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Rhino is an open-source implementation of JavaScript written entirely in Java. It is typically embedded into Java applications to provide scripting to end users.

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/* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

package org.mozilla.javascript.optimizer;

import java.io.PrintWriter;
import java.io.StringWriter;
import java.util.BitSet;
import java.util.HashMap;
import java.util.Map;

import org.mozilla.javascript.Node;
import org.mozilla.javascript.ObjArray;
import org.mozilla.javascript.ObjToIntMap;
import org.mozilla.javascript.Token;
import org.mozilla.javascript.ast.Jump;

class Block
{

    private static class FatBlock
    {

        private static Block[] reduceToArray(ObjToIntMap map)
        {
            Block[] result = null;
            if (!map.isEmpty()) {
                result = new Block[map.size()];
                int i = 0;
                ObjToIntMap.Iterator iter = map.newIterator();
                for (iter.start(); !iter.done(); iter.next()) {
                    FatBlock fb = (FatBlock)(iter.getKey());
                    result[i++] = fb.realBlock;
                }
            }
            return result;
        }

        void addSuccessor(FatBlock b)  { successors.put(b, 0); }
        void addPredecessor(FatBlock b)  { predecessors.put(b, 0); }

        Block[] getSuccessors() { return reduceToArray(successors); }
        Block[] getPredecessors() { return reduceToArray(predecessors); }

        // all the Blocks that come immediately after this
        private ObjToIntMap successors = new ObjToIntMap();
        // all the Blocks that come immediately before this
        private ObjToIntMap predecessors = new ObjToIntMap();

        Block realBlock;
    }

    Block(int startNodeIndex, int endNodeIndex)
    {
        itsStartNodeIndex = startNodeIndex;
        itsEndNodeIndex = endNodeIndex;
    }

    static void runFlowAnalyzes(OptFunctionNode fn, Node[] statementNodes)
    {
        int paramCount = fn.fnode.getParamCount();
        int varCount = fn.fnode.getParamAndVarCount();
        int[] varTypes = new int[varCount];
        // If the variable is a parameter, it could have any type.
        for (int i = 0; i != paramCount; ++i) {
            varTypes[i] = Optimizer.AnyType;
        }
        // If the variable is from a "var" statement, its typeEvent will be set
        // when we see the setVar node.
        for (int i = paramCount; i != varCount; ++i) {
            varTypes[i] = Optimizer.NoType;
        }

        Block[] theBlocks = buildBlocks(statementNodes);

        if (DEBUG) {
            ++debug_blockCount;
            System.out.println("-------------------"+fn.fnode.getFunctionName()+"  "+debug_blockCount+"--------");
            System.out.println(fn.fnode.toStringTree(fn.fnode));
            System.out.println(toString(theBlocks, statementNodes));
        }

        reachingDefDataFlow(fn, statementNodes, theBlocks, varTypes);
        typeFlow(fn, statementNodes, theBlocks, varTypes);

        if (DEBUG) {
            for (int i = 0; i < theBlocks.length; i++) {
                System.out.println("For block " + theBlocks[i].itsBlockID);
                theBlocks[i].printLiveOnEntrySet(fn);
            }
            System.out.println("Variable Table, size = " + varCount);
            for (int i = 0; i != varCount; i++) {
                System.out.println("["+i+"] type: "+varTypes[i]);
            }
        }

        for (int i = paramCount; i != varCount; i++) {
            if (varTypes[i] == Optimizer.NumberType) {
                fn.setIsNumberVar(i);
            }
        }

    }

    private static Block[] buildBlocks(Node[] statementNodes)
    {
        // a mapping from each target node to the block it begins
        Map theTargetBlocks = new HashMap();
        ObjArray theBlocks = new ObjArray();

        // there's a block that starts at index 0
        int beginNodeIndex = 0;

        for (int i = 0; i < statementNodes.length; i++) {
            switch (statementNodes[i].getType()) {
                case Token.TARGET :
                {
                    if (i != beginNodeIndex) {
                        FatBlock fb = newFatBlock(beginNodeIndex, i - 1);
                        if (statementNodes[beginNodeIndex].getType() == Token.TARGET) {
                            theTargetBlocks.put(statementNodes[beginNodeIndex], fb);
                        }
                        theBlocks.add(fb);
                        // start the next block at this node
                        beginNodeIndex = i;
                    }
                }
                break;
                case Token.IFNE :
                case Token.IFEQ :
                case Token.GOTO :
                {
                    FatBlock fb = newFatBlock(beginNodeIndex, i);
                    if (statementNodes[beginNodeIndex].getType() == Token.TARGET) {
                        theTargetBlocks.put(statementNodes[beginNodeIndex], fb);
                    }
                    theBlocks.add(fb);
                    // start the next block at the next node
                    beginNodeIndex = i + 1;
                }
                break;
            }
        }

        if (beginNodeIndex != statementNodes.length) {
            FatBlock fb = newFatBlock(beginNodeIndex, statementNodes.length - 1);
            if (statementNodes[beginNodeIndex].getType() == Token.TARGET) {
                theTargetBlocks.put(statementNodes[beginNodeIndex], fb);
            }
            theBlocks.add(fb);
        }

        // build successor and predecessor links

        for (int i = 0; i < theBlocks.size(); i++) {
            FatBlock fb = (FatBlock)(theBlocks.get(i));

            Node blockEndNode = statementNodes[fb.realBlock.itsEndNodeIndex];
            int blockEndNodeType = blockEndNode.getType();

            if ((blockEndNodeType != Token.GOTO) && (i < (theBlocks.size() - 1))) {
                FatBlock fallThruTarget = (FatBlock)(theBlocks.get(i + 1));
                fb.addSuccessor(fallThruTarget);
                fallThruTarget.addPredecessor(fb);
            }


            if ( (blockEndNodeType == Token.IFNE)
                    || (blockEndNodeType == Token.IFEQ)
                    || (blockEndNodeType == Token.GOTO) ) {
                Node target = ((Jump)blockEndNode).target;
                FatBlock branchTargetBlock = theTargetBlocks.get(target);
                target.putProp(Node.TARGETBLOCK_PROP, branchTargetBlock.realBlock);
                fb.addSuccessor(branchTargetBlock);
                branchTargetBlock.addPredecessor(fb);
            }
        }

        Block[] result = new Block[theBlocks.size()];

        for (int i = 0; i < theBlocks.size(); i++) {
            FatBlock fb = (FatBlock)(theBlocks.get(i));
            Block b = fb.realBlock;
            b.itsSuccessors = fb.getSuccessors();
            b.itsPredecessors = fb.getPredecessors();
            b.itsBlockID = i;
            result[i] = b;
        }

        return result;
    }

    private static FatBlock newFatBlock(int startNodeIndex, int endNodeIndex)
    {
        FatBlock fb = new FatBlock();
        fb.realBlock = new Block(startNodeIndex, endNodeIndex);
        return fb;
    }

    private static String toString(Block[] blockList, Node[] statementNodes)
    {
        if (!DEBUG) return null;

        StringWriter sw = new StringWriter();
        PrintWriter pw = new PrintWriter(sw);

        pw.println(blockList.length + " Blocks");
        for (int i = 0; i < blockList.length; i++) {
            Block b = blockList[i];
            pw.println("#" + b.itsBlockID);
            pw.println("from " + b.itsStartNodeIndex
                    + " "
                    + statementNodes[b.itsStartNodeIndex].toString());
            pw.println("thru " + b.itsEndNodeIndex
                    + " "
                    + statementNodes[b.itsEndNodeIndex].toString());
            pw.print("Predecessors ");
            if (b.itsPredecessors != null) {
                for (int j = 0; j < b.itsPredecessors.length; j++) {
                    pw.print(b.itsPredecessors[j].itsBlockID + " ");
                }
                pw.println();
            } else {
                pw.println("none");
            }
            pw.print("Successors ");
            if (b.itsSuccessors != null) {
                for (int j = 0; j < b.itsSuccessors.length; j++) {
                    pw.print(b.itsSuccessors[j].itsBlockID + " ");
                }
                pw.println();
            } else {
                pw.println("none");
            }
        }
        return sw.toString();
    }

    private static void reachingDefDataFlow(OptFunctionNode fn, Node[] statementNodes,
                                            Block theBlocks[], int[] varTypes)
    {
/*
    initialize the liveOnEntry and liveOnExit sets, then discover the variables
    that are def'd by each function, and those that are used before being def'd
    (hence liveOnEntry)
*/
        for (int i = 0; i < theBlocks.length; i++) {
            theBlocks[i].initLiveOnEntrySets(fn, statementNodes);
        }
/*
    this visits every block starting at the last, re-adding the predecessors of
    any block whose inputs change as a result of the dataflow.
    REMIND, better would be to visit in CFG postorder
*/
        boolean visit[] = new boolean[theBlocks.length];
        boolean doneOnce[] = new boolean[theBlocks.length];
        int vIndex = theBlocks.length - 1;
        boolean needRescan = false;
        visit[vIndex] = true;
        while (true) {
            if (visit[vIndex] || !doneOnce[vIndex]) {
                doneOnce[vIndex] = true;
                visit[vIndex] = false;
                if (theBlocks[vIndex].doReachedUseDataFlow()) {
                    Block pred[] = theBlocks[vIndex].itsPredecessors;
                    if (pred != null) {
                        for (int i = 0; i < pred.length; i++) {
                            int index = pred[i].itsBlockID;
                            visit[index] = true;
                            needRescan |= (index > vIndex);
                        }
                    }
                }
            }
            if (vIndex == 0) {
                if (needRescan) {
                    vIndex = theBlocks.length - 1;
                    needRescan = false;
                } else {
                    break;
                }
            } else {
                vIndex--;
            }
        }
/*
        if any variable is live on entry to block 0, we have to mark it as
        not jRegable - since it means that someone is trying to access the
        'undefined'-ness of that variable.
*/

        theBlocks[0].markAnyTypeVariables(varTypes);
    }

    private static void typeFlow(OptFunctionNode fn, Node[] statementNodes,
                                 Block theBlocks[], int[] varTypes)
    {
        boolean visit[] = new boolean[theBlocks.length];
        boolean doneOnce[] = new boolean[theBlocks.length];
        int vIndex = 0;
        boolean needRescan = false;
        visit[vIndex] = true;
        while (true) {
            if (visit[vIndex] || !doneOnce[vIndex]) {
                doneOnce[vIndex] = true;
                visit[vIndex] = false;
                if (theBlocks[vIndex].doTypeFlow(fn, statementNodes, varTypes))
                {
                    Block succ[] = theBlocks[vIndex].itsSuccessors;
                    if (succ != null) {
                        for (int i = 0; i < succ.length; i++) {
                            int index = succ[i].itsBlockID;
                            visit[index] = true;
                            needRescan |= (index < vIndex);
                        }
                    }
                }
            }
            if (vIndex == (theBlocks.length - 1)) {
                if (needRescan) {
                    vIndex = 0;
                    needRescan = false;
                } else {
                    break;
                }
            } else {
                vIndex++;
            }
        }
    }

    private static boolean assignType(int[] varTypes, int index, int type)
    {
        int prev = varTypes[index];
        return prev != (varTypes[index] |= type);
    }

    private void markAnyTypeVariables(int[] varTypes)
    {
        for (int i = 0; i != varTypes.length; i++) {
            if (itsLiveOnEntrySet.get(i)) {
                assignType(varTypes, i, Optimizer.AnyType);
            }
        }

    }

    /*
        We're tracking uses and defs - in order to
        build the def set and to identify the last use
        nodes.

        The itsNotDefSet is built reversed then flipped later.

    */
    private void lookForVariableAccess(OptFunctionNode fn, Node n)
    {
        switch (n.getType()) {
            case Token.TYPEOFNAME:
            {
                // TYPEOFNAME may be used with undefined names, which is why
                // this is handled separately from GETVAR above.
                int varIndex = fn.fnode.getIndexForNameNode(n);
                if (varIndex > -1 && !itsNotDefSet.get(varIndex))
                    itsUseBeforeDefSet.set(varIndex);
            }
            break;
            case Token.DEC :
            case Token.INC :
            {
                Node child = n.getFirstChild();
                if (child.getType() == Token.GETVAR) {
                    int varIndex = fn.getVarIndex(child);
                    if (!itsNotDefSet.get(varIndex))
                        itsUseBeforeDefSet.set(varIndex);
                    itsNotDefSet.set(varIndex);
                } else {
                    lookForVariableAccess(fn, child);
                }
            }
            break;
            case Token.SETVAR :
            case Token.SETCONSTVAR :
            {
                Node lhs = n.getFirstChild();
                Node rhs = lhs.getNext();
                lookForVariableAccess(fn, rhs);
                itsNotDefSet.set(fn.getVarIndex(n));
            }
            break;
            case Token.GETVAR :
            {
                int varIndex = fn.getVarIndex(n);
                if (!itsNotDefSet.get(varIndex))
                    itsUseBeforeDefSet.set(varIndex);
            }
            break;
            default :
                Node child = n.getFirstChild();
                while (child != null) {
                    lookForVariableAccess(fn, child);
                    child = child.getNext();
                }
                break;
        }
    }

    /*
        build the live on entry/exit sets.
        Then walk the trees looking for defs/uses of variables
        and build the def and useBeforeDef sets.
    */
    private void initLiveOnEntrySets(OptFunctionNode fn, Node[] statementNodes)
    {
        int listLength = fn.getVarCount();
        itsUseBeforeDefSet = new BitSet(listLength);
        itsNotDefSet = new BitSet(listLength);
        itsLiveOnEntrySet = new BitSet(listLength);
        itsLiveOnExitSet = new BitSet(listLength);
        for (int i = itsStartNodeIndex; i <= itsEndNodeIndex; i++) {
            Node n = statementNodes[i];
            lookForVariableAccess(fn, n);
        }
        itsNotDefSet.flip(0, listLength);         // truth in advertising
    }

    /*
        the liveOnEntry of each successor is the liveOnExit for this block.
        The liveOnEntry for this block is -
        liveOnEntry = liveOnExit - defsInThisBlock + useBeforeDefsInThisBlock

    */
    private boolean doReachedUseDataFlow()
    {
        itsLiveOnExitSet.clear();
        if (itsSuccessors != null) {
            for (int i = 0; i < itsSuccessors.length; i++) {
                itsLiveOnExitSet.or(itsSuccessors[i].itsLiveOnEntrySet);
            }
        }
        return updateEntrySet(itsLiveOnEntrySet, itsLiveOnExitSet,
                              itsUseBeforeDefSet, itsNotDefSet);
    }

    private static boolean updateEntrySet(BitSet entrySet, BitSet exitSet,
                                   BitSet useBeforeDef, BitSet notDef) {
        int card = entrySet.cardinality();
        entrySet.or(exitSet);
        entrySet.and(notDef);
        entrySet.or(useBeforeDef);
        return entrySet.cardinality() != card;
    }

    /*
        the type of an expression is relatively unknown. Cases we can be sure
        about are -
            Literals,
            Arithmetic operations - always return a Number
    */
    private static int findExpressionType(OptFunctionNode fn, Node n,
                                          int[] varTypes)
    {
        switch (n.getType()) {
            case Token.NUMBER:
                return Optimizer.NumberType;

            case Token.CALL:
            case Token.NEW:
            case Token.REF_CALL:
                return Optimizer.AnyType;

            case Token.GETELEM:
            case Token.GETPROP:
            case Token.NAME:
            case Token.THIS:
                return Optimizer.AnyType;

            case Token.GETVAR:
                return varTypes[fn.getVarIndex(n)];

            case Token.INC:
            case Token.DEC:
            case Token.MUL:
            case Token.DIV:
            case Token.MOD:
            case Token.BITOR:
            case Token.BITXOR:
            case Token.BITAND:
            case Token.BITNOT:
            case Token.LSH:
            case Token.RSH:
            case Token.URSH:
            case Token.SUB:
            case Token.POS:
            case Token.NEG:
                return Optimizer.NumberType;

            case Token.VOID:
                // NYI: undefined type
                return Optimizer.AnyType;

            case Token.FALSE:
            case Token.TRUE:
            case Token.EQ:
            case Token.NE:
            case Token.LT:
            case Token.LE:
            case Token.GT:
            case Token.GE:
            case Token.SHEQ:
            case Token.SHNE:
            case Token.NOT:
            case Token.INSTANCEOF:
            case Token.IN:
            case Token.DEL_REF:
            case Token.DELPROP:
                // NYI: boolean type
                return Optimizer.AnyType;

            case Token.STRING:
            case Token.TYPEOF:
            case Token.TYPEOFNAME:
                // NYI: string type
                return Optimizer.AnyType;

            case Token.NULL:
            case Token.REGEXP:
            case Token.ARRAYCOMP:
            case Token.ARRAYLIT:
            case Token.OBJECTLIT:
                return Optimizer.AnyType; // XXX: actually, we know it's not
            // number, but no type yet for that

            case Token.ADD: {
                // if the lhs & rhs are known to be numbers, we can be sure that's
                // the result, otherwise it could be a string.
                Node child = n.getFirstChild();
                int lType = findExpressionType(fn, child, varTypes);
                int rType = findExpressionType(fn, child.getNext(), varTypes);
                return lType | rType;    // we're not distinguishing strings yet
            }

            case Token.HOOK: {
                Node ifTrue = n.getFirstChild().getNext();
                Node ifFalse = ifTrue.getNext();
                int ifTrueType = findExpressionType(fn, ifTrue, varTypes);
                int ifFalseType = findExpressionType(fn, ifFalse, varTypes);
                return ifTrueType | ifFalseType;
            }

            case Token.COMMA:
            case Token.SETVAR:
            case Token.SETCONSTVAR:
            case Token.SETNAME:
            case Token.SETPROP:
            case Token.SETELEM:
                return findExpressionType(fn, n.getLastChild(), varTypes);

            case Token.AND:
            case Token.OR: {
                Node child = n.getFirstChild();
                int lType = findExpressionType(fn, child, varTypes);
                int rType = findExpressionType(fn, child.getNext(), varTypes);
                return lType | rType;
            }
        }

        return Optimizer.AnyType;
    }

    private static boolean findDefPoints(OptFunctionNode fn, Node n,
                                         int[] varTypes)
    {
        boolean result = false;
        Node first = n.getFirstChild();
        for (Node next = first; next != null; next = next.getNext()) {
            result |= findDefPoints(fn, next, varTypes);
        }
        switch (n.getType()) {
            case Token.DEC :
            case Token.INC :
                if (first.getType() == Token.GETVAR) {
                    // theVar is a Number now
                    int i = fn.getVarIndex(first);
                    if (!fn.fnode.getParamAndVarConst()[i]) {
                        result |= assignType(varTypes, i, Optimizer.NumberType);
                    }
                }
                break;
            case Token.SETVAR :
            case Token.SETCONSTVAR : {
                Node rValue = first.getNext();
                int theType = findExpressionType(fn, rValue, varTypes);
                int i = fn.getVarIndex(n);
                if (!(n.getType() == Token.SETVAR
                        && fn.fnode.getParamAndVarConst()[i])) {
                    result |= assignType(varTypes, i, theType);
                }
                break;
            }
        }
        return result;
    }

    private boolean doTypeFlow(OptFunctionNode fn, Node[] statementNodes,
                               int[] varTypes)
    {
        boolean changed = false;

        for (int i = itsStartNodeIndex; i <= itsEndNodeIndex; i++) {
            Node n = statementNodes[i];
            if (n != null) {
                changed |= findDefPoints(fn, n, varTypes);
            }
        }

        return changed;
    }

    private void printLiveOnEntrySet(OptFunctionNode fn)
    {
        if (DEBUG) {
            for (int i = 0; i < fn.getVarCount(); i++) {
                String name = fn.fnode.getParamOrVarName(i);
                if (itsUseBeforeDefSet.get(i))
                    System.out.println(name + " is used before def'd");
                if (itsNotDefSet.get(i))
                    System.out.println(name + " is not def'd");
                if (itsLiveOnEntrySet.get(i))
                    System.out.println(name + " is live on entry");
                if (itsLiveOnExitSet.get(i))
                    System.out.println(name + " is live on exit");
            }
        }
    }

    // all the Blocks that come immediately after this
    private Block[] itsSuccessors;
    // all the Blocks that come immediately before this
    private Block[] itsPredecessors;

    private int itsStartNodeIndex;       // the Node at the start of the block
    private int itsEndNodeIndex;         // the Node at the end of the block

    private int itsBlockID;               // a unique index for each block

    // reaching def bit sets -
    private BitSet itsLiveOnEntrySet;
    private BitSet itsLiveOnExitSet;
    private BitSet itsUseBeforeDefSet;
    private BitSet itsNotDefSet;

    static final boolean DEBUG = false;
    private static int debug_blockCount;

}





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