package org.graalvm.compiler.nodes;
import static org.graalvm.compiler.graph.iterators.NodePredicates.isNotA;
import org.graalvm.compiler.core.common.type.IntegerStamp;
import org.graalvm.compiler.graph.IterableNodeType;
import org.graalvm.compiler.graph.Node;
import org.graalvm.compiler.graph.NodeClass;
import org.graalvm.compiler.graph.iterators.NodeIterable;
import org.graalvm.compiler.graph.spi.SimplifierTool;
import org.graalvm.compiler.nodeinfo.InputType;
import org.graalvm.compiler.nodeinfo.NodeInfo;
import org.graalvm.compiler.nodes.calc.AddNode;
import org.graalvm.compiler.nodes.extended.GuardingNode;
import org.graalvm.compiler.nodes.spi.LIRLowerable;
import org.graalvm.compiler.nodes.spi.NodeLIRBuilderTool;
import org.graalvm.compiler.nodes.util.GraphUtil;
@NodeInfo
public final class LoopBeginNode extends AbstractMergeNode implements IterableNodeType, LIRLowerable {
public static final NodeClass<LoopBeginNode> TYPE = NodeClass.create(LoopBeginNode.class);
protected double loopFrequency;
protected int nextEndIndex;
protected int unswitches;
protected int inversionCount;
boolean canEndsSafepoint;
@OptionalInput(InputType.Guard) GuardingNode overflowGuard;
public LoopBeginNode() {
super(TYPE);
loopFrequency = 1;
this.canEndsSafepoint = true;
}
public void disableSafepoint() {
this.canEndsSafepoint = false;
for (LoopEndNode loopEnd : loopEnds()) {
loopEnd.disableSafepoint();
}
}
public double loopFrequency() {
return loopFrequency;
}
public void setLoopFrequency(double loopFrequency) {
assert loopFrequency >= 0;
this.loopFrequency = loopFrequency;
}
public NodeIterable<LoopEndNode> loopEnds() {
return usages().filter(LoopEndNode.class);
}
public NodeIterable<LoopExitNode> loopExits() {
return usages().filter(LoopExitNode.class);
}
@Override
public NodeIterable<Node> anchored() {
return super.anchored().filter(isNotA(LoopEndNode.class).nor(LoopExitNode.class));
}
public LoopEndNode[] orderedLoopEnds() {
LoopEndNode[] result = new LoopEndNode[this.getLoopEndCount()];
for (LoopEndNode end : loopEnds()) {
result[end.endIndex()] = end;
}
return result;
}
public AbstractEndNode forwardEnd() {
assert forwardEndCount() == 1;
return forwardEndAt(0);
}
@Override
public void generate(NodeLIRBuilderTool gen) {
}
@Override
protected void deleteEnd(AbstractEndNode end) {
if (end instanceof LoopEndNode) {
LoopEndNode loopEnd = (LoopEndNode) end;
loopEnd.setLoopBegin(null);
int idx = loopEnd.endIndex();
for (LoopEndNode le : loopEnds()) {
int leIdx = le.endIndex();
assert leIdx != idx;
if (leIdx > idx) {
le.setEndIndex(leIdx - 1);
}
}
nextEndIndex--;
} else {
super.deleteEnd(end);
}
}
@Override
public int phiPredecessorCount() {
return forwardEndCount() + loopEnds().count();
}
@Override
public int phiPredecessorIndex(AbstractEndNode pred) {
if (pred instanceof LoopEndNode) {
LoopEndNode loopEnd = (LoopEndNode) pred;
if (loopEnd.loopBegin() == this) {
assert loopEnd.endIndex() < loopEnds().count() : "Invalid endIndex : " + loopEnd;
return loopEnd.endIndex() + forwardEndCount();
}
} else {
return super.forwardEndIndex((EndNode) pred);
}
throw ValueNodeUtil.shouldNotReachHere("unknown pred : " + pred);
}
@Override
public AbstractEndNode phiPredecessorAt(int index) {
if (index < forwardEndCount()) {
return forwardEndAt(index);
}
for (LoopEndNode end : loopEnds()) {
int idx = index - forwardEndCount();
assert idx >= 0;
if (end.endIndex() == idx) {
return end;
}
}
throw ValueNodeUtil.shouldNotReachHere();
}
@Override
public boolean verify() {
assertTrue(loopEnds().isNotEmpty(), "missing loopEnd");
return super.verify();
}
int nextEndIndex() {
return nextEndIndex++;
}
public int getLoopEndCount() {
return nextEndIndex;
}
public int unswitches() {
return unswitches;
}
public void incrementUnswitches() {
unswitches++;
}
public int getInversionCount() {
return inversionCount;
}
public void setInversionCount(int count) {
inversionCount = count;
}
@Override
public void simplify(SimplifierTool tool) {
canonicalizePhis(tool);
}
public boolean isLoopExit(AbstractBeginNode begin) {
return begin instanceof LoopExitNode && ((LoopExitNode) begin).loopBegin() == this;
}
public void removeExits() {
for (LoopExitNode loopexit : loopExits().snapshot()) {
loopexit.removeProxies();
FrameState loopStateAfter = loopexit.stateAfter();
graph().replaceFixedWithFixed(loopexit, graph().add(new BeginNode()));
if (loopStateAfter != null && loopStateAfter.isAlive() && loopStateAfter.hasNoUsages()) {
GraphUtil.killWithUnusedFloatingInputs(loopStateAfter);
}
}
}
public GuardingNode getOverflowGuard() {
return overflowGuard;
}
public void setOverflowGuard(GuardingNode overflowGuard) {
updateUsagesInterface(this.overflowGuard, overflowGuard);
this.overflowGuard = overflowGuard;
}
private static final int NO_INCREMENT = Integer.MIN_VALUE;
private static int[] getSelfIncrements(PhiNode phi) {
int[] selfIncrement = new int[phi.valueCount()];
for (int i = 0; i < phi.valueCount(); i++) {
ValueNode input = phi.valueAt(i);
long increment = NO_INCREMENT;
if (input != null && input instanceof AddNode && input.stamp() instanceof IntegerStamp) {
AddNode add = (AddNode) input;
if (add.getX() == phi && add.getY().isConstant()) {
increment = add.getY().asJavaConstant().asLong();
} else if (add.getY() == phi && add.getX().isConstant()) {
increment = add.getX().asJavaConstant().asLong();
}
} else if (input == phi) {
increment = 0;
}
if (increment < Integer.MIN_VALUE || increment > Integer.MAX_VALUE || increment == NO_INCREMENT) {
increment = NO_INCREMENT;
}
selfIncrement[i] = (int) increment;
}
return selfIncrement;
}
public void canonicalizePhis(SimplifierTool tool) {
int phiCount = phis().count();
if (phiCount > 1) {
int phiInputCount = phiPredecessorCount();
int phiIndex = 0;
int[][] selfIncrement = new int[phiCount][];
PhiNode[] phis = this.phis().snapshot().toArray(new PhiNode[phiCount]);
for (phiIndex = 0; phiIndex < phiCount; phiIndex++) {
PhiNode phi = phis[phiIndex];
if (phi != null) {
nextPhi: for (int otherPhiIndex = phiIndex + 1; otherPhiIndex < phiCount; otherPhiIndex++) {
PhiNode otherPhi = phis[otherPhiIndex];
if (otherPhi == null || phi.getNodeClass() != otherPhi.getNodeClass() || !phi.valueEquals(otherPhi)) {
continue nextPhi;
}
if (selfIncrement[phiIndex] == null) {
selfIncrement[phiIndex] = getSelfIncrements(phi);
}
if (selfIncrement[otherPhiIndex] == null) {
selfIncrement[otherPhiIndex] = getSelfIncrements(otherPhi);
}
int[] phiIncrement = selfIncrement[phiIndex];
int[] otherPhiIncrement = selfIncrement[otherPhiIndex];
for (int inputIndex = 0; inputIndex < phiInputCount; inputIndex++) {
if (phiIncrement[inputIndex] == NO_INCREMENT) {
if (phi.valueAt(inputIndex) != otherPhi.valueAt(inputIndex)) {
continue nextPhi;
}
}
if (phiIncrement[inputIndex] != otherPhiIncrement[inputIndex]) {
continue nextPhi;
}
}
if (tool != null) {
tool.addToWorkList(otherPhi.usages());
}
otherPhi.replaceAtUsages(phi);
GraphUtil.killWithUnusedFloatingInputs(otherPhi);
phis[otherPhiIndex] = null;
}
}
}
}
}
}