Mercurial > hg > graal-compiler
view graal/com.oracle.graal.phases.common/src/com/oracle/graal/phases/common/inlining/info/MultiTypeGuardInlineInfo.java @ 23351:3bc2598ce1e0
Update JVMCI import: Move lookup of Java class and hub from ResolvedJavaType to ConstantReflectionProvider
| author | Christian Wimmer <christian.wimmer@oracle.com> |
|---|---|
| date | Mon, 25 Jan 2016 15:03:43 -0800 |
| parents | 615f3bbbb174 |
| children |
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/* * Copyright (c) 2013, 2015, 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. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package com.oracle.graal.phases.common.inlining.info; import static com.oracle.graal.compiler.common.GraalOptions.UseGraalInstrumentation; import java.util.ArrayList; import java.util.Collection; import java.util.HashSet; import java.util.List; import java.util.Set; import jdk.vm.ci.meta.ConstantReflectionProvider; import jdk.vm.ci.meta.DeoptimizationAction; import jdk.vm.ci.meta.DeoptimizationReason; import jdk.vm.ci.meta.JavaKind; import jdk.vm.ci.meta.JavaTypeProfile.ProfiledType; import jdk.vm.ci.meta.ResolvedJavaMethod; import jdk.vm.ci.meta.ResolvedJavaType; import com.oracle.graal.compiler.common.type.StampFactory; import com.oracle.graal.debug.Debug; import com.oracle.graal.graph.Node; import com.oracle.graal.nodes.AbstractBeginNode; import com.oracle.graal.nodes.AbstractMergeNode; import com.oracle.graal.nodes.BeginNode; import com.oracle.graal.nodes.CallTargetNode.InvokeKind; import com.oracle.graal.nodes.DeoptimizeNode; import com.oracle.graal.nodes.EndNode; import com.oracle.graal.nodes.FixedNode; import com.oracle.graal.nodes.FixedWithNextNode; import com.oracle.graal.nodes.FrameState; import com.oracle.graal.nodes.GuardedValueNode; import com.oracle.graal.nodes.Invoke; import com.oracle.graal.nodes.InvokeWithExceptionNode; import com.oracle.graal.nodes.MergeNode; import com.oracle.graal.nodes.PhiNode; import com.oracle.graal.nodes.StructuredGraph; import com.oracle.graal.nodes.ValueNode; import com.oracle.graal.nodes.ValuePhiNode; import com.oracle.graal.nodes.extended.LoadHubNode; import com.oracle.graal.nodes.java.ExceptionObjectNode; import com.oracle.graal.nodes.java.MethodCallTargetNode; import com.oracle.graal.nodes.java.TypeSwitchNode; import com.oracle.graal.nodes.spi.StampProvider; import com.oracle.graal.nodes.util.GraphUtil; import com.oracle.graal.phases.common.inlining.InliningUtil; import com.oracle.graal.phases.common.inlining.info.elem.Inlineable; import com.oracle.graal.phases.util.Providers; /** * Polymorphic inlining of m methods with n type checks (n ≥ m) in case that the profiling * information suggests a reasonable amount of different receiver types and different methods. If an * unknown type is encountered a deoptimization is triggered. */ public class MultiTypeGuardInlineInfo extends AbstractInlineInfo { private final List<ResolvedJavaMethod> concretes; private final double[] methodProbabilities; private final double maximumMethodProbability; private final ArrayList<Integer> typesToConcretes; private final ArrayList<ProfiledType> ptypes; private final double notRecordedTypeProbability; private final Inlineable[] inlineableElements; public MultiTypeGuardInlineInfo(Invoke invoke, ArrayList<ResolvedJavaMethod> concretes, ArrayList<ProfiledType> ptypes, ArrayList<Integer> typesToConcretes, double notRecordedTypeProbability) { super(invoke); assert concretes.size() > 0 : "must have at least one method"; assert ptypes.size() == typesToConcretes.size() : "array lengths must match"; this.concretes = concretes; this.ptypes = ptypes; this.typesToConcretes = typesToConcretes; this.notRecordedTypeProbability = notRecordedTypeProbability; this.inlineableElements = new Inlineable[concretes.size()]; this.methodProbabilities = computeMethodProbabilities(); this.maximumMethodProbability = maximumMethodProbability(); assert maximumMethodProbability > 0; assert assertUniqueTypes(ptypes); } private static boolean assertUniqueTypes(ArrayList<ProfiledType> ptypes) { Set<ResolvedJavaType> set = new HashSet<>(); for (ProfiledType ptype : ptypes) { set.add(ptype.getType()); } return set.size() == ptypes.size(); } private double[] computeMethodProbabilities() { double[] result = new double[concretes.size()]; for (int i = 0; i < typesToConcretes.size(); i++) { int concrete = typesToConcretes.get(i); double probability = ptypes.get(i).getProbability(); result[concrete] += probability; } return result; } private double maximumMethodProbability() { double max = 0; for (int i = 0; i < methodProbabilities.length; i++) { max = Math.max(max, methodProbabilities[i]); } return max; } @Override public int numberOfMethods() { return concretes.size(); } @Override public ResolvedJavaMethod methodAt(int index) { assert index >= 0 && index < concretes.size(); return concretes.get(index); } @Override public Inlineable inlineableElementAt(int index) { assert index >= 0 && index < concretes.size(); return inlineableElements[index]; } @Override public double probabilityAt(int index) { return methodProbabilities[index]; } @Override public double relevanceAt(int index) { return probabilityAt(index) / maximumMethodProbability; } @Override public void setInlinableElement(int index, Inlineable inlineableElement) { assert index >= 0 && index < concretes.size(); inlineableElements[index] = inlineableElement; } @Override public Collection<Node> inline(Providers providers) { if (hasSingleMethod()) { return inlineSingleMethod(graph(), providers.getStampProvider(), providers.getConstantReflection()); } else { return inlineMultipleMethods(graph(), providers); } } public boolean shouldInline() { for (ResolvedJavaMethod method : concretes) { if (method.shouldBeInlined()) { return true; } } return false; } private boolean hasSingleMethod() { return concretes.size() == 1 && !shouldFallbackToInvoke(); } private boolean shouldFallbackToInvoke() { return notRecordedTypeProbability > 0; } private Collection<Node> inlineMultipleMethods(StructuredGraph graph, Providers providers) { int numberOfMethods = concretes.size(); FixedNode continuation = invoke.next(); // setup merge and phi nodes for results and exceptions AbstractMergeNode returnMerge = graph.add(new MergeNode()); returnMerge.setStateAfter(invoke.stateAfter()); PhiNode returnValuePhi = null; if (invoke.asNode().getStackKind() != JavaKind.Void) { returnValuePhi = graph.addWithoutUnique(new ValuePhiNode(invoke.asNode().stamp().unrestricted(), returnMerge)); } AbstractMergeNode exceptionMerge = null; PhiNode exceptionObjectPhi = null; if (invoke instanceof InvokeWithExceptionNode) { InvokeWithExceptionNode invokeWithException = (InvokeWithExceptionNode) invoke; ExceptionObjectNode exceptionEdge = (ExceptionObjectNode) invokeWithException.exceptionEdge(); exceptionMerge = graph.add(new MergeNode()); FixedNode exceptionSux = exceptionEdge.next(); graph.addBeforeFixed(exceptionSux, exceptionMerge); exceptionObjectPhi = graph.addWithoutUnique(new ValuePhiNode(StampFactory.forKind(JavaKind.Object), exceptionMerge)); exceptionMerge.setStateAfter(exceptionEdge.stateAfter().duplicateModified(invoke.stateAfter().bci, true, JavaKind.Object, new JavaKind[]{JavaKind.Object}, new ValueNode[]{exceptionObjectPhi})); } // create one separate block for each invoked method AbstractBeginNode[] successors = new AbstractBeginNode[numberOfMethods + 1]; for (int i = 0; i < numberOfMethods; i++) { successors[i] = createInvocationBlock(graph, invoke, returnMerge, returnValuePhi, exceptionMerge, exceptionObjectPhi, true); } // create the successor for an unknown type FixedNode unknownTypeSux; if (shouldFallbackToInvoke()) { unknownTypeSux = createInvocationBlock(graph, invoke, returnMerge, returnValuePhi, exceptionMerge, exceptionObjectPhi, false); } else { unknownTypeSux = graph.add(new DeoptimizeNode(DeoptimizationAction.InvalidateReprofile, DeoptimizationReason.TypeCheckedInliningViolated)); } successors[successors.length - 1] = BeginNode.begin(unknownTypeSux); // replace the invoke exception edge if (invoke instanceof InvokeWithExceptionNode) { InvokeWithExceptionNode invokeWithExceptionNode = (InvokeWithExceptionNode) invoke; ExceptionObjectNode exceptionEdge = (ExceptionObjectNode) invokeWithExceptionNode.exceptionEdge(); exceptionEdge.replaceAtUsages(exceptionObjectPhi); exceptionEdge.setNext(null); GraphUtil.killCFG(invokeWithExceptionNode.exceptionEdge()); } assert invoke.asNode().isAlive(); // replace the invoke with a switch on the type of the actual receiver boolean methodDispatch = createDispatchOnTypeBeforeInvoke(graph, successors, false, providers.getStampProvider(), providers.getConstantReflection()); assert invoke.next() == continuation; invoke.setNext(null); returnMerge.setNext(continuation); if (UseGraalInstrumentation.getValue()) { InliningUtil.removeAttachedInstrumentation(invoke); } if (returnValuePhi != null) { invoke.asNode().replaceAtUsages(returnValuePhi); } invoke.asNode().safeDelete(); ArrayList<GuardedValueNode> replacementNodes = new ArrayList<>(); // prepare the anchors for the invokes for (int i = 0; i < numberOfMethods; i++) { AbstractBeginNode node = successors[i]; Invoke invokeForInlining = (Invoke) node.next(); ResolvedJavaType commonType; if (methodDispatch) { commonType = concretes.get(i).getDeclaringClass(); } else { commonType = getLeastCommonType(i); } ValueNode receiver = ((MethodCallTargetNode) invokeForInlining.callTarget()).receiver(); boolean exact = (getTypeCount(i) == 1 && !methodDispatch); GuardedValueNode anchoredReceiver = InliningUtil.createAnchoredReceiver(graph, node, commonType, receiver, exact); invokeForInlining.callTarget().replaceFirstInput(receiver, anchoredReceiver); assert !anchoredReceiver.isDeleted() : anchoredReceiver; replacementNodes.add(anchoredReceiver); } if (shouldFallbackToInvoke()) { replacementNodes.add(null); } Collection<Node> canonicalizeNodes = new ArrayList<>(); // do the actual inlining for every invoke for (int i = 0; i < numberOfMethods; i++) { Invoke invokeForInlining = (Invoke) successors[i].next(); canonicalizeNodes.addAll(inline(invokeForInlining, methodAt(i), inlineableElementAt(i), false)); } if (returnValuePhi != null) { canonicalizeNodes.add(returnValuePhi); } return canonicalizeNodes; } private int getTypeCount(int concreteMethodIndex) { int count = 0; for (int i = 0; i < typesToConcretes.size(); i++) { if (typesToConcretes.get(i) == concreteMethodIndex) { count++; } } return count; } private ResolvedJavaType getLeastCommonType(int concreteMethodIndex) { ResolvedJavaType commonType = null; for (int i = 0; i < typesToConcretes.size(); i++) { if (typesToConcretes.get(i) == concreteMethodIndex) { if (commonType == null) { commonType = ptypes.get(i).getType(); } else { commonType = commonType.findLeastCommonAncestor(ptypes.get(i).getType()); } } } assert commonType != null; return commonType; } private ResolvedJavaType getLeastCommonType() { ResolvedJavaType result = getLeastCommonType(0); for (int i = 1; i < concretes.size(); i++) { result = result.findLeastCommonAncestor(getLeastCommonType(i)); } return result; } private Collection<Node> inlineSingleMethod(StructuredGraph graph, StampProvider stampProvider, ConstantReflectionProvider constantReflection) { assert concretes.size() == 1 && inlineableElements.length == 1 && ptypes.size() > 1 && !shouldFallbackToInvoke() && notRecordedTypeProbability == 0; AbstractBeginNode calleeEntryNode = graph.add(new BeginNode()); AbstractBeginNode unknownTypeSux = createUnknownTypeSuccessor(graph); AbstractBeginNode[] successors = new AbstractBeginNode[]{calleeEntryNode, unknownTypeSux}; createDispatchOnTypeBeforeInvoke(graph, successors, false, stampProvider, constantReflection); calleeEntryNode.setNext(invoke.asNode()); return inline(invoke, methodAt(0), inlineableElementAt(0), false); } private boolean createDispatchOnTypeBeforeInvoke(StructuredGraph graph, AbstractBeginNode[] successors, boolean invokeIsOnlySuccessor, StampProvider stampProvider, ConstantReflectionProvider constantReflection) { assert ptypes.size() >= 1; ValueNode nonNullReceiver = InliningUtil.nonNullReceiver(invoke); LoadHubNode hub = graph.unique(new LoadHubNode(stampProvider, nonNullReceiver)); Debug.log("Type switch with %d types", concretes.size()); ResolvedJavaType[] keys = new ResolvedJavaType[ptypes.size()]; double[] keyProbabilities = new double[ptypes.size() + 1]; int[] keySuccessors = new int[ptypes.size() + 1]; double totalProbability = notRecordedTypeProbability; for (int i = 0; i < ptypes.size(); i++) { keys[i] = ptypes.get(i).getType(); keyProbabilities[i] = ptypes.get(i).getProbability(); totalProbability += keyProbabilities[i]; keySuccessors[i] = invokeIsOnlySuccessor ? 0 : typesToConcretes.get(i); assert keySuccessors[i] < successors.length - 1 : "last successor is the unknownTypeSux"; } keyProbabilities[keyProbabilities.length - 1] = notRecordedTypeProbability; keySuccessors[keySuccessors.length - 1] = successors.length - 1; // Normalize the probabilities. for (int i = 0; i < keyProbabilities.length; i++) { keyProbabilities[i] /= totalProbability; } TypeSwitchNode typeSwitch = graph.add(new TypeSwitchNode(hub, successors, keys, keyProbabilities, keySuccessors, constantReflection)); FixedWithNextNode pred = (FixedWithNextNode) invoke.asNode().predecessor(); pred.setNext(typeSwitch); return false; } private static AbstractBeginNode createInvocationBlock(StructuredGraph graph, Invoke invoke, AbstractMergeNode returnMerge, PhiNode returnValuePhi, AbstractMergeNode exceptionMerge, PhiNode exceptionObjectPhi, boolean useForInlining) { Invoke duplicatedInvoke = duplicateInvokeForInlining(graph, invoke, exceptionMerge, exceptionObjectPhi, useForInlining); AbstractBeginNode calleeEntryNode = graph.add(new BeginNode()); calleeEntryNode.setNext(duplicatedInvoke.asNode()); EndNode endNode = graph.add(new EndNode()); duplicatedInvoke.setNext(endNode); returnMerge.addForwardEnd(endNode); if (returnValuePhi != null) { returnValuePhi.addInput(duplicatedInvoke.asNode()); } return calleeEntryNode; } private static Invoke duplicateInvokeForInlining(StructuredGraph graph, Invoke invoke, AbstractMergeNode exceptionMerge, PhiNode exceptionObjectPhi, boolean useForInlining) { Invoke result = (Invoke) invoke.asNode().copyWithInputs(); Node callTarget = result.callTarget().copyWithInputs(); result.asNode().replaceFirstInput(result.callTarget(), callTarget); result.setUseForInlining(useForInlining); JavaKind kind = invoke.asNode().getStackKind(); if (kind != JavaKind.Void) { FrameState stateAfter = invoke.stateAfter(); stateAfter = stateAfter.duplicate(stateAfter.bci); stateAfter.replaceFirstInput(invoke.asNode(), result.asNode()); result.setStateAfter(stateAfter); } if (invoke instanceof InvokeWithExceptionNode) { assert exceptionMerge != null && exceptionObjectPhi != null; InvokeWithExceptionNode invokeWithException = (InvokeWithExceptionNode) invoke; ExceptionObjectNode exceptionEdge = (ExceptionObjectNode) invokeWithException.exceptionEdge(); FrameState stateAfterException = exceptionEdge.stateAfter(); ExceptionObjectNode newExceptionEdge = (ExceptionObjectNode) exceptionEdge.copyWithInputs(); // set new state (pop old exception object, push new one) newExceptionEdge.setStateAfter(stateAfterException.duplicateModified(JavaKind.Object, JavaKind.Object, newExceptionEdge)); EndNode endNode = graph.add(new EndNode()); newExceptionEdge.setNext(endNode); exceptionMerge.addForwardEnd(endNode); exceptionObjectPhi.addInput(newExceptionEdge); ((InvokeWithExceptionNode) result).setExceptionEdge(newExceptionEdge); } return result; } @Override public void tryToDevirtualizeInvoke(Providers providers) { if (hasSingleMethod()) { devirtualizeWithTypeSwitch(graph(), InvokeKind.Special, concretes.get(0), providers.getStampProvider(), providers.getConstantReflection()); } else { tryToDevirtualizeMultipleMethods(graph(), providers.getStampProvider(), providers.getConstantReflection()); } } private void tryToDevirtualizeMultipleMethods(StructuredGraph graph, StampProvider stampProvider, ConstantReflectionProvider constantReflection) { MethodCallTargetNode methodCallTarget = (MethodCallTargetNode) invoke.callTarget(); if (methodCallTarget.invokeKind() == InvokeKind.Interface) { ResolvedJavaMethod targetMethod = methodCallTarget.targetMethod(); ResolvedJavaType leastCommonType = getLeastCommonType(); ResolvedJavaType contextType = invoke.getContextType(); // check if we have a common base type that implements the interface -> in that case // we have a vtable entry for the interface method and can use a less expensive // virtual call if (!leastCommonType.isInterface() && targetMethod.getDeclaringClass().isAssignableFrom(leastCommonType)) { ResolvedJavaMethod baseClassTargetMethod = leastCommonType.resolveConcreteMethod(targetMethod, contextType); if (baseClassTargetMethod != null) { devirtualizeWithTypeSwitch(graph, InvokeKind.Virtual, leastCommonType.resolveConcreteMethod(targetMethod, contextType), stampProvider, constantReflection); } } } } private void devirtualizeWithTypeSwitch(StructuredGraph graph, InvokeKind kind, ResolvedJavaMethod target, StampProvider stampProvider, ConstantReflectionProvider constantReflection) { AbstractBeginNode invocationEntry = graph.add(new BeginNode()); AbstractBeginNode unknownTypeSux = createUnknownTypeSuccessor(graph); AbstractBeginNode[] successors = new AbstractBeginNode[]{invocationEntry, unknownTypeSux}; createDispatchOnTypeBeforeInvoke(graph, successors, true, stampProvider, constantReflection); invocationEntry.setNext(invoke.asNode()); ValueNode receiver = ((MethodCallTargetNode) invoke.callTarget()).receiver(); GuardedValueNode anchoredReceiver = InliningUtil.createAnchoredReceiver(graph, invocationEntry, target.getDeclaringClass(), receiver, false); invoke.callTarget().replaceFirstInput(receiver, anchoredReceiver); InliningUtil.replaceInvokeCallTarget(invoke, graph, kind, target); } private static AbstractBeginNode createUnknownTypeSuccessor(StructuredGraph graph) { return BeginNode.begin(graph.add(new DeoptimizeNode(DeoptimizationAction.InvalidateReprofile, DeoptimizationReason.TypeCheckedInliningViolated))); } @Override public String toString() { StringBuilder builder = new StringBuilder(shouldFallbackToInvoke() ? "megamorphic" : "polymorphic"); builder.append(", "); builder.append(concretes.size()); builder.append(" methods [ "); for (int i = 0; i < concretes.size(); i++) { builder.append(concretes.get(i).format(" %H.%n(%p):%r")); } builder.append(" ], "); builder.append(ptypes.size()); builder.append(" type checks [ "); for (int i = 0; i < ptypes.size(); i++) { builder.append(" "); builder.append(ptypes.get(i).getType().getName()); builder.append(ptypes.get(i).getProbability()); } builder.append(" ]"); return builder.toString(); } }