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 * Copyright (c) 2013, 2014, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.
 *
 * This code 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 General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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package org.graalvm.compiler.nodes;

import static org.graalvm.compiler.nodeinfo.InputType.Condition;
import static org.graalvm.compiler.nodeinfo.NodeCycles.CYCLES_0;
import static org.graalvm.compiler.nodeinfo.NodeSize.SIZE_0;

import org.graalvm.compiler.core.common.type.IntegerStamp;
import org.graalvm.compiler.graph.IterableNodeType;
import org.graalvm.compiler.graph.NodeClass;
import org.graalvm.compiler.graph.spi.Canonicalizable;
import org.graalvm.compiler.graph.spi.CanonicalizerTool;
import org.graalvm.compiler.nodeinfo.NodeInfo;
import org.graalvm.compiler.nodes.calc.IntegerBelowNode;
import org.graalvm.compiler.nodes.calc.IntegerLessThanNode;

import jdk.vm.ci.meta.TriState;

@NodeInfo(cycles = CYCLES_0, size = SIZE_0)
public final class ShortCircuitOrNode extends LogicNode implements IterableNodeType, Canonicalizable.Binary<LogicNode> {
    public static final NodeClass<ShortCircuitOrNode> TYPE = NodeClass.create(ShortCircuitOrNode.class);
    @Input(Condition) LogicNode x;
    @Input(Condition) LogicNode y;
    protected boolean xNegated;
    protected boolean yNegated;
    protected double shortCircuitProbability;

    public ShortCircuitOrNode(LogicNode x, boolean xNegated, LogicNode y, boolean yNegated, double shortCircuitProbability) {
        super(TYPE);
        this.x = x;
        this.xNegated = xNegated;
        this.y = y;
        this.yNegated = yNegated;
        this.shortCircuitProbability = shortCircuitProbability;
    }

    @Override
    public LogicNode getX() {
        return x;
    }

    @Override
    public LogicNode getY() {
        return y;
    }

    public boolean isXNegated() {
        return xNegated;
    }

    public boolean isYNegated() {
        return yNegated;
    }

    
Gets the probability that the y part of this binary node is not evaluated. This is the probability that this operator will short-circuit its execution.
/** * Gets the probability that the {@link #getY() y} part of this binary node is <b>not</b> * evaluated. This is the probability that this operator will short-circuit its execution. */
public double getShortCircuitProbability() { return shortCircuitProbability; } protected ShortCircuitOrNode canonicalizeNegation(LogicNode forX, LogicNode forY) { LogicNode xCond = forX; boolean xNeg = xNegated; while (xCond instanceof LogicNegationNode) { xCond = ((LogicNegationNode) xCond).getValue(); xNeg = !xNeg; } LogicNode yCond = forY; boolean yNeg = yNegated; while (yCond instanceof LogicNegationNode) { yCond = ((LogicNegationNode) yCond).getValue(); yNeg = !yNeg; } if (xCond != forX || yCond != forY) { return new ShortCircuitOrNode(xCond, xNeg, yCond, yNeg, shortCircuitProbability); } else { return this; } } @Override public LogicNode canonical(CanonicalizerTool tool, LogicNode forX, LogicNode forY) { ShortCircuitOrNode ret = canonicalizeNegation(forX, forY); if (ret != this) { return ret; } if (forX == forY) { // @formatter:off // a || a = a // a || !a = true // !a || a = true // !a || !a = !a // @formatter:on if (isXNegated()) { if (isYNegated()) { // !a || !a = !a return LogicNegationNode.create(forX); } else { // !a || a = true return LogicConstantNode.tautology(); } } else { if (isYNegated()) { // a || !a = true return LogicConstantNode.tautology(); } else { // a || a = a return forX; } } } if (forX instanceof LogicConstantNode) { if (((LogicConstantNode) forX).getValue() ^ isXNegated()) { return LogicConstantNode.tautology(); } else { if (isYNegated()) { return new LogicNegationNode(forY); } else { return forY; } } } if (forY instanceof LogicConstantNode) { if (((LogicConstantNode) forY).getValue() ^ isYNegated()) { return LogicConstantNode.tautology(); } else { if (isXNegated()) { return new LogicNegationNode(forX); } else { return forX; } } } if (forX instanceof ShortCircuitOrNode) { ShortCircuitOrNode inner = (ShortCircuitOrNode) forX; if (forY == inner.getX()) { return optimizeShortCircuit(inner, this.xNegated, this.yNegated, true); } else if (forY == inner.getY()) { return optimizeShortCircuit(inner, this.xNegated, this.yNegated, false); } } else if (forY instanceof ShortCircuitOrNode) { ShortCircuitOrNode inner = (ShortCircuitOrNode) forY; if (inner.getX() == forX) { return optimizeShortCircuit(inner, this.yNegated, this.xNegated, true); } else if (inner.getY() == forX) { return optimizeShortCircuit(inner, this.yNegated, this.xNegated, false); } } // !X => Y constant TriState impliedForY = forX.implies(!isXNegated(), forY); if (impliedForY.isKnown()) { boolean yResult = impliedForY.toBoolean() ^ isYNegated(); return yResult ? LogicConstantNode.tautology() : (isXNegated() ? LogicNegationNode.create(forX) : forX); } // if X >= 0: // u < 0 || X < u ==>> X |<| u if (!isXNegated() && !isYNegated()) { LogicNode sym = simplifyComparison(forX, forY); if (sym != null) { return sym; } } // if X >= 0: // X |<| u || X < u ==>> X |<| u if (forX instanceof IntegerBelowNode && forY instanceof IntegerLessThanNode && !isXNegated() && !isYNegated()) { IntegerBelowNode xNode = (IntegerBelowNode) forX; IntegerLessThanNode yNode = (IntegerLessThanNode) forY; ValueNode xxNode = xNode.getX(); // X >= 0 ValueNode yxNode = yNode.getX(); // X >= 0 if (xxNode == yxNode && ((IntegerStamp) xxNode.stamp(NodeView.DEFAULT)).isPositive()) { ValueNode xyNode = xNode.getY(); // u ValueNode yyNode = yNode.getY(); // u if (xyNode == yyNode) { return forX; } } } // if X >= 0: // u < 0 || (X < u || tail) ==>> X |<| u || tail if (forY instanceof ShortCircuitOrNode && !isXNegated() && !isYNegated()) { ShortCircuitOrNode yNode = (ShortCircuitOrNode) forY; if (!yNode.isXNegated()) { LogicNode sym = simplifyComparison(forX, yNode.getX()); if (sym != null) { double p1 = getShortCircuitProbability(); double p2 = yNode.getShortCircuitProbability(); return new ShortCircuitOrNode(sym, isXNegated(), yNode.getY(), yNode.isYNegated(), p1 + (1 - p1) * p2); } } } return this; } private static LogicNode simplifyComparison(LogicNode forX, LogicNode forY) { LogicNode sym = simplifyComparisonOrdered(forX, forY); if (sym == null) { return simplifyComparisonOrdered(forY, forX); } return sym; } private static LogicNode simplifyComparisonOrdered(LogicNode forX, LogicNode forY) { // if X is >= 0: // u < 0 || X < u ==>> X |<| u if (forX instanceof IntegerLessThanNode && forY instanceof IntegerLessThanNode) { IntegerLessThanNode xNode = (IntegerLessThanNode) forX; IntegerLessThanNode yNode = (IntegerLessThanNode) forY; ValueNode xyNode = xNode.getY(); // 0 if (xyNode.isConstant() && IntegerStamp.OPS.getAdd().isNeutral(xyNode.asConstant())) { ValueNode yxNode = yNode.getX(); // X >= 0 IntegerStamp stamp = (IntegerStamp) yxNode.stamp(NodeView.DEFAULT); if (stamp.isPositive()) { if (xNode.getX() == yNode.getY()) { ValueNode u = xNode.getX(); return IntegerBelowNode.create(yxNode, u, NodeView.DEFAULT); } } } } return null; } private static LogicNode optimizeShortCircuit(ShortCircuitOrNode inner, boolean innerNegated, boolean matchNegated, boolean matchIsInnerX) { boolean innerMatchNegated; if (matchIsInnerX) { innerMatchNegated = inner.isXNegated(); } else { innerMatchNegated = inner.isYNegated(); } if (!innerNegated) { // The four digit results of the expression used in the 16 subsequent formula comments // correspond to results when using the following truth table for inputs a and b // and testing all 4 possible input combinations: // _ 1234 // a 1100 // b 1010 if (innerMatchNegated == matchNegated) { // ( (!a ||!b) ||!a) => 0111 (!a ||!b) // ( (!a || b) ||!a) => 1011 (!a || b) // ( ( a ||!b) || a) => 1101 ( a ||!b) // ( ( a || b) || a) => 1110 ( a || b) // Only the inner or is relevant, the outer or never adds information. return inner; } else { // ( ( a || b) ||!a) => 1111 (true) // ( (!a ||!b) || a) => 1111 (true) // ( (!a || b) || a) => 1111 (true) // ( ( a ||!b) ||!a) => 1111 (true) // The result of the expression is always true. return LogicConstantNode.tautology(); } } else { if (innerMatchNegated == matchNegated) { // (!(!a ||!b) ||!a) => 1011 (!a || b) // (!(!a || b) ||!a) => 0111 (!a ||!b) // (!( a ||!b) || a) => 1110 ( a || b) // (!( a || b) || a) => 1101 ( a ||!b) boolean newInnerXNegated = inner.isXNegated(); boolean newInnerYNegated = inner.isYNegated(); double newProbability = inner.getShortCircuitProbability(); if (matchIsInnerX) { newInnerYNegated = !newInnerYNegated; } else { newInnerXNegated = !newInnerXNegated; newProbability = 1.0 - newProbability; } // The expression can be transformed into a single or. return new ShortCircuitOrNode(inner.getX(), newInnerXNegated, inner.getY(), newInnerYNegated, newProbability); } else { // (!(!a ||!b) || a) => 1100 (a) // (!(!a || b) || a) => 1100 (a) // (!( a ||!b) ||!a) => 0011 (!a) // (!( a || b) ||!a) => 0011 (!a) LogicNode result = inner.getY(); if (matchIsInnerX) { result = inner.getX(); } // Only the second part of the outer or is relevant. if (matchNegated) { return LogicNegationNode.create(result); } else { return result; } } } } }