSPIN) Promela for transition system: " 
            + system.getName() + " */");
    println();

    // Lock types (R = reentrant, W = waiting)
    println("/* Lock operations */");
    println("typedef lock_ {\n  byte owner;\n};");
    println("typedef lock_W {\n  byte owner;\n  int waiting;\n};");
    println("typedef lock_R {\n  byte count;\n  byte owner;\n};");
    println("typedef lock_RW {\n  byte count;\n  byte owner;\n  int waiting;\n};");

        // Monitor operations - most have separate reentrant version (_R)
    println("#define _lock(sync,locNum,transNum,actionNum) \\");
    println("  sync.owner = _pid ");
    println("#define _lock_R(sync,locNum,transNum,actionNum) \\");
    println("  if \\");
        println("  :: sync.owner == _pid -> sync.count++; \\");
    println("  :: else -> sync.owner = _pid; \\");
    println("  fi ");

    println("#define _unlock(sync,locNum,transNum,actionNum) \\");
    println("  sync.owner = 0 ");
    println("#define _unlock_R(sync,locNum,transNum,actionNum) \\");
    println("  if \\");
        println("  :: sync.count > 0 -> sync.count--; \\");
    println("  :: else -> sync.owner = 0; \\");
    println("  fi ");

    println("#define _lockAvailable(sync) \\");
    println("  (sync.owner == 0)");
    println("#define _lockAvailable_R(sync) \\");
    println("  (sync.owner == 0 || sync.owner == _pid) ");

    println("#define _unwait(sync,locNum,transNum,actionNum) \\");
    println("  sync.owner = _pid ");
    println("#define _unwait_R(sync,locNum,transNum,actionNum) \\");
    println("  sync.owner = _pid; sync.count = _temp_; _temp_ = 0 ");

    println("#define _notifyAll(sync,locNum,transNum,actionNum) \\");
    println("  if \\");
        println("  :: sync.owner == _pid -> sync.waiting = 0; \\");
    println("  :: else -> printf(\"BIR: locNum transNum actionNum IllegalMonitorStateException\"); assert(0); \\");
    println("  fi ");

    println("#define _notify(sync,locNum,transNum,actionNum) \\");
    println("  if \\");
    for (int i = 0; i < threadVector.size(); i++) {
        int thread = (1 << i);
        println("  :: (sync.owner == _pid) && (sync.waiting & " + thread + ") -> sync.waiting = sync.waiting & " + ~ thread + " ; printf(\"BIR? %d " + i + "\",actionNum); \\");
    }
    println("  :: (sync.owner == _pid) && (sync.waiting == 0) -> printf(\"BIR? %d " + threadVector.size() + "\\n\",actionNum); \\");
    println("  :: else -> printf(\"BIR: locNum transNum actionNum IllegalMonitorStateException\"); assert(0); \\");
    println("  fi  ");

    for (int i = 0; i < threadVector.size(); i++) {
        int thread = (1 << i);

        println("#define _wait_" + i + "(sync,locNum,transNum,actionNum) \\");
        println("  if \\");
        println("  :: sync.owner == _pid -> sync.waiting = sync.waiting | " + thread + ";  \\");
        println("       sync.owner = 0; \\");
        println("  :: else -> printf(\"BIR: locNum transNum actionNum IllegalMonitorStateException\"); assert(0); \\");
        println("  fi ");
        println("#define _wait_" + i + "_R(sync,locNum,transNum,actionNum) \\");
        println("  if \\");
        println("  :: sync.owner == _pid -> sync.waiting = sync.waiting | " + thread + ";  \\");
        println("       _temp_ = sync.count; sync.count = 0; sync.owner = 0; \\");
        println("  :: else -> printf(\"BIR: locNum transNum actionNum IllegalMonitorStateException\"); assert(0); \\");
        println("  fi ");

        println("#define _wasNotified_" + i + "(sync) \\");
        println("  !(sync.waiting & " + thread + ") ");
        
        if (! threadVector.elementAt(i).isMain()) {
        println("#define _startThread_" + i + " \\");
        println("  _threadActive_" + i + " = 1; _threadStart_" + 
                i + "!ready");
        println("#define _beginThread_" + i + " \\");
        println("  _threadStart_" + i + "?ready");
        println("#define _joinThread_" + i + " \\");
        println("  skip");
        println("#define _exitThread_" + i + " \\");
        println("  _threadActive_" + i + " = 0; goto endtop_"  + i);
        println("#define _threadTerminated_" + i + " \\");
        println("  (_threadActive_" + i + " == 0)");
        }
    }
    
    println("typedef object {\n  byte refIndex;\n  byte length; object& elements\n};");
    println("#define TRAP 1");
    println("mtype { ready };");
    println();
    }
    void initBlock() {
    ThreadVector threadVector = system.getThreads();
    println("init {");
    indentLevel = 2;
    println("atomic {");
    indentLevel++;
    StateVarVector stateVarVector = system.getStateVars();
    DSpinTypeInit initializer = new DSpinTypeInit(this,out);
    for (int i = 0; i < stateVarVector.size(); i++) {
        StateVar var = stateVarVector.elementAt(i);
        var.getType().apply(initializer,var);
    }
    for (int i = 0; i < threadVector.size(); i++) {
        BirThread thread = threadVector.elementAt(i);
        println("assert(run " + thread.getName() + "() == " +
            (1 + thread.getId()) + ");");
    }
    indentLevel--;
    println("}");
    println("assert(! limit_exception);");
    indentLevel = 0;
    println("}");
    }
    boolean isIfBranch(TransVector outTrans) {
    if (outTrans.size() != 2) 
        return false;
    Expr guard1 = outTrans.elementAt(0).getGuard();
    Expr guard2 = outTrans.elementAt(1).getGuard();
    if (guard1 == null || guard2 == null) 
        return false;
    if ((guard1 instanceof NotExpr) 
        && ((NotExpr)guard1).getOp().equals(guard2))
        return true;
    if ((guard2 instanceof NotExpr) 
        && ((NotExpr)guard2).getOp().equals(guard1))
        return true;
    return false;
    }
    static String locLabel(Location loc) {
    if (loc.getOutTrans().size() == 0)
        return "endloc_" + loc.getId();
    else
        return "loc_" + loc.getId();
    }
    static String locLabel(Location loc1, int branch, Location loc2) {
    return "loc_" + loc1.getId() + "_" + branch + "_" + loc2.getId();
    }
    boolean nonNegative(Expr expr) {
    if (expr instanceof ConstExpr) 
        return ((ConstExpr)expr).getValue() >= 0;
    if (expr.getType() instanceof Range) {
        Range type = (Range) expr.getType();
        return (type.getFromVal().getValue() >= 0);
    }
    return false;
    }
    static int parseInt(String s) {
    try {
        int result = Integer.parseInt(s);
        return result;
    } catch (NumberFormatException e) {
        throw new RuntimeException("Integer didn't parse: " + s);
    }
    }
    void parseLine(String line, BirTrace trace) {
    int pos = line.indexOf("BIR:");
    if (pos >= 0) {
        StringTokenizer st = 
        new StringTokenizer(line.substring(pos + 4));
        int locId = parseInt(st.nextToken());
        int transNum = parseInt(st.nextToken());
        int actionNum = parseInt(st.nextToken());
        String status = st.nextToken();
        Location loc = system.getLocation(locId);
        Transformation trans = 
        loc.getOutTrans().elementAt(transNum);
        if (status.equals("OK")) {
        if (actionNum == 1)
            trace.addTrans(trans);
        }
        else
        trace.setTrap(status,trans,actionNum);
        return;
    }
    pos = line.indexOf("BIR?");
    if (pos >= 0) {
        StringTokenizer st = 
        new StringTokenizer(line.substring(pos + 4));
        int actionNum = parseInt(st.nextToken());
        int choiceNum = parseInt(st.nextToken());
        trace.setChoice(actionNum,choiceNum);
    }
    }
    /**
     * Parse the output of 'pan' and interpret it as either a violation 
     * (sequence of transformations) or as a error-free analysis.
     * <p>
     * @return a vector of transformations (if there was an error found), or null (otherwise)
     */

    public BirTrace parseOutput() {
    if (! ranVerifier) 
        throw new RuntimeException("Did not run verifier on input");
    try {
            File sourceFile = new File(currentDir(), 
                       system.getName() + ".dprom");
            File trailFile = new File(currentDir(), 
                      system.getName() + ".dprom.trail");
        BirTrace trace = new BirTrace(system);
        // We use the presence of the trail file to detect success/failure
        if (! trailFile.exists()) {
        trace.setVerified(true);   // property verified
        return trace;
        }
        String output = 
        execAndWait("dspin -t " + sourceFile.getAbsolutePath(), true);
        BufferedReader reader = 
        new BufferedReader(new StringReader(output));
        String line = reader.readLine();
        while (line != null) {
        parseLine(line,trace);
        line = reader.readLine();
        }
        trace.done();
        trace.setVerified(false);
        return trace;
        } catch(IOException e) {
            throw new RuntimeException("Error parsing dSPIN output: \n" + e);
        }   
    }
    void predicates() {
    println("/* Predicates */");
    Vector preds = system.getPredicates();
    for (int i = 0; i < preds.size(); i++) {
        Expr pred = (Expr) preds.elementAt(i);
        String name = system.predicateName(pred);
        inDefine = true;
        println("#define " + name + " ");
        indentLevel = 1;
        printGuard(applyTo(pred).getCase(normal));
        inDefine = false;
        println("");
        indentLevel = 0;
    }
    println("");
    }
    void print(String s) {
    if (newLine) {
        for (int i = 0; i < indentLevel; i++)
        out.print("   ");
        newLine = false;
    }
    out.print(s);
    }
    void printGuard(TreeNode tree) {
    if (tree instanceof ExprNode) {
        ExprNode node = (ExprNode) tree;
        print(node.expr1);
    }
    else if (tree instanceof TrapNode) {
        TrapNode node = (TrapNode) tree;
        print("TRAP");
    }
    else {
        CaseNode node = (CaseNode) tree;
        print("(  ");
        for (int i = 0; i < node.size(); i++) {
        Case c = node.elementAt(i);
        indentLevel++;
        println("(  " + c.cond);
        print("&& ");
        indentLevel++;
        printGuard(c.node);
        indentLevel--;
        print(" )");
        indentLevel--;
        if (i < node.size() - 1) {
            println();
            print("|| ");
        }
        }
        println(" )");
    }
    }
    void println() {
    if (inDefine)
        out.print("\\");
    out.println();
    newLine = true;
    }
    void println(String s) {
    print(s);
    println();
    }
    void printStatement(TreeNode tree) {
    if (tree instanceof ExprNode) {
        ExprNode node = (ExprNode) tree;
        println(node.expr1);
    }
    else if (tree instanceof TrapNode) {
        TrapNode node = (TrapNode) tree;
        print("   printf(\"BIR: " + actionId() 
          + " " + node.desc + "\\n\"); ");
        if (node.fatal)
        println("assert(0);");
        else
        println("limit_exception = 1; goto endtrap;");
    }
    else {
        CaseNode node = (CaseNode) tree;
        println("if ");
        for (int i = 0; i < node.size(); i++) {
        Case c = node.elementAt(i);
        String cond = (i < node.size() - 1) ? c.cond : "else";
        println(":: " + cond + " -> ");
        indentLevel++;
        printStatement(c.node);
        indentLevel--;
        }
        println("fi; ");
    }   
    }
    void property() {
    if (options.ApplyNeverClaim)
        println("#include \"" + system.getName() + ".never\"");
    }
    int refIndex(StateVar target) {
    return 1 + system.refAnyType().getTargets().indexOf(target);
    }
    void resetDeadVariables(Location fromLoc, Location toLoc) {
    StateVarVector liveBefore = fromLoc.getLiveVars();
    StateVarVector liveAfter = toLoc.getLiveVars();
    if (liveBefore != null && liveAfter!= null) 
        for (int i = 0; i < liveBefore.size(); i++) 
        if (liveAfter.indexOf(liveBefore.elementAt(i)) == -1) {
            // var was live, now is not---reset it
            StateVar var = liveBefore.elementAt(i);
            var.apply(this);
            print(getSimpleResult() + " = ");
            var.getInitVal().apply(this);
            println(getSimpleResult() + ";");
        }
    }
    DSpinTrans run() {
    header();
    definitions();
    stateVariables();
    transitions();
    predicates();
    property();
    return this;
    }
    /**
     * Run SPIN to generate an analyzer (pan), and then run the analyzer.
     * <p>
     * The translator must have been executed for the transition system
     * (the file NAME.dprom must exist and contain the translated PROMELA).
     * @return the output of 'pan' (as a String)
     */

    public String runSpin() {
    try {
        if (options.ApplyNeverClaim) {
        File ltlFile = new File(currentDir(), 
                       system.getName() + ".spin.ltl");
        if (! ltlFile.exists())
            throw new RuntimeException("Cannot find LTL file: " +
                           ltlFile.getAbsolutePath());
        String neverClaim = 
            execAndWait("spin -F " + ltlFile.getAbsolutePath(), true);
        File neverFile = new File(currentDir(), 
                      system.getName() + ".never");
        FileOutputStream streamOut = new FileOutputStream(neverFile);
        PrintWriter writerOut = new PrintWriter(streamOut);
        writerOut.println(neverClaim);
        writerOut.close();
        }
            File sourceFile = new File(currentDir(), 
                       system.getName() + ".dprom");
        if (! sourceFile.exists())
        throw new RuntimeException("Cannot find dSPIN source file: " +
                       sourceFile.getAbsolutePath());
            File trailFile = new File(currentDir(), 
                      system.getName() + ".dprom.trail");
        if (trailFile.exists())
        trailFile.delete();
        File panFile = new File(currentDir(), 
                    "pan.exe");
        execAndWait("dspin -a " + sourceFile.getAbsolutePath(), true);
        execAndWait(ccName + " " + options.compileOptions() +
            " -o pan.exe -I " + includeDir + " pan.c", true);
        ranVerifier = true;
        return execAndWait(panFile.getCanonicalPath() + " " +
                   options.panOptions(), true);
        
        } catch(Exception e)
        {
            throw new RuntimeException("Could not produce SPIN file (" + e + ")");
        }   
    }
    TreeNode specialize(String expr) {
    return new CaseNode(new Case(normal, new ExprNode(expr)));
    }
    void stateVariables() {
    println("bool limit_exception = 0;");
    println("byte _i_ = 0;");
    println("object& _new_;");
    ThreadVector threads = system.getThreads();
    for (int i = 0; i < threads.size(); i++) {
        if (! threads.elementAt(i).isMain()) {
        println("chan _threadStart_" + i + " = [1] of { bit };");
        println("bit _threadActive_" + i + ";");
        }
    }
    println();
    StateVarVector stateVarVector = system.getStateVars();
    for (int i = 0; i < stateVarVector.size(); i++) {
        StateVar var = stateVarVector.elementAt(i);
        String refIndex = "   ";
        if (var.getType().isKind(COLLECTION)) 
        println("/* Collection: " + var.getName() + ", ref index = "
            + refIndex(var) + " */");
        else {
        if (var.getType().isKind(RECORD|ARRAY))
            refIndex += "/*  ref index = " + refIndex(var) + " */";
        println(dSpinTypeName(var.getType(),null) + " " 
            + var.getName() + ";" + refIndex);
        }
    }
    println();
    }
    void transitions() {
    ThreadVector threadVector = system.getThreads();
    for (int i = 0; i < threadVector.size(); i++) {
        BirThread thread = threadVector.elementAt(i);
        println("proctype " + thread.getName() + "() { ");
        println("  int _temp_;");
        if (! thread.isMain()) 
        println("endtop_" + i + ":\n   _beginThread_" + i + ";");
        LocVector threadLocVector = thread.getLocations();
        for (int j = 0; j < threadLocVector.size(); j++) 
        translateLocation(threadLocVector.elementAt(j));
        println("endtrap:");
        println("  0;");
        println("}");
        println();
    }
    initBlock();
    }
    /**
     * Generate PROMELA source representing a transition system.
     * <p>
     * As above, but with default options.
     * @param system the transition system
     * @return the DSpinTrans control object
     */

    public static DSpinTrans translate(TransSystem system) {
    return translate(system,null);
    }
    /**
     * Generate PROMELA source representing a transition system.
     * <p>
     * The PROMELA is written to a file NAME.dprom where NAME
     * is the name of the transition system.  A set of
     * options can be provided in a DSpinOptions object.
     * @param system the transition system
     * @param options the SPIN verifier options
     * @return the SpinTrans control object
     */

    public static DSpinTrans translate(TransSystem system, 
                       DSpinOptions options) {
    try {
            File sourceFile = new File(currentDir(), 
                       system.getName() + ".dprom");

            FileOutputStream streamOut = new FileOutputStream(sourceFile);
            PrintWriter writerOut = new PrintWriter(streamOut);
        DSpinTrans result = translate(system, options, writerOut);
            writerOut.close();
        return result;
        } catch(IOException e)
        {
            throw new RuntimeException("Could not produce dSPIN file: " + e);
        }
    }
    /**
     * Generate PROMELA source representing a transition system.
     * <p>
     * As above, but the PROMELA is written to the PrintWriter provided.
     * @param system the transition system
     * @param out the PrintWriter to write the PROMELA to
     * @return the DSpinTrans control object
     */

    public static DSpinTrans translate(TransSystem system, 
                       DSpinOptions options,
                       PrintWriter out) {
    return (new DSpinTrans(system,options,out)).run();
    }
    void translateBinaryOp(Expr e1, Expr e2, String op) {
    TreeNode e1Tree = applyTo(e1);
    TreeNode e2Tree = applyTo(e2);
    TreeNode result = e1Tree.compose(e2Tree,null);
    Vector leaves = result.getLeaves(new Vector());
    for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update("(" + leaf.expr1 + op + leaf.expr2 + ")");
    }
    setResult(result);
    }
    public void translateLocation(Location loc)
    {
    if (! loc.isVisible())
        return;
    println(locLabel(loc) + ":");
    indentLevel++;
    TransVector outTrans = loc.getOutTrans();
    if (outTrans.size() == 1) 
        translateSequence(outTrans.elementAt(0),0);
    else if (outTrans.size() == 0)  
        println("0;");
    else {
        println("if");
        for (int i = 0;  i < outTrans.size(); i++) {
        print(":: ");
        indentLevel++;
        translateSequence(outTrans.elementAt(i),i);
        indentLevel--;
        }
        println("fi;");
    }
    indentLevel--;
    }
    void translateSeq(LocVector locSet, Transformation trans, 
              int branch, boolean supressGuard) {
    translateTrans(trans, supressGuard);
    if (trans.getToLoc().isVisible()) {
        resetDeadVariables(locSet.firstElement(), trans.getToLoc());
        println("goto " + locLabel(trans.getToLoc()) + ";");
    }
    else if (locSet.contains(trans.getToLoc()))
        println("goto " + 
            locLabel(locSet.firstElement(),branch,trans.getToLoc()) 
            + ";");
    else {
        locSet.addElement(trans.getToLoc());
        if (trans.getToLoc().getInTrans().size() > 1)
        println(locLabel(locSet.firstElement(),branch,trans.getToLoc())
            + ":");
        TransVector successors = trans.getToLoc().getOutTrans();
        if (successors.size() == 1) 
        translateSeq(locSet, successors.elementAt(0), branch,false);
        else if (isIfBranch(successors)) {
        println("if");
        print(":: ");
        indentLevel++;
        translateSeq(locSet, successors.elementAt(0), branch, false);
        indentLevel--;
        print(":: else -> ");
        indentLevel++;
        translateSeq(locSet, successors.elementAt(1), branch, true);
        indentLevel--;
        println("fi;");
        }
        else {
        println("if");
        for (int i = 0; i < successors.size(); i++) {
            print(":: ");
            indentLevel++;
            translateSeq(locSet, successors.elementAt(i),branch,false);
            indentLevel--;
        }
        println("fi;");
        }       
    }
    }
    void translateSequence(Transformation trans, int branch) {
    Location startLoc = trans.getFromLoc();
        println("atomic { ");
    indentLevel++;
    translateSeq(new LocVector(startLoc), trans, branch, false);
    indentLevel--;
    println("}");
    }
    void translateTrans(Transformation trans, boolean supressGuard)
    {
    currentTrans = trans;
    actionNum = 0;
    if (! supressGuard && guardPresent(trans)) {
        printGuard(applyTo(trans.getGuard()).getCase(normal));
        println("-> ");
    }
    ActionVector actions = trans.getActions();
    for (int i = 0; i < actions.size(); i++) {
        actionNum = i + 1;
        println("printf(\"BIR: " + actionId() + " OK\\n\"); ");
        actions.elementAt(i).apply(this);
    }
    if (resetTemp) {
        println("_temp_ = 0;");
        resetTemp = false;
    }
    if (resetNew) {
        println("_new_ = null;");
        resetNew = false;
    }
    }
    void translateUnaryOp(Expr e, String op) {
    TreeNode result = applyTo(e);
    Vector leaves = result.getLeaves(new Vector());
    for (int i = 0; i < leaves.size(); i++) {
        ExprNode leaf = (ExprNode) leaves.elementAt(i);
        leaf.update("(" + op + leaf.expr1 + ")");
    }
    setResult(result);
    }
}

---