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 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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 * 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).
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 * 2 along with this work; if not, write to the Free Software Foundation,
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package org.graalvm.compiler.nodes.calc;

import static org.graalvm.compiler.nodeinfo.NodeCycles.CYCLES_1;

import java.nio.ByteBuffer;
import java.nio.ByteOrder;

import org.graalvm.compiler.core.common.LIRKind;
import org.graalvm.compiler.core.common.type.ArithmeticStamp;
import org.graalvm.compiler.core.common.type.FloatStamp;
import org.graalvm.compiler.core.common.type.IntegerStamp;
import org.graalvm.compiler.core.common.type.Stamp;
import org.graalvm.compiler.core.common.type.StampFactory;
import org.graalvm.compiler.graph.NodeClass;
import org.graalvm.compiler.graph.spi.CanonicalizerTool;
import org.graalvm.compiler.lir.gen.ArithmeticLIRGeneratorTool;
import org.graalvm.compiler.nodeinfo.NodeInfo;
import org.graalvm.compiler.nodes.ConstantNode;
import org.graalvm.compiler.nodes.NodeView;
import org.graalvm.compiler.nodes.ValueNode;
import org.graalvm.compiler.nodes.spi.ArithmeticLIRLowerable;
import org.graalvm.compiler.nodes.spi.NodeLIRBuilderTool;

import jdk.vm.ci.code.CodeUtil;
import jdk.vm.ci.meta.JavaKind;
import jdk.vm.ci.meta.SerializableConstant;

The ReinterpretNode class represents a reinterpreting conversion that changes the stamp of a primitive value to some other incompatible stamp. The new stamp must have the same width as the old stamp.
/** * The {@code ReinterpretNode} class represents a reinterpreting conversion that changes the stamp * of a primitive value to some other incompatible stamp. The new stamp must have the same width as * the old stamp. */
@NodeInfo(cycles = CYCLES_1) public final class ReinterpretNode extends UnaryNode implements ArithmeticLIRLowerable { public static final NodeClass<ReinterpretNode> TYPE = NodeClass.create(ReinterpretNode.class); protected ReinterpretNode(JavaKind to, ValueNode value) { this(StampFactory.forKind(to), value); } protected ReinterpretNode(Stamp to, ValueNode value) { super(TYPE, getReinterpretStamp(to, value.stamp(NodeView.DEFAULT)), value); assert to instanceof ArithmeticStamp; } public static ValueNode create(JavaKind to, ValueNode value, NodeView view) { return create(StampFactory.forKind(to), value, view); } public static ValueNode create(Stamp to, ValueNode value, NodeView view) { return canonical(null, to, value, view); } private static SerializableConstant evalConst(Stamp stamp, SerializableConstant c) { /* * We don't care about byte order here. Either would produce the correct result. */ ByteBuffer buffer = ByteBuffer.wrap(new byte[c.getSerializedSize()]).order(ByteOrder.nativeOrder()); c.serialize(buffer); buffer.rewind(); SerializableConstant ret = ((ArithmeticStamp) stamp).deserialize(buffer); assert !buffer.hasRemaining(); return ret; } @Override public ValueNode canonical(CanonicalizerTool tool, ValueNode forValue) { NodeView view = NodeView.from(tool); return canonical(this, this.stamp(view), forValue, view); } public static ValueNode canonical(ReinterpretNode node, Stamp forStamp, ValueNode forValue, NodeView view) { if (forValue.isConstant()) { return ConstantNode.forConstant(forStamp, evalConst(forStamp, (SerializableConstant) forValue.asConstant()), null); } if (forStamp.isCompatible(forValue.stamp(view))) { return forValue; } if (forValue instanceof ReinterpretNode) { ReinterpretNode reinterpret = (ReinterpretNode) forValue; return new ReinterpretNode(forStamp, reinterpret.getValue()); } return node != null ? node : new ReinterpretNode(forStamp, forValue); }
Compute the IntegerStamp from a FloatStamp, losing as little information as possible. Sorting by their bit pattern reinterpreted as signed integers gives the following order of floating point numbers: -0 | negative numbers | -Inf | NaNs | 0 | positive numbers | +Inf | NaNs So we can compute a better integer range if we know that the input is positive, negative, finite, non-zero and/or not NaN.
/** * Compute the {@link IntegerStamp} from a {@link FloatStamp}, losing as little information as * possible. * * Sorting by their bit pattern reinterpreted as signed integers gives the following order of * floating point numbers: * * -0 | negative numbers | -Inf | NaNs | 0 | positive numbers | +Inf | NaNs * * So we can compute a better integer range if we know that the input is positive, negative, * finite, non-zero and/or not NaN. */
private static IntegerStamp floatToInt(FloatStamp stamp) { int bits = stamp.getBits(); long signBit = 1L << (bits - 1); long exponentMask; if (bits == 64) { exponentMask = Double.doubleToRawLongBits(Double.POSITIVE_INFINITY); } else { assert bits == 32; exponentMask = Float.floatToRawIntBits(Float.POSITIVE_INFINITY); } long positiveInfinity = exponentMask; long negativeInfinity = CodeUtil.signExtend(signBit | positiveInfinity, bits); long negativeZero = CodeUtil.signExtend(signBit | 0, bits); if (stamp.isNaN()) { // special case: in addition to the range, we know NaN has all exponent bits set return IntegerStamp.create(bits, negativeInfinity + 1, CodeUtil.maxValue(bits), exponentMask, CodeUtil.mask(bits)); } long upperBound; if (stamp.isNonNaN()) { if (stamp.upperBound() < 0.0) { if (stamp.lowerBound() > Double.NEGATIVE_INFINITY) { upperBound = negativeInfinity - 1; } else { upperBound = negativeInfinity; } } else if (stamp.upperBound() == 0.0) { upperBound = 0; } else if (stamp.upperBound() < Double.POSITIVE_INFINITY) { upperBound = positiveInfinity - 1; } else { upperBound = positiveInfinity; } } else { upperBound = CodeUtil.maxValue(bits); } long lowerBound; if (stamp.lowerBound() > 0.0) { if (stamp.isNonNaN()) { lowerBound = 1; } else { lowerBound = negativeInfinity + 1; } } else if (stamp.upperBound() == Double.NEGATIVE_INFINITY) { lowerBound = negativeInfinity; } else if (stamp.upperBound() < 0.0) { lowerBound = negativeZero + 1; } else { lowerBound = negativeZero; } return StampFactory.forInteger(bits, lowerBound, upperBound); }
Compute the IntegerStamp from a FloatStamp, losing as little information as possible. Sorting by their bit pattern reinterpreted as signed integers gives the following order of floating point numbers: -0 | negative numbers | -Inf | NaNs | 0 | positive numbers | +Inf | NaNs So from certain integer ranges we may be able to infer something about the sign, finiteness or NaN-ness of the result.
/** * Compute the {@link IntegerStamp} from a {@link FloatStamp}, losing as little information as * possible. * * Sorting by their bit pattern reinterpreted as signed integers gives the following order of * floating point numbers: * * -0 | negative numbers | -Inf | NaNs | 0 | positive numbers | +Inf | NaNs * * So from certain integer ranges we may be able to infer something about the sign, finiteness * or NaN-ness of the result. */
private static FloatStamp intToFloat(IntegerStamp stamp) { int bits = stamp.getBits(); double minPositive; double maxPositive; long signBit = 1L << (bits - 1); long exponentMask; if (bits == 64) { exponentMask = Double.doubleToRawLongBits(Double.POSITIVE_INFINITY); minPositive = Double.MIN_VALUE; maxPositive = Double.MAX_VALUE; } else { assert bits == 32; exponentMask = Float.floatToRawIntBits(Float.POSITIVE_INFINITY); minPositive = Float.MIN_VALUE; maxPositive = Float.MAX_VALUE; } long significandMask = CodeUtil.mask(bits) & ~(signBit | exponentMask); long positiveInfinity = exponentMask; long negativeInfinity = CodeUtil.signExtend(signBit | positiveInfinity, bits); long negativeZero = CodeUtil.signExtend(signBit | 0, bits); if ((stamp.downMask() & exponentMask) == exponentMask && (stamp.downMask() & significandMask) != 0) { // if all exponent bits and at least one significand bit are set, the result is NaN return new FloatStamp(bits, Double.NaN, Double.NaN, false); } double upperBound; if (stamp.upperBound() < negativeInfinity) { if (stamp.lowerBound() > negativeZero) { upperBound = -minPositive; } else { upperBound = -0.0; } } else if (stamp.upperBound() < 0) { if (stamp.lowerBound() > negativeInfinity) { return new FloatStamp(bits, Double.NaN, Double.NaN, false); } else if (stamp.lowerBound() == negativeInfinity) { upperBound = Double.NEGATIVE_INFINITY; } else if (stamp.lowerBound() > negativeZero) { upperBound = -minPositive; } else { upperBound = -0.0; } } else if (stamp.upperBound() == 0) { upperBound = 0.0; } else if (stamp.upperBound() < positiveInfinity) { upperBound = maxPositive; } else { upperBound = Double.POSITIVE_INFINITY; } double lowerBound; if (stamp.lowerBound() > positiveInfinity) { return new FloatStamp(bits, Double.NaN, Double.NaN, false); } else if (stamp.lowerBound() == positiveInfinity) { lowerBound = Double.POSITIVE_INFINITY; } else if (stamp.lowerBound() > 0) { lowerBound = minPositive; } else if (stamp.lowerBound() > negativeInfinity) { lowerBound = 0.0; } else { lowerBound = Double.NEGATIVE_INFINITY; } boolean nonNaN; if ((stamp.upMask() & exponentMask) != exponentMask) { // NaN has all exponent bits set nonNaN = true; } else { boolean negativeNaNBlock = stamp.lowerBound() < 0 && stamp.upperBound() > negativeInfinity; boolean positiveNaNBlock = stamp.upperBound() > positiveInfinity; nonNaN = !negativeNaNBlock && !positiveNaNBlock; } return new FloatStamp(bits, lowerBound, upperBound, nonNaN); } private static Stamp getReinterpretStamp(Stamp toStamp, Stamp fromStamp) { if (toStamp instanceof IntegerStamp && fromStamp instanceof FloatStamp) { return floatToInt((FloatStamp) fromStamp); } else if (toStamp instanceof FloatStamp && fromStamp instanceof IntegerStamp) { return intToFloat((IntegerStamp) fromStamp); } else { return toStamp; } } @Override public boolean inferStamp() { return updateStamp(getReinterpretStamp(stamp(NodeView.DEFAULT), getValue().stamp(NodeView.DEFAULT))); } @Override public void generate(NodeLIRBuilderTool builder, ArithmeticLIRGeneratorTool gen) { LIRKind kind = builder.getLIRGeneratorTool().getLIRKind(stamp(NodeView.DEFAULT)); builder.setResult(this, gen.emitReinterpret(kind, builder.operand(getValue()))); } public static ValueNode reinterpret(JavaKind toKind, ValueNode value) { return value.graph().unique(new ReinterpretNode(toKind, value)); } }