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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.phases.graph;
import static org.graalvm.compiler.nodes.cfg.ControlFlowGraph.multiplyRelativeFrequencies;
import java.util.function.ToDoubleFunction;
import jdk.internal.vm.compiler.collections.EconomicMap;
import jdk.internal.vm.compiler.collections.Equivalence;
import org.graalvm.compiler.debug.CounterKey;
import org.graalvm.compiler.debug.DebugContext;
import org.graalvm.compiler.graph.Node;
import org.graalvm.compiler.graph.NodeInputList;
import org.graalvm.compiler.nodes.AbstractBeginNode;
import org.graalvm.compiler.nodes.AbstractEndNode;
import org.graalvm.compiler.nodes.AbstractMergeNode;
import org.graalvm.compiler.nodes.ControlSplitNode;
import org.graalvm.compiler.nodes.EndNode;
import org.graalvm.compiler.nodes.FixedNode;
import org.graalvm.compiler.nodes.LoopBeginNode;
import org.graalvm.compiler.nodes.StartNode;
Compute relative frequencies for fixed nodes on the fly and cache them at AbstractBeginNode
s. /**
* Compute relative frequencies for fixed nodes on the fly and cache them at
* {@link AbstractBeginNode}s.
*/
public class FixedNodeRelativeFrequencyCache implements ToDoubleFunction<FixedNode> {
private static final CounterKey computeNodeRelativeFrequencyCounter = DebugContext.counter("ComputeNodeRelativeFrequency");
private final EconomicMap<FixedNode, Double> cache = EconomicMap.create(Equivalence.IDENTITY);
Given a FixedNode
this method finds the most immediate AbstractBeginNode
preceding it that either:
- has no predecessor (ie, the begin-node is a merge, in particular a loop-begin, or the
start-node)
- has a control-split predecessor
The thus found AbstractBeginNode
is equi-probable with the FixedNode
it was obtained from. When computed for the first time (afterwards a cache lookup returns it) that relative frequency is computed as follows, again depending on the begin-node's predecessor:
- No predecessor. In this case the begin-node is either:
- a merge-node, whose relative frequency adds up those of its forward-ends
- a loop-begin, with frequency as above multiplied by the loop-frequency
- Control-split predecessor: frequency of the branch times that of the control-split
As an exception to all the above, a frequency of 1 is assumed for a FixedNode
that appears to be dead-code (ie, lacks a predecessor).
/**
* <p>
* Given a {@link FixedNode} this method finds the most immediate {@link AbstractBeginNode}
* preceding it that either:
* <ul>
* <li>has no predecessor (ie, the begin-node is a merge, in particular a loop-begin, or the
* start-node)</li>
* <li>has a control-split predecessor</li>
* </ul>
* </p>
*
* <p>
* The thus found {@link AbstractBeginNode} is equi-probable with the {@link FixedNode} it was
* obtained from. When computed for the first time (afterwards a cache lookup returns it) that
* relative frequency is computed as follows, again depending on the begin-node's predecessor:
* <ul>
* <li>No predecessor. In this case the begin-node is either:</li>
* <ul>
* <li>a merge-node, whose relative frequency adds up those of its forward-ends</li>
* <li>a loop-begin, with frequency as above multiplied by the loop-frequency</li>
* </ul>
* <li>Control-split predecessor: frequency of the branch times that of the control-split</li>
* </ul>
* </p>
*
* <p>
* As an exception to all the above, a frequency of 1 is assumed for a {@link FixedNode} that
* appears to be dead-code (ie, lacks a predecessor).
* </p>
*
*/
@Override
public double applyAsDouble(FixedNode node) {
assert node != null;
computeNodeRelativeFrequencyCounter.increment(node.getDebug());
FixedNode current = findBegin(node);
if (current == null) {
// this should only appear for dead code
return 1D;
}
assert current instanceof AbstractBeginNode;
Double cachedValue = cache.get(current);
if (cachedValue != null) {
return cachedValue;
}
double relativeFrequency = 0.0;
if (current.predecessor() == null) {
if (current instanceof AbstractMergeNode) {
relativeFrequency = handleMerge(current, relativeFrequency);
} else {
assert current instanceof StartNode;
relativeFrequency = 1D;
}
} else {
ControlSplitNode split = (ControlSplitNode) current.predecessor();
relativeFrequency = multiplyRelativeFrequencies(split.probability((AbstractBeginNode) current), applyAsDouble(split));
}
assert !Double.isNaN(relativeFrequency) && !Double.isInfinite(relativeFrequency) : current + " " + relativeFrequency;
cache.put(current, relativeFrequency);
return relativeFrequency;
}
private double handleMerge(FixedNode current, double relativeFrequency) {
double result = relativeFrequency;
AbstractMergeNode currentMerge = (AbstractMergeNode) current;
NodeInputList<EndNode> currentForwardEnds = currentMerge.forwardEnds();
/*
* Use simple iteration instead of streams, since the stream infrastructure adds many frames
* which causes the recursion to overflow the stack earlier than it would otherwise.
*/
for (AbstractEndNode endNode : currentForwardEnds) {
result += applyAsDouble(endNode);
}
if (current instanceof LoopBeginNode) {
result = multiplyRelativeFrequencies(result, ((LoopBeginNode) current).loopFrequency());
}
return result;
}
private static FixedNode findBegin(FixedNode node) {
FixedNode current = node;
while (true) {
assert current != null;
Node predecessor = current.predecessor();
if (current instanceof AbstractBeginNode) {
if (predecessor == null) {
break;
} else if (predecessor.successors().count() != 1) {
assert predecessor instanceof ControlSplitNode : "a FixedNode with multiple successors needs to be a ControlSplitNode: " + current + " / " + predecessor;
break;
}
} else if (predecessor == null) {
current = null;
break;
}
current = (FixedNode) predecessor;
}
return current;
}
}