Mercurial > hg > graal-compiler
view graal/com.oracle.graal.java/src/com/oracle/graal/java/BytecodeParser.java @ 21713:454a99ca00a9
fixed canonicalizeprojects issues
author | Doug Simon <doug.simon@oracle.com> |
---|---|
date | Wed, 03 Jun 2015 22:13:10 +0200 |
parents | 8b03b940c29d |
children | d915361cc3a1 |
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/* * Copyright (c) 2009, 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. * * 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.java; import static com.oracle.graal.compiler.common.GraalOptions.*; import static com.oracle.graal.compiler.common.type.StampFactory.*; import static com.oracle.graal.graphbuilderconf.IntrinsicContext.CompilationContext.*; import static com.oracle.graal.java.BytecodeParser.Options.*; import static com.oracle.graal.nodes.StructuredGraph.*; import static com.oracle.graal.nodes.type.StampTool.*; import static com.oracle.jvmci.bytecode.Bytecodes.*; import static com.oracle.jvmci.code.TypeCheckHints.*; import static com.oracle.jvmci.common.JVMCIError.*; import static com.oracle.jvmci.meta.DeoptimizationAction.*; import static com.oracle.jvmci.meta.DeoptimizationReason.*; import static java.lang.String.*; import java.util.*; import com.oracle.graal.compiler.common.*; import com.oracle.graal.compiler.common.calc.*; import com.oracle.graal.compiler.common.type.*; import com.oracle.graal.graph.Graph.Mark; import com.oracle.graal.graph.*; import com.oracle.graal.graph.Node.ValueNumberable; import com.oracle.graal.graph.iterators.*; import com.oracle.graal.graphbuilderconf.*; import com.oracle.graal.graphbuilderconf.InlineInvokePlugin.InlineInfo; import com.oracle.graal.graphbuilderconf.InvocationPlugins.InvocationPluginReceiver; import com.oracle.graal.java.BciBlockMapping.BciBlock; import com.oracle.graal.java.BciBlockMapping.ExceptionDispatchBlock; import com.oracle.graal.nodeinfo.*; import com.oracle.graal.nodes.*; import com.oracle.graal.nodes.CallTargetNode.InvokeKind; import com.oracle.graal.nodes.calc.*; import com.oracle.graal.nodes.extended.*; import com.oracle.graal.nodes.java.*; import com.oracle.graal.nodes.spi.*; import com.oracle.graal.nodes.type.*; import com.oracle.graal.nodes.util.*; import com.oracle.graal.phases.*; import com.oracle.jvmci.bytecode.*; import com.oracle.jvmci.code.*; import com.oracle.jvmci.common.*; import com.oracle.jvmci.debug.*; import com.oracle.jvmci.debug.Debug.Scope; import com.oracle.jvmci.meta.*; import com.oracle.jvmci.options.*; /** * The {@code GraphBuilder} class parses the bytecode of a method and builds the IR graph. */ public class BytecodeParser implements GraphBuilderContext { public static class Options { @Option(help = "The trace level for the bytecode parser used when building a graph from bytecode", type = OptionType.Debug)// public static final OptionValue<Integer> TraceBytecodeParserLevel = new OptionValue<>(0); @Option(help = "Inlines trivial methods during bytecode parsing.", type = OptionType.Expert)// public static final StableOptionValue<Boolean> InlineDuringParsing = new StableOptionValue<>(true); @Option(help = "Inlines intrinsic methods during bytecode parsing.", type = OptionType.Expert)// public static final StableOptionValue<Boolean> InlineIntrinsicsDuringParsing = new StableOptionValue<>(true); @Option(help = "Traces inlining performed during bytecode parsing.", type = OptionType.Debug)// public static final StableOptionValue<Boolean> TraceInlineDuringParsing = new StableOptionValue<>(false); @Option(help = "Traces use of plugins during bytecode parsing.", type = OptionType.Debug)// public static final StableOptionValue<Boolean> TraceParserPlugins = new StableOptionValue<>(false); @Option(help = "Maximum depth when inlining during bytecode parsing.", type = OptionType.Debug)// public static final StableOptionValue<Integer> InlineDuringParsingMaxDepth = new StableOptionValue<>(10); @Option(help = "Dump graphs after non-trivial changes during bytecode parsing.", type = OptionType.Debug)// public static final StableOptionValue<Boolean> DumpDuringGraphBuilding = new StableOptionValue<>(false); @Option(help = "Max number of loop explosions per method.", type = OptionType.Debug)// public static final OptionValue<Integer> MaximumLoopExplosionCount = new OptionValue<>(10000); @Option(help = "Do not bail out but throw an exception on failed loop explosion.", type = OptionType.Debug)// public static final OptionValue<Boolean> FailedLoopExplosionIsFatal = new OptionValue<>(false); @Option(help = "When creating info points hide the methods of the substitutions.", type = OptionType.Debug)// public static final OptionValue<Boolean> HideSubstitutionStates = new OptionValue<>(false); } /** * The minimum value to which {@link Options#TraceBytecodeParserLevel} must be set to trace the * bytecode instructions as they are parsed. */ public static final int TRACELEVEL_INSTRUCTIONS = 1; /** * The minimum value to which {@link Options#TraceBytecodeParserLevel} must be set to trace the * frame state before each bytecode instruction as it is parsed. */ public static final int TRACELEVEL_STATE = 2; /** * Meters the number of actual bytecodes parsed. */ public static final DebugMetric BytecodesParsed = Debug.metric("BytecodesParsed"); protected static final DebugMetric EXPLICIT_EXCEPTIONS = Debug.metric("ExplicitExceptions"); /** * A scoped object for tasks to be performed after parsing an intrinsic such as processing * {@linkplain BytecodeFrame#isPlaceholderBci(int) placeholder} frames states. */ static class IntrinsicScope implements AutoCloseable { FrameState stateBefore; final Mark mark; final BytecodeParser parser; /** * Creates a scope for root parsing an intrinsic. * * @param parser the parsing context of the intrinsic */ public IntrinsicScope(BytecodeParser parser) { this.parser = parser; assert parser.parent == null; assert parser.bci() == 0; mark = null; } /** * Creates a scope for parsing an intrinsic during graph builder inlining. * * @param parser the parsing context of the (non-intrinsic) method calling the intrinsic * @param args the arguments to the call */ public IntrinsicScope(BytecodeParser parser, Kind[] argSlotKinds, ValueNode[] args) { assert !parser.parsingIntrinsic(); this.parser = parser; mark = parser.getGraph().getMark(); stateBefore = parser.frameState.create(parser.bci(), parser.getNonIntrinsicAncestor(), false, argSlotKinds, args); } public void close() { IntrinsicContext intrinsic = parser.intrinsicContext; if (intrinsic != null && intrinsic.isPostParseInlined()) { return; } processPlaceholderFrameStates(intrinsic); } /** * Fixes up the {@linkplain BytecodeFrame#isPlaceholderBci(int) placeholder} frame states * added to the graph while parsing/inlining the intrinsic for which this object exists. */ private void processPlaceholderFrameStates(IntrinsicContext intrinsic) { FrameState stateAfterReturn = null; StructuredGraph graph = parser.getGraph(); for (Node node : graph.getNewNodes(mark)) { if (node instanceof FrameState) { FrameState frameState = (FrameState) node; if (BytecodeFrame.isPlaceholderBci(frameState.bci)) { if (frameState.bci == BytecodeFrame.AFTER_BCI) { FrameStateBuilder frameStateBuilder = parser.frameState; if (frameState.stackSize() != 0) { assert frameState.usages().count() == 1; ValueNode returnVal = frameState.stackAt(0); assert returnVal == frameState.usages().first(); /* * Swap the top-of-stack value with the side-effect return value * using the frame state. */ Kind returnKind = parser.currentInvokeReturnType.getKind(); ValueNode tos = frameStateBuilder.pop(returnKind); assert tos.getKind() == returnVal.getKind(); FrameState newFrameState = frameStateBuilder.create(parser.stream.nextBCI(), parser.getNonIntrinsicAncestor(), false, new Kind[]{returnKind}, new ValueNode[]{returnVal}); frameState.replaceAndDelete(newFrameState); frameStateBuilder.push(returnKind, tos); } else { if (stateAfterReturn == null) { if (intrinsic != null) { assert intrinsic.isCompilationRoot(); stateAfterReturn = graph.add(new FrameState(BytecodeFrame.INVALID_FRAMESTATE_BCI)); } else { stateAfterReturn = frameStateBuilder.create(parser.stream.nextBCI(), null); } } frameState.replaceAndDelete(stateAfterReturn); } } else if (frameState.bci == BytecodeFrame.BEFORE_BCI) { if (stateBefore == null) { stateBefore = graph.start().stateAfter(); } if (stateBefore != frameState) { frameState.replaceAndDelete(stateBefore); } } else { assert frameState.bci == BytecodeFrame.INVALID_FRAMESTATE_BCI; } } } } } } private static class Target { FixedNode fixed; FrameStateBuilder state; public Target(FixedNode fixed, FrameStateBuilder state) { this.fixed = fixed; this.state = state; } } private static class ExplodedLoopContext { private BciBlock header; private int[] targetPeelIteration; private int peelIteration; } @SuppressWarnings("serial") public static class BytecodeParserError extends JVMCIError { public BytecodeParserError(Throwable cause) { super(cause); } public BytecodeParserError(String msg, Object... args) { super(msg, args); } } private final GraphBuilderPhase.Instance graphBuilderInstance; protected final StructuredGraph graph; private BciBlockMapping blockMap; private LocalLiveness liveness; protected final int entryBCI; private final BytecodeParser parent; private LineNumberTable lnt; private int previousLineNumber; private int currentLineNumber; private ValueNode methodSynchronizedObject; private ValueNode returnValue; private FixedWithNextNode beforeReturnNode; private ValueNode unwindValue; private FixedWithNextNode beforeUnwindNode; private FixedWithNextNode lastInstr; // the last instruction added private final boolean explodeLoops; private final boolean mergeExplosions; private final Map<FrameStateBuilder, Integer> mergeExplosionsMap; private Deque<ExplodedLoopContext> explodeLoopsContext; private int nextPeelIteration = 1; private boolean controlFlowSplit; private final InvocationPluginReceiver invocationPluginReceiver = new InvocationPluginReceiver(this); private FixedWithNextNode[] firstInstructionArray; private FrameStateBuilder[] entryStateArray; private FixedWithNextNode[][] firstInstructionMatrix; private FrameStateBuilder[][] entryStateMatrix; protected BytecodeParser(GraphBuilderPhase.Instance graphBuilderInstance, StructuredGraph graph, BytecodeParser parent, ResolvedJavaMethod method, int entryBCI, IntrinsicContext intrinsicContext) { this.graphBuilderInstance = graphBuilderInstance; this.graph = graph; this.graphBuilderConfig = graphBuilderInstance.graphBuilderConfig; this.optimisticOpts = graphBuilderInstance.optimisticOpts; this.metaAccess = graphBuilderInstance.metaAccess; this.stampProvider = graphBuilderInstance.stampProvider; this.constantReflection = graphBuilderInstance.constantReflection; this.stream = new BytecodeStream(method.getCode()); this.profilingInfo = (graphBuilderConfig.getUseProfiling() ? method.getProfilingInfo() : null); this.constantPool = method.getConstantPool(); this.method = method; this.intrinsicContext = intrinsicContext; this.entryBCI = entryBCI; this.parent = parent; assert method.getCode() != null : "method must contain bytecodes: " + method; if (graphBuilderConfig.insertNonSafepointDebugInfo() && !parsingIntrinsic()) { lnt = method.getLineNumberTable(); previousLineNumber = -1; } LoopExplosionPlugin loopExplosionPlugin = graphBuilderConfig.getPlugins().getLoopExplosionPlugin(); if (loopExplosionPlugin != null) { explodeLoops = loopExplosionPlugin.shouldExplodeLoops(method); if (explodeLoops) { mergeExplosions = loopExplosionPlugin.shouldMergeExplosions(method); mergeExplosionsMap = new HashMap<>(); } else { mergeExplosions = false; mergeExplosionsMap = null; } } else { explodeLoops = false; mergeExplosions = false; mergeExplosionsMap = null; } } public ValueNode getReturnValue() { return returnValue; } public FixedWithNextNode getBeforeReturnNode() { return this.beforeReturnNode; } public ValueNode getUnwindValue() { return unwindValue; } public FixedWithNextNode getBeforeUnwindNode() { return this.beforeUnwindNode; } protected void buildRootMethod() { FrameStateBuilder startFrameState = new FrameStateBuilder(this, method, graph); startFrameState.initializeForMethodStart(graphBuilderConfig.eagerResolving() || intrinsicContext != null, graphBuilderConfig.getPlugins().getParameterPlugins()); try (IntrinsicScope s = intrinsicContext != null ? new IntrinsicScope(this) : null) { build(graph.start(), startFrameState); } cleanupFinalGraph(); ComputeLoopFrequenciesClosure.compute(graph); } protected void build(FixedWithNextNode startInstruction, FrameStateBuilder startFrameState) { if (PrintProfilingInformation.getValue() && profilingInfo != null) { TTY.println("Profiling info for " + method.format("%H.%n(%p)")); TTY.println(MetaUtil.indent(profilingInfo.toString(method, CodeUtil.NEW_LINE), " ")); } try (Indent indent = Debug.logAndIndent("build graph for %s", method)) { // compute the block map, setup exception handlers and get the entrypoint(s) BciBlockMapping newMapping = BciBlockMapping.create(stream, method); this.blockMap = newMapping; this.firstInstructionArray = new FixedWithNextNode[blockMap.getBlockCount()]; this.entryStateArray = new FrameStateBuilder[blockMap.getBlockCount()]; /* * Configure the assertion checking behavior of the FrameStateBuilder. This needs to be * done only when assertions are enabled, so it is wrapped in an assertion itself. */ assert computeKindVerification(startFrameState); try (Scope s = Debug.scope("LivenessAnalysis")) { int maxLocals = method.getMaxLocals(); liveness = LocalLiveness.compute(stream, blockMap.getBlocks(), maxLocals, blockMap.getLoopCount()); } catch (Throwable e) { throw Debug.handle(e); } lastInstr = startInstruction; this.setCurrentFrameState(startFrameState); stream.setBCI(0); BciBlock startBlock = blockMap.getStartBlock(); if (this.parent == null) { StartNode startNode = graph.start(); if (method.isSynchronized()) { assert !parsingIntrinsic(); startNode.setStateAfter(createFrameState(BytecodeFrame.BEFORE_BCI, startNode)); } else { if (!parsingIntrinsic()) { if (graph.method() != null && graph.method().isJavaLangObjectInit()) { /* * Don't clear the receiver when Object.<init> is the compilation root. * The receiver is needed as input to RegisterFinalizerNode. */ } else { frameState.clearNonLiveLocals(startBlock, liveness, true); } assert bci() == 0; startNode.setStateAfter(createFrameState(bci(), startNode)); } else { if (startNode.stateAfter() == null) { FrameState stateAfterStart = createStateAfterStartOfReplacementGraph(); startNode.setStateAfter(stateAfterStart); } } } } if (method.isSynchronized()) { // add a monitor enter to the start block methodSynchronizedObject = synchronizedObject(frameState, method); frameState.clearNonLiveLocals(startBlock, liveness, true); assert bci() == 0; genMonitorEnter(methodSynchronizedObject, bci()); } finishPrepare(lastInstr); if (graphBuilderConfig.insertNonSafepointDebugInfo() && !parsingIntrinsic()) { genInfoPointNode(InfopointReason.METHOD_START, null); } currentBlock = blockMap.getStartBlock(); setEntryState(startBlock, 0, frameState); if (startBlock.isLoopHeader && !explodeLoops) { appendGoto(startBlock); } else { setFirstInstruction(startBlock, 0, lastInstr); } int index = 0; BciBlock[] blocks = blockMap.getBlocks(); while (index < blocks.length) { BciBlock block = blocks[index]; index = iterateBlock(blocks, block); } if (this.mergeExplosions) { Debug.dump(graph, "Before loop detection"); detectLoops(startInstruction); } if (Debug.isDumpEnabled() && DumpDuringGraphBuilding.getValue() && this.beforeReturnNode != startInstruction) { Debug.dump(graph, "Bytecodes parsed: " + method.getDeclaringClass().getUnqualifiedName() + "." + method.getName()); } } } private boolean computeKindVerification(FrameStateBuilder startFrameState) { if (blockMap.hasJsrBytecodes) { /* * The JSR return address is an int value, but stored using the astore bytecode. Instead * of weakening the kind assertion checking for all methods, we disable it completely * for methods that contain a JSR bytecode. */ startFrameState.disableKindVerification(); } for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.canChangeStackKind(this)) { /* * We have a plugin that can change the kind of values, so no kind assertion * checking is possible. */ startFrameState.disableKindVerification(); } } return true; } /** * Hook for subclasses to modify the graph start instruction or append new instructions to it. * * @param startInstr the start instruction of the graph */ protected void finishPrepare(FixedWithNextNode startInstr) { } protected void cleanupFinalGraph() { GraphUtil.normalizeLoops(graph); // Remove dead parameters. for (ParameterNode param : graph.getNodes(ParameterNode.TYPE)) { if (param.hasNoUsages()) { assert param.inputs().isEmpty(); param.safeDelete(); } } // Remove redundant begin nodes. Debug.dump(graph, "Before removing redundant begins"); for (BeginNode beginNode : graph.getNodes(BeginNode.TYPE)) { Node predecessor = beginNode.predecessor(); if (predecessor instanceof ControlSplitNode) { // The begin node is necessary. } else { if (beginNode.hasUsages()) { reanchorGuardedNodes(beginNode); } GraphUtil.unlinkFixedNode(beginNode); beginNode.safeDelete(); } } } /** * Removes {@link GuardedNode}s from {@code beginNode}'s usages and re-attaches them to an * appropriate preceeding {@link GuardingNode}. */ protected void reanchorGuardedNodes(BeginNode beginNode) { // Find the new guarding node GuardingNode guarding = null; Node pred = beginNode.predecessor(); while (pred != null) { if (pred instanceof BeginNode) { if (pred.predecessor() instanceof ControlSplitNode) { guarding = (GuardingNode) pred; break; } } else if (pred.getNodeClass().getAllowedUsageTypes().contains(InputType.Guard)) { guarding = (GuardingNode) pred; break; } pred = pred.predecessor(); } // Reset the guard for all of beginNode's usages for (Node usage : beginNode.usages().snapshot()) { GuardedNode guarded = (GuardedNode) usage; assert guarded.getGuard() == beginNode; guarded.setGuard(guarding); } assert beginNode.hasNoUsages() : beginNode; } /** * Creates the frame state after the start node of a graph for an {@link IntrinsicContext * intrinsic} that is the parse root (either for root compiling or for post-parse inlining). */ private FrameState createStateAfterStartOfReplacementGraph() { assert parent == null; assert frameState.getMethod().equals(intrinsicContext.getIntrinsicMethod()); assert bci() == 0; assert frameState.stackSize() == 0; FrameState stateAfterStart; if (intrinsicContext.isPostParseInlined()) { stateAfterStart = graph.add(new FrameState(BytecodeFrame.BEFORE_BCI)); } else { ResolvedJavaMethod original = intrinsicContext.getOriginalMethod(); ValueNode[] locals; if (original.getMaxLocals() == frameState.localsSize() || original.isNative()) { locals = new ValueNode[original.getMaxLocals()]; for (int i = 0; i < locals.length; i++) { ValueNode node = frameState.locals[i]; if (node == FrameState.TWO_SLOT_MARKER) { node = null; } locals[i] = node; } locals = frameState.locals; } else { locals = new ValueNode[original.getMaxLocals()]; int parameterCount = original.getSignature().getParameterCount(!original.isStatic()); for (int i = 0; i < parameterCount; i++) { ValueNode param = frameState.locals[i]; if (param == FrameState.TWO_SLOT_MARKER) { param = null; } locals[i] = param; assert param == null || param instanceof ParameterNode || param.isConstant(); } } ValueNode[] stack = {}; int stackSize = 0; ValueNode[] locks = {}; List<MonitorIdNode> monitorIds = Collections.emptyList(); stateAfterStart = graph.add(new FrameState(null, original, 0, locals, stack, stackSize, locks, monitorIds, false, false)); } return stateAfterStart; } private void detectLoops(FixedNode startInstruction) { NodeBitMap visited = graph.createNodeBitMap(); NodeBitMap active = graph.createNodeBitMap(); Deque<Node> stack = new ArrayDeque<>(); stack.add(startInstruction); visited.mark(startInstruction); while (!stack.isEmpty()) { Node next = stack.peek(); assert next.isDeleted() || visited.isMarked(next); if (next.isDeleted() || active.isMarked(next)) { stack.pop(); if (!next.isDeleted()) { active.clear(next); } } else { active.mark(next); for (Node n : next.cfgSuccessors()) { if (active.contains(n)) { // Detected cycle. assert n instanceof MergeNode; assert next instanceof EndNode; MergeNode merge = (MergeNode) n; EndNode endNode = (EndNode) next; merge.removeEnd(endNode); FixedNode afterMerge = merge.next(); if (!(afterMerge instanceof EndNode) || !(((EndNode) afterMerge).merge() instanceof LoopBeginNode)) { merge.setNext(null); LoopBeginNode newLoopBegin = this.appendLoopBegin(merge); newLoopBegin.setNext(afterMerge); } LoopBeginNode loopBegin = (LoopBeginNode) ((EndNode) merge.next()).merge(); LoopEndNode loopEnd = graph.add(new LoopEndNode(loopBegin)); if (parsingIntrinsic()) { loopEnd.disableSafepoint(); } endNode.replaceAndDelete(loopEnd); } else if (visited.contains(n)) { // Normal merge into a branch we are already exploring. } else { visited.mark(n); stack.push(n); } } } } Debug.dump(graph, "After loops detected"); insertLoopEnds(startInstruction); } private void insertLoopEnds(FixedNode startInstruction) { NodeBitMap visited = graph.createNodeBitMap(); Deque<Node> stack = new ArrayDeque<>(); stack.add(startInstruction); visited.mark(startInstruction); List<LoopBeginNode> loopBegins = new ArrayList<>(); while (!stack.isEmpty()) { Node next = stack.pop(); assert visited.isMarked(next); if (next instanceof LoopBeginNode) { loopBegins.add((LoopBeginNode) next); } for (Node n : next.cfgSuccessors()) { if (visited.contains(n)) { // Nothing to do. } else { visited.mark(n); stack.push(n); } } } IdentityHashMap<LoopBeginNode, List<LoopBeginNode>> innerLoopsMap = new IdentityHashMap<>(); for (int i = loopBegins.size() - 1; i >= 0; --i) { LoopBeginNode loopBegin = loopBegins.get(i); insertLoopExits(loopBegin, innerLoopsMap); if (DumpDuringGraphBuilding.getValue()) { Debug.dump(graph, "After building loop exits for %s.", loopBegin); } } // Remove degenerated merges with only one predecessor. for (LoopBeginNode loopBegin : loopBegins) { Node pred = loopBegin.forwardEnd().predecessor(); if (pred instanceof MergeNode) { MergeNode.removeMergeIfDegenerated((MergeNode) pred); } } } private void insertLoopExits(LoopBeginNode loopBegin, IdentityHashMap<LoopBeginNode, List<LoopBeginNode>> innerLoopsMap) { NodeBitMap visited = graph.createNodeBitMap(); Deque<Node> stack = new ArrayDeque<>(); for (LoopEndNode loopEnd : loopBegin.loopEnds()) { stack.push(loopEnd); visited.mark(loopEnd); } List<ControlSplitNode> controlSplits = new ArrayList<>(); List<LoopBeginNode> innerLoopBegins = new ArrayList<>(); while (!stack.isEmpty()) { Node current = stack.pop(); if (current == loopBegin) { continue; } for (Node pred : current.cfgPredecessors()) { if (!visited.isMarked(pred)) { visited.mark(pred); if (pred instanceof LoopExitNode) { // Inner loop LoopExitNode loopExitNode = (LoopExitNode) pred; LoopBeginNode innerLoopBegin = loopExitNode.loopBegin(); if (!visited.isMarked(innerLoopBegin)) { stack.push(innerLoopBegin); visited.mark(innerLoopBegin); innerLoopBegins.add(innerLoopBegin); } } else { if (pred instanceof ControlSplitNode) { ControlSplitNode controlSplitNode = (ControlSplitNode) pred; controlSplits.add(controlSplitNode); } stack.push(pred); } } } } for (ControlSplitNode controlSplit : controlSplits) { for (Node succ : controlSplit.cfgSuccessors()) { if (!visited.isMarked(succ)) { LoopExitNode loopExit = graph.add(new LoopExitNode(loopBegin)); FixedNode next = ((FixedWithNextNode) succ).next(); next.replaceAtPredecessor(loopExit); loopExit.setNext(next); } } } for (LoopBeginNode inner : innerLoopBegins) { addLoopExits(loopBegin, inner, innerLoopsMap, visited); if (DumpDuringGraphBuilding.getValue()) { Debug.dump(graph, "After adding loop exits for %s.", inner); } } innerLoopsMap.put(loopBegin, innerLoopBegins); } private void addLoopExits(LoopBeginNode loopBegin, LoopBeginNode inner, IdentityHashMap<LoopBeginNode, List<LoopBeginNode>> innerLoopsMap, NodeBitMap visited) { for (LoopExitNode exit : inner.loopExits()) { if (!visited.isMarked(exit)) { LoopExitNode newLoopExit = graph.add(new LoopExitNode(loopBegin)); FixedNode next = exit.next(); next.replaceAtPredecessor(newLoopExit); newLoopExit.setNext(next); } } for (LoopBeginNode innerInner : innerLoopsMap.get(inner)) { addLoopExits(loopBegin, innerInner, innerLoopsMap, visited); } } private int iterateBlock(BciBlock[] blocks, BciBlock block) { if (block.isLoopHeader && this.explodeLoops) { return iterateExplodedLoopHeader(blocks, block); } else { processBlock(this, block); return block.getId() + 1; } } private int iterateExplodedLoopHeader(BciBlock[] blocks, BciBlock header) { if (explodeLoopsContext == null) { explodeLoopsContext = new ArrayDeque<>(); } ExplodedLoopContext context = new ExplodedLoopContext(); context.header = header; context.peelIteration = this.getCurrentDimension(); if (this.mergeExplosions) { this.addToMergeCache(getEntryState(context.header, context.peelIteration), context.peelIteration); } explodeLoopsContext.push(context); if (Debug.isDumpEnabled() && DumpDuringGraphBuilding.getValue()) { Debug.dump(graph, "before loop explosion dimension " + context.peelIteration); } peelIteration(blocks, header, context); explodeLoopsContext.pop(); return header.loopEnd + 1; } private void addToMergeCache(FrameStateBuilder key, int dimension) { mergeExplosionsMap.put(key, dimension); } private void peelIteration(BciBlock[] blocks, BciBlock header, ExplodedLoopContext context) { while (true) { if (TraceParserPlugins.getValue()) { traceWithContext("exploding loop, iteration %d", context.peelIteration); } processBlock(this, header); int j = header.getId() + 1; while (j <= header.loopEnd) { BciBlock block = blocks[j]; j = iterateBlock(blocks, block); } int[] targets = context.targetPeelIteration; if (targets != null) { // We were reaching the backedge during explosion. Explode further. for (int i = 0; i < targets.length; ++i) { context.peelIteration = targets[i]; context.targetPeelIteration = null; if (Debug.isDumpEnabled() && DumpDuringGraphBuilding.getValue()) { Debug.dump(graph, "next loop explosion iteration " + context.peelIteration); } if (i < targets.length - 1) { peelIteration(blocks, header, context); } } } else { // We did not reach the backedge. Exit. break; } } } /** * @param type the unresolved type of the constant */ protected void handleUnresolvedLoadConstant(JavaType type) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param type the unresolved type of the type check * @param object the object value whose type is being checked against {@code type} */ protected void handleUnresolvedCheckCast(JavaType type, ValueNode object) { assert !graphBuilderConfig.eagerResolving(); append(new FixedGuardNode(graph.unique(new IsNullNode(object)), Unresolved, InvalidateRecompile)); frameState.push(Kind.Object, appendConstant(JavaConstant.NULL_POINTER)); } /** * @param type the unresolved type of the type check * @param object the object value whose type is being checked against {@code type} */ protected void handleUnresolvedInstanceOf(JavaType type, ValueNode object) { assert !graphBuilderConfig.eagerResolving(); AbstractBeginNode successor = graph.add(new BeginNode()); DeoptimizeNode deopt = graph.add(new DeoptimizeNode(InvalidateRecompile, Unresolved)); append(new IfNode(graph.unique(new IsNullNode(object)), successor, deopt, 1)); lastInstr = successor; frameState.push(Kind.Int, appendConstant(JavaConstant.INT_0)); } /** * @param type the type being instantiated */ protected void handleUnresolvedNewInstance(JavaType type) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param type the type of the array being instantiated * @param length the length of the array */ protected void handleUnresolvedNewObjectArray(JavaType type, ValueNode length) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param type the type being instantiated * @param dims the dimensions for the multi-array */ protected void handleUnresolvedNewMultiArray(JavaType type, List<ValueNode> dims) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param field the unresolved field * @param receiver the object containing the field or {@code null} if {@code field} is static */ protected void handleUnresolvedLoadField(JavaField field, ValueNode receiver) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param field the unresolved field * @param value the value being stored to the field * @param receiver the object containing the field or {@code null} if {@code field} is static */ protected void handleUnresolvedStoreField(JavaField field, ValueNode value, ValueNode receiver) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param type */ protected void handleUnresolvedExceptionType(JavaType type) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } /** * @param javaMethod * @param invokeKind */ protected void handleUnresolvedInvoke(JavaMethod javaMethod, InvokeKind invokeKind) { assert !graphBuilderConfig.eagerResolving(); append(new DeoptimizeNode(InvalidateRecompile, Unresolved)); } private DispatchBeginNode handleException(ValueNode exceptionObject, int bci) { assert bci == BytecodeFrame.BEFORE_BCI || bci == bci() : "invalid bci"; Debug.log("Creating exception dispatch edges at %d, exception object=%s, exception seen=%s", bci, exceptionObject, (profilingInfo == null ? "" : profilingInfo.getExceptionSeen(bci))); BciBlock dispatchBlock = currentBlock.exceptionDispatchBlock(); /* * The exception dispatch block is always for the last bytecode of a block, so if we are not * at the endBci yet, there is no exception handler for this bci and we can unwind * immediately. */ if (bci != currentBlock.endBci || dispatchBlock == null) { dispatchBlock = blockMap.getUnwindBlock(); } FrameStateBuilder dispatchState = frameState.copy(); dispatchState.clearStack(); DispatchBeginNode dispatchBegin; if (exceptionObject == null) { dispatchBegin = graph.add(new ExceptionObjectNode(metaAccess)); dispatchState.push(Kind.Object, dispatchBegin); dispatchState.setRethrowException(true); dispatchBegin.setStateAfter(dispatchState.create(bci, dispatchBegin)); } else { dispatchBegin = graph.add(new DispatchBeginNode()); dispatchState.push(Kind.Object, exceptionObject); dispatchBegin.setStateAfter(dispatchState.create(bci, dispatchBegin)); dispatchState.setRethrowException(true); } this.controlFlowSplit = true; FixedNode target = createTarget(dispatchBlock, dispatchState); FixedWithNextNode finishedDispatch = finishInstruction(dispatchBegin, dispatchState); finishedDispatch.setNext(target); return dispatchBegin; } protected ValueNode genLoadIndexed(ValueNode array, ValueNode index, Kind kind) { return LoadIndexedNode.create(array, index, kind, metaAccess, constantReflection); } protected void genStoreIndexed(ValueNode array, ValueNode index, Kind kind, ValueNode value) { add(new StoreIndexedNode(array, index, kind, value)); } protected ValueNode genIntegerAdd(ValueNode x, ValueNode y) { return AddNode.create(x, y); } protected ValueNode genIntegerSub(ValueNode x, ValueNode y) { return SubNode.create(x, y); } protected ValueNode genIntegerMul(ValueNode x, ValueNode y) { return MulNode.create(x, y); } protected ValueNode genFloatAdd(ValueNode x, ValueNode y) { return AddNode.create(x, y); } protected ValueNode genFloatSub(ValueNode x, ValueNode y) { return SubNode.create(x, y); } protected ValueNode genFloatMul(ValueNode x, ValueNode y) { return MulNode.create(x, y); } protected ValueNode genFloatDiv(ValueNode x, ValueNode y) { return DivNode.create(x, y); } protected ValueNode genFloatRem(ValueNode x, ValueNode y) { return new RemNode(x, y); } protected ValueNode genIntegerDiv(ValueNode x, ValueNode y) { return new IntegerDivNode(x, y); } protected ValueNode genIntegerRem(ValueNode x, ValueNode y) { return new IntegerRemNode(x, y); } protected ValueNode genNegateOp(ValueNode x) { return (new NegateNode(x)); } protected ValueNode genLeftShift(ValueNode x, ValueNode y) { return new LeftShiftNode(x, y); } protected ValueNode genRightShift(ValueNode x, ValueNode y) { return new RightShiftNode(x, y); } protected ValueNode genUnsignedRightShift(ValueNode x, ValueNode y) { return new UnsignedRightShiftNode(x, y); } protected ValueNode genAnd(ValueNode x, ValueNode y) { return AndNode.create(x, y); } protected ValueNode genOr(ValueNode x, ValueNode y) { return OrNode.create(x, y); } protected ValueNode genXor(ValueNode x, ValueNode y) { return XorNode.create(x, y); } protected ValueNode genNormalizeCompare(ValueNode x, ValueNode y, boolean isUnorderedLess) { return NormalizeCompareNode.create(x, y, isUnorderedLess, constantReflection); } protected ValueNode genFloatConvert(FloatConvert op, ValueNode input) { return FloatConvertNode.create(op, input); } protected ValueNode genNarrow(ValueNode input, int bitCount) { return NarrowNode.create(input, bitCount); } protected ValueNode genSignExtend(ValueNode input, int bitCount) { return SignExtendNode.create(input, bitCount); } protected ValueNode genZeroExtend(ValueNode input, int bitCount) { return ZeroExtendNode.create(input, bitCount); } protected void genGoto() { appendGoto(currentBlock.getSuccessor(0)); assert currentBlock.numNormalSuccessors() == 1; } protected LogicNode genObjectEquals(ValueNode x, ValueNode y) { return ObjectEqualsNode.create(x, y, constantReflection); } protected LogicNode genIntegerEquals(ValueNode x, ValueNode y) { return IntegerEqualsNode.create(x, y, constantReflection); } protected LogicNode genIntegerLessThan(ValueNode x, ValueNode y) { return IntegerLessThanNode.create(x, y, constantReflection); } protected ValueNode genUnique(ValueNode x) { return (ValueNode) graph.unique((Node & ValueNumberable) x); } protected ValueNode genIfNode(LogicNode condition, FixedNode falseSuccessor, FixedNode trueSuccessor, double d) { return new IfNode(condition, falseSuccessor, trueSuccessor, d); } protected void genThrow() { genInfoPointNode(InfopointReason.LINE_NUMBER, null); ValueNode exception = frameState.pop(Kind.Object); append(new FixedGuardNode(graph.unique(new IsNullNode(exception)), NullCheckException, InvalidateReprofile, true)); lastInstr.setNext(handleException(exception, bci())); } protected ValueNode createCheckCast(ResolvedJavaType type, ValueNode object, JavaTypeProfile profileForTypeCheck, boolean forStoreCheck) { return CheckCastNode.create(type, object, profileForTypeCheck, forStoreCheck, graph.getAssumptions()); } protected ValueNode createInstanceOf(ResolvedJavaType type, ValueNode object, JavaTypeProfile profileForTypeCheck) { return InstanceOfNode.create(type, object, profileForTypeCheck); } protected ValueNode genConditional(ValueNode x) { return new ConditionalNode((LogicNode) x); } protected NewInstanceNode createNewInstance(ResolvedJavaType type, boolean fillContents) { return new NewInstanceNode(type, fillContents); } protected NewArrayNode createNewArray(ResolvedJavaType elementType, ValueNode length, boolean fillContents) { return new NewArrayNode(elementType, length, fillContents); } protected NewMultiArrayNode createNewMultiArray(ResolvedJavaType type, List<ValueNode> dimensions) { return new NewMultiArrayNode(type, dimensions.toArray(new ValueNode[0])); } protected ValueNode genLoadField(ValueNode receiver, ResolvedJavaField field) { return new LoadFieldNode(receiver, field); } protected ValueNode emitExplicitNullCheck(ValueNode receiver) { if (StampTool.isPointerNonNull(receiver.stamp())) { return receiver; } BytecodeExceptionNode exception = graph.add(new BytecodeExceptionNode(metaAccess, NullPointerException.class)); AbstractBeginNode falseSucc = graph.add(new BeginNode()); PiNode nonNullReceiver = graph.unique(new PiNode(receiver, receiver.stamp().join(objectNonNull()))); nonNullReceiver.setGuard(falseSucc); append(new IfNode(graph.unique(new IsNullNode(receiver)), exception, falseSucc, 0.01)); lastInstr = falseSucc; exception.setStateAfter(createFrameState(bci(), exception)); exception.setNext(handleException(exception, bci())); return nonNullReceiver; } protected void emitExplicitBoundsCheck(ValueNode index, ValueNode length) { AbstractBeginNode trueSucc = graph.add(new BeginNode()); BytecodeExceptionNode exception = graph.add(new BytecodeExceptionNode(metaAccess, ArrayIndexOutOfBoundsException.class, index)); append(new IfNode(graph.unique(IntegerBelowNode.create(index, length, constantReflection)), trueSucc, exception, 0.99)); lastInstr = trueSucc; exception.setStateAfter(createFrameState(bci(), exception)); exception.setNext(handleException(exception, bci())); } protected ValueNode genArrayLength(ValueNode x) { return ArrayLengthNode.create(x, constantReflection); } protected void genStoreField(ValueNode receiver, ResolvedJavaField field, ValueNode value) { StoreFieldNode storeFieldNode = new StoreFieldNode(receiver, field, value); append(storeFieldNode); storeFieldNode.setStateAfter(this.createFrameState(stream.nextBCI(), storeFieldNode)); } /** * Ensure that concrete classes are at least linked before generating an invoke. Interfaces may * never be linked so simply return true for them. * * @param target * @return true if the declared holder is an interface or is linked */ private static boolean callTargetIsResolved(JavaMethod target) { if (target instanceof ResolvedJavaMethod) { ResolvedJavaMethod resolvedTarget = (ResolvedJavaMethod) target; ResolvedJavaType resolvedType = resolvedTarget.getDeclaringClass(); return resolvedType.isInterface() || resolvedType.isLinked(); } return false; } protected void genInvokeStatic(JavaMethod target) { if (callTargetIsResolved(target)) { ResolvedJavaMethod resolvedTarget = (ResolvedJavaMethod) target; ResolvedJavaType holder = resolvedTarget.getDeclaringClass(); if (!holder.isInitialized() && ResolveClassBeforeStaticInvoke.getValue()) { handleUnresolvedInvoke(target, InvokeKind.Static); } else { ValueNode[] args = frameState.popArguments(resolvedTarget.getSignature().getParameterCount(false)); appendInvoke(InvokeKind.Static, resolvedTarget, args); } } else { handleUnresolvedInvoke(target, InvokeKind.Static); } } protected void genInvokeInterface(JavaMethod target) { if (callTargetIsResolved(target)) { ValueNode[] args = frameState.popArguments(target.getSignature().getParameterCount(true)); appendInvoke(InvokeKind.Interface, (ResolvedJavaMethod) target, args); } else { handleUnresolvedInvoke(target, InvokeKind.Interface); } } protected void genInvokeDynamic(JavaMethod target) { if (target instanceof ResolvedJavaMethod) { JavaConstant appendix = constantPool.lookupAppendix(stream.readCPI4(), Bytecodes.INVOKEDYNAMIC); if (appendix != null) { frameState.push(Kind.Object, ConstantNode.forConstant(appendix, metaAccess, graph)); } ValueNode[] args = frameState.popArguments(target.getSignature().getParameterCount(false)); appendInvoke(InvokeKind.Static, (ResolvedJavaMethod) target, args); } else { handleUnresolvedInvoke(target, InvokeKind.Static); } } protected void genInvokeVirtual(JavaMethod target) { if (callTargetIsResolved(target)) { /* * Special handling for runtimes that rewrite an invocation of MethodHandle.invoke(...) * or MethodHandle.invokeExact(...) to a static adapter. HotSpot does this - see * https://wikis.oracle.com/display/HotSpotInternals/Method+handles +and+invokedynamic */ boolean hasReceiver = !((ResolvedJavaMethod) target).isStatic(); JavaConstant appendix = constantPool.lookupAppendix(stream.readCPI(), Bytecodes.INVOKEVIRTUAL); if (appendix != null) { frameState.push(Kind.Object, ConstantNode.forConstant(appendix, metaAccess, graph)); } ValueNode[] args = frameState.popArguments(target.getSignature().getParameterCount(hasReceiver)); if (hasReceiver) { appendInvoke(InvokeKind.Virtual, (ResolvedJavaMethod) target, args); } else { appendInvoke(InvokeKind.Static, (ResolvedJavaMethod) target, args); } } else { handleUnresolvedInvoke(target, InvokeKind.Virtual); } } protected void genInvokeSpecial(JavaMethod target) { if (callTargetIsResolved(target)) { assert target != null; assert target.getSignature() != null; ValueNode[] args = frameState.popArguments(target.getSignature().getParameterCount(true)); appendInvoke(InvokeKind.Special, (ResolvedJavaMethod) target, args); } else { handleUnresolvedInvoke(target, InvokeKind.Special); } } private InvokeKind currentInvokeKind; private JavaType currentInvokeReturnType; protected FrameStateBuilder frameState; protected BciBlock currentBlock; protected final BytecodeStream stream; protected final GraphBuilderConfiguration graphBuilderConfig; protected final ResolvedJavaMethod method; protected final ProfilingInfo profilingInfo; protected final OptimisticOptimizations optimisticOpts; protected final ConstantPool constantPool; protected final MetaAccessProvider metaAccess; private final ConstantReflectionProvider constantReflection; private final StampProvider stampProvider; protected final IntrinsicContext intrinsicContext; public InvokeKind getInvokeKind() { return currentInvokeKind; } public JavaType getInvokeReturnType() { return currentInvokeReturnType; } public void handleReplacedInvoke(InvokeKind invokeKind, ResolvedJavaMethod targetMethod, ValueNode[] args) { appendInvoke(invokeKind, targetMethod, args); } private void appendInvoke(InvokeKind initialInvokeKind, ResolvedJavaMethod initialTargetMethod, ValueNode[] args) { ResolvedJavaMethod targetMethod = initialTargetMethod; InvokeKind invokeKind = initialInvokeKind; if (initialInvokeKind.isIndirect()) { ResolvedJavaType contextType = this.frameState.getMethod().getDeclaringClass(); ResolvedJavaMethod specialCallTarget = MethodCallTargetNode.findSpecialCallTarget(initialInvokeKind, args[0], initialTargetMethod, contextType); if (specialCallTarget != null) { invokeKind = InvokeKind.Special; targetMethod = specialCallTarget; } } Kind resultType = targetMethod.getSignature().getReturnKind(); if (DeoptALot.getValue()) { append(new DeoptimizeNode(DeoptimizationAction.None, RuntimeConstraint)); frameState.pushReturn(resultType, ConstantNode.defaultForKind(resultType, graph)); return; } JavaType returnType = targetMethod.getSignature().getReturnType(method.getDeclaringClass()); if (graphBuilderConfig.eagerResolving() || parsingIntrinsic()) { returnType = returnType.resolve(targetMethod.getDeclaringClass()); } if (invokeKind.hasReceiver()) { args[0] = emitExplicitExceptions(args[0], null); if (invokeKind.isIndirect() && profilingInfo != null && this.optimisticOpts.useTypeCheckHints()) { JavaTypeProfile profile = profilingInfo.getTypeProfile(bci()); args[0] = TypeProfileProxyNode.proxify(args[0], profile); } if (args[0].isNullConstant()) { append(new DeoptimizeNode(InvalidateRecompile, NullCheckException)); return; } } try { currentInvokeReturnType = returnType; currentInvokeKind = invokeKind; if (tryNodePluginForInvocation(args, targetMethod)) { if (TraceParserPlugins.getValue()) { traceWithContext("used node plugin for %s", targetMethod.format("%h.%n(%p)")); } return; } if (invokeKind.isDirect()) { if (tryInvocationPlugin(args, targetMethod, resultType)) { if (TraceParserPlugins.getValue()) { traceWithContext("used invocation plugin for %s", targetMethod.format("%h.%n(%p)")); } return; } if (tryInline(args, targetMethod, returnType)) { return; } } } finally { currentInvokeReturnType = null; currentInvokeKind = null; } MethodCallTargetNode callTarget = graph.add(createMethodCallTarget(invokeKind, targetMethod, args, returnType)); // be conservative if information was not recorded (could result in endless // recompiles otherwise) Invoke invoke; if (graphBuilderConfig.omitAllExceptionEdges() || (!StressInvokeWithExceptionNode.getValue() && optimisticOpts.useExceptionProbability() && profilingInfo != null && profilingInfo.getExceptionSeen(bci()) == TriState.FALSE)) { invoke = createInvoke(callTarget, resultType); } else { invoke = createInvokeWithException(callTarget, resultType); AbstractBeginNode beginNode = graph.add(new KillingBeginNode(LocationIdentity.any())); invoke.setNext(beginNode); lastInstr = beginNode; } for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) { plugin.notifyNotInlined(this, targetMethod, invoke); } } /** * Contains all the assertion checking logic around the application of an * {@link InvocationPlugin}. This class is only loaded when assertions are enabled. */ class InvocationPluginAssertions { final InvocationPlugin plugin; final ValueNode[] args; final ResolvedJavaMethod targetMethod; final Kind resultType; final int beforeStackSize; final boolean needsNullCheck; final int nodeCount; final Mark mark; public InvocationPluginAssertions(InvocationPlugin plugin, ValueNode[] args, ResolvedJavaMethod targetMethod, Kind resultType) { guarantee(assertionsEnabled(), "%s should only be loaded and instantiated if assertions are enabled", getClass().getSimpleName()); this.plugin = plugin; this.targetMethod = targetMethod; this.args = args; this.resultType = resultType; this.beforeStackSize = frameState.stackSize(); this.needsNullCheck = !targetMethod.isStatic() && args[0].getKind() == Kind.Object && !StampTool.isPointerNonNull(args[0].stamp()); this.nodeCount = graph.getNodeCount(); this.mark = graph.getMark(); } String error(String format, Object... a) { return String.format(format, a) + String.format("%n\tplugin at %s", plugin.getApplySourceLocation(metaAccess)); } boolean check(boolean pluginResult) { if (pluginResult == true) { int expectedStackSize = beforeStackSize + resultType.getSlotCount(); assert expectedStackSize == frameState.stackSize() : error("plugin manipulated the stack incorrectly: expected=%d, actual=%d", expectedStackSize, frameState.stackSize()); NodeIterable<Node> newNodes = graph.getNewNodes(mark); assert !needsNullCheck || isPointerNonNull(args[0].stamp()) : error("plugin needs to null check the receiver of %s: receiver=%s", targetMethod.format("%H.%n(%p)"), args[0]); for (Node n : newNodes) { if (n instanceof StateSplit) { StateSplit stateSplit = (StateSplit) n; assert stateSplit.stateAfter() != null || !stateSplit.hasSideEffect() : error("%s node added by plugin for %s need to have a non-null frame state: %s", StateSplit.class.getSimpleName(), targetMethod.format("%H.%n(%p)"), stateSplit); } } try { graphBuilderConfig.getPlugins().getInvocationPlugins().checkNewNodes(BytecodeParser.this, plugin, newNodes); } catch (Throwable t) { throw new AssertionError(error("Error in plugin"), t); } } else { assert nodeCount == graph.getNodeCount() : error("plugin that returns false must not create new nodes"); assert beforeStackSize == frameState.stackSize() : error("plugin that returns false must not modify the stack"); } return true; } } private boolean tryInvocationPlugin(ValueNode[] args, ResolvedJavaMethod targetMethod, Kind resultType) { InvocationPlugin plugin = graphBuilderConfig.getPlugins().getInvocationPlugins().lookupInvocation(targetMethod); if (plugin != null) { if (intrinsicContext != null && intrinsicContext.isCallToOriginal(targetMethod)) { // Self recursive intrinsic means the original // method should be called. assert !targetMethod.hasBytecodes() : "TODO: when does this happen?"; return false; } InvocationPluginAssertions assertions = assertionsEnabled() ? new InvocationPluginAssertions(plugin, args, targetMethod, resultType) : null; if (plugin.execute(this, targetMethod, invocationPluginReceiver.init(targetMethod, args), args)) { assert assertions.check(true); return true; } assert assertions.check(false); } return false; } private boolean tryNodePluginForInvocation(ValueNode[] args, ResolvedJavaMethod targetMethod) { for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleInvoke(this, targetMethod, args)) { return true; } } return false; } private boolean tryInline(ValueNode[] args, ResolvedJavaMethod targetMethod, JavaType returnType) { boolean canBeInlined = parsingIntrinsic() || targetMethod.canBeInlined(); if (!canBeInlined) { return false; } for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) { InlineInfo inlineInfo = plugin.shouldInlineInvoke(this, targetMethod, args, returnType); if (inlineInfo != null) { if (inlineInfo.getMethodToInline() == null) { /* Do not inline, and do not ask the remaining plugins. */ return false; } else { return inline(targetMethod, inlineInfo.getMethodToInline(), inlineInfo.isIntrinsic(), args); } } } return false; } public void intrinsify(ResolvedJavaMethod targetMethod, ResolvedJavaMethod substitute, ValueNode[] args) { boolean res = inline(targetMethod, substitute, true, args); assert res : "failed to inline " + substitute; } private boolean inline(ResolvedJavaMethod targetMethod, ResolvedJavaMethod inlinedMethod, boolean isIntrinsic, ValueNode[] args) { if (TraceInlineDuringParsing.getValue() || TraceParserPlugins.getValue()) { if (targetMethod.equals(inlinedMethod)) { traceWithContext("inlining call to %s", inlinedMethod.format("%h.%n(%p)")); } else { traceWithContext("inlining call to %s as intrinsic for %s", inlinedMethod.format("%h.%n(%p)"), targetMethod.format("%h.%n(%p)")); } } IntrinsicContext intrinsic = this.intrinsicContext; if (intrinsic != null && intrinsic.isCallToOriginal(targetMethod)) { if (intrinsic.isCompilationRoot()) { // A root compiled intrinsic needs to deoptimize // if the slow path is taken. During frame state // assignment, the deopt node will get its stateBefore // from the start node of the intrinsic append(new DeoptimizeNode(InvalidateRecompile, RuntimeConstraint)); return true; } else { // Otherwise inline the original method. Any frame state created // during the inlining will exclude frame(s) in the // intrinsic method (see HIRFrameStateBuilder.create(int bci)). if (intrinsic.getOriginalMethod().isNative()) { return false; } parseAndInlineCallee(intrinsic.getOriginalMethod(), args, null); return true; } } else { if (intrinsic == null && isIntrinsic) { assert !inlinedMethod.equals(targetMethod); intrinsic = new IntrinsicContext(targetMethod, inlinedMethod, INLINE_DURING_PARSING); } if (inlinedMethod.hasBytecodes()) { for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) { plugin.notifyBeforeInline(inlinedMethod); } parseAndInlineCallee(inlinedMethod, args, intrinsic); for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) { plugin.notifyAfterInline(inlinedMethod); } } else { return false; } } return true; } /** * Prints a line to {@link TTY} with a prefix indicating the current parse context. The prefix * is of the form: * * <pre> * {SPACE * n} {name of method being parsed} "(" {file name} ":" {line number} ")" * </pre> * * where {@code n} is the current inlining depth. * * @param format a format string * @param args arguments to the format string */ protected void traceWithContext(String format, Object... args) { StackTraceElement where = method.asStackTraceElement(bci()); TTY.println(format("%s%s (%s:%d) %s", nSpaces(getDepth()), method.isConstructor() ? method.format("%h.%n") : method.getName(), where.getFileName(), where.getLineNumber(), format(format, args))); } protected BytecodeParserError asParserError(Throwable e) { if (e instanceof BytecodeParserError) { return (BytecodeParserError) e; } BytecodeParser bp = this; BytecodeParserError res = new BytecodeParserError(e); while (bp != null) { res.addContext("parsing " + bp.method.asStackTraceElement(bp.bci())); bp = bp.parent; } return res; } private void parseAndInlineCallee(ResolvedJavaMethod targetMethod, ValueNode[] args, IntrinsicContext calleeIntrinsicContext) { try (IntrinsicScope s = calleeIntrinsicContext != null && !parsingIntrinsic() ? new IntrinsicScope(this, targetMethod.getSignature().toParameterKinds(!targetMethod.isStatic()), args) : null) { BytecodeParser parser = graphBuilderInstance.createBytecodeParser(graph, this, targetMethod, INVOCATION_ENTRY_BCI, calleeIntrinsicContext); FrameStateBuilder startFrameState = new FrameStateBuilder(parser, targetMethod, graph); if (!targetMethod.isStatic()) { args[0] = nullCheckedValue(args[0]); } startFrameState.initializeFromArgumentsArray(args); parser.build(this.lastInstr, startFrameState); FixedWithNextNode calleeBeforeReturnNode = parser.getBeforeReturnNode(); this.lastInstr = calleeBeforeReturnNode; Kind calleeReturnKind = targetMethod.getSignature().getReturnKind(); if (calleeBeforeReturnNode != null) { ValueNode calleeReturnValue = parser.getReturnValue(); if (calleeReturnValue != null) { frameState.push(calleeReturnKind.getStackKind(), calleeReturnValue); } } FixedWithNextNode calleeBeforeUnwindNode = parser.getBeforeUnwindNode(); if (calleeBeforeUnwindNode != null) { ValueNode calleeUnwindValue = parser.getUnwindValue(); assert calleeUnwindValue != null; calleeBeforeUnwindNode.setNext(handleException(calleeUnwindValue, bci())); } // Record inlined method dependency in the graph graph.recordInlinedMethod(targetMethod); } } protected MethodCallTargetNode createMethodCallTarget(InvokeKind invokeKind, ResolvedJavaMethod targetMethod, ValueNode[] args, JavaType returnType) { return new MethodCallTargetNode(invokeKind, targetMethod, args, returnType); } protected InvokeNode createInvoke(CallTargetNode callTarget, Kind resultType) { InvokeNode invoke = append(new InvokeNode(callTarget, bci())); frameState.pushReturn(resultType, invoke); invoke.setStateAfter(createFrameState(stream.nextBCI(), invoke)); return invoke; } protected InvokeWithExceptionNode createInvokeWithException(CallTargetNode callTarget, Kind resultType) { if (currentBlock != null && stream.nextBCI() > currentBlock.endBci) { /* * Clear non-live locals early so that the exception handler entry gets the cleared * state. */ frameState.clearNonLiveLocals(currentBlock, liveness, false); } DispatchBeginNode exceptionEdge = handleException(null, bci()); InvokeWithExceptionNode invoke = append(new InvokeWithExceptionNode(callTarget, exceptionEdge, bci())); frameState.pushReturn(resultType, invoke); invoke.setStateAfter(createFrameState(stream.nextBCI(), invoke)); return invoke; } protected void genReturn(ValueNode returnVal, Kind returnKind) { if (parsingIntrinsic() && returnVal != null) { if (returnVal instanceof StateSplit) { StateSplit stateSplit = (StateSplit) returnVal; FrameState stateAfter = stateSplit.stateAfter(); if (stateSplit.hasSideEffect()) { assert stateSplit != null; if (stateAfter.bci == BytecodeFrame.AFTER_BCI) { assert stateAfter.usages().count() == 1; assert stateAfter.usages().first() == stateSplit; stateAfter.replaceAtUsages(graph.add(new FrameState(BytecodeFrame.AFTER_BCI, returnVal))); GraphUtil.killWithUnusedFloatingInputs(stateAfter); } else { /* * This must be the return value from within a partial intrinsification. */ assert !BytecodeFrame.isPlaceholderBci(stateAfter.bci); } } else { assert stateAfter == null; } } } if (parent == null) { frameState.setRethrowException(false); frameState.clearStack(); beforeReturn(returnVal, returnKind); append(new ReturnNode(returnVal)); } else { if (blockMap.getReturnCount() == 1 || !controlFlowSplit) { // There is only a single return. beforeReturn(returnVal, returnKind); this.returnValue = returnVal; this.beforeReturnNode = this.lastInstr; this.lastInstr = null; } else { frameState.setRethrowException(false); frameState.clearStack(); if (returnVal != null) { frameState.push(returnKind, returnVal); } assert blockMap.getReturnCount() > 1; appendGoto(blockMap.getReturnBlock()); } } } private void beforeReturn(ValueNode x, Kind kind) { if (graph.method() != null && graph.method().isJavaLangObjectInit()) { append(new RegisterFinalizerNode(frameState.loadLocal(0, Kind.Object))); } if (graphBuilderConfig.insertNonSafepointDebugInfo() && !parsingIntrinsic()) { genInfoPointNode(InfopointReason.METHOD_END, x); } synchronizedEpilogue(BytecodeFrame.AFTER_BCI, x, kind); if (frameState.lockDepth() != 0) { throw bailout("unbalanced monitors"); } } protected void genMonitorEnter(ValueNode x, int bci) { MonitorIdNode monitorId = graph.add(new MonitorIdNode(frameState.lockDepth())); MonitorEnterNode monitorEnter = append(new MonitorEnterNode(x, monitorId)); frameState.pushLock(x, monitorId); monitorEnter.setStateAfter(createFrameState(bci, monitorEnter)); } protected void genMonitorExit(ValueNode x, ValueNode escapedReturnValue, int bci) { MonitorIdNode monitorId = frameState.peekMonitorId(); ValueNode lockedObject = frameState.popLock(); if (GraphUtil.originalValue(lockedObject) != GraphUtil.originalValue(x)) { throw bailout(String.format("unbalanced monitors: mismatch at monitorexit, %s != %s", GraphUtil.originalValue(x), GraphUtil.originalValue(lockedObject))); } MonitorExitNode monitorExit = append(new MonitorExitNode(x, monitorId, escapedReturnValue)); monitorExit.setStateAfter(createFrameState(bci, monitorExit)); } protected void genJsr(int dest) { BciBlock successor = currentBlock.getJsrSuccessor(); assert successor.startBci == dest : successor.startBci + " != " + dest + " @" + bci(); JsrScope scope = currentBlock.getJsrScope(); int nextBci = getStream().nextBCI(); if (!successor.getJsrScope().pop().equals(scope)) { throw new JsrNotSupportedBailout("unstructured control flow (internal limitation)"); } if (successor.getJsrScope().nextReturnAddress() != nextBci) { throw new JsrNotSupportedBailout("unstructured control flow (internal limitation)"); } ConstantNode nextBciNode = getJsrConstant(nextBci); frameState.push(Kind.Object, nextBciNode); appendGoto(successor); } protected void genRet(int localIndex) { BciBlock successor = currentBlock.getRetSuccessor(); ValueNode local = frameState.loadLocal(localIndex, Kind.Object); JsrScope scope = currentBlock.getJsrScope(); int retAddress = scope.nextReturnAddress(); ConstantNode returnBciNode = getJsrConstant(retAddress); LogicNode guard = IntegerEqualsNode.create(local, returnBciNode, constantReflection); guard = graph.unique(guard); append(new FixedGuardNode(guard, JavaSubroutineMismatch, InvalidateReprofile)); if (!successor.getJsrScope().equals(scope.pop())) { throw new JsrNotSupportedBailout("unstructured control flow (ret leaves more than one scope)"); } appendGoto(successor); } private ConstantNode getJsrConstant(long bci) { JavaConstant nextBciConstant = new RawConstant(bci); Stamp nextBciStamp = StampFactory.forConstant(nextBciConstant); ConstantNode nextBciNode = new ConstantNode(nextBciConstant, nextBciStamp); return graph.unique(nextBciNode); } protected void genIntegerSwitch(ValueNode value, ArrayList<BciBlock> actualSuccessors, int[] keys, double[] keyProbabilities, int[] keySuccessors) { if (value.isConstant()) { JavaConstant constant = (JavaConstant) value.asConstant(); int constantValue = constant.asInt(); for (int i = 0; i < keys.length; ++i) { if (keys[i] == constantValue) { appendGoto(actualSuccessors.get(keySuccessors[i])); return; } } appendGoto(actualSuccessors.get(keySuccessors[keys.length])); } else { this.controlFlowSplit = true; double[] successorProbabilities = successorProbabilites(actualSuccessors.size(), keySuccessors, keyProbabilities); IntegerSwitchNode switchNode = append(new IntegerSwitchNode(value, actualSuccessors.size(), keys, keyProbabilities, keySuccessors)); for (int i = 0; i < actualSuccessors.size(); i++) { switchNode.setBlockSuccessor(i, createBlockTarget(successorProbabilities[i], actualSuccessors.get(i), frameState)); } } } /** * Helper function that sums up the probabilities of all keys that lead to a specific successor. * * @return an array of size successorCount with the accumulated probability for each successor. */ private static double[] successorProbabilites(int successorCount, int[] keySuccessors, double[] keyProbabilities) { double[] probability = new double[successorCount]; for (int i = 0; i < keySuccessors.length; i++) { probability[keySuccessors[i]] += keyProbabilities[i]; } return probability; } protected ConstantNode appendConstant(JavaConstant constant) { assert constant != null; return ConstantNode.forConstant(constant, metaAccess, graph); } @Override public <T extends ValueNode> T append(T v) { if (v.graph() != null) { return v; } T added = graph.addOrUnique(v); if (added == v) { updateLastInstruction(v); } return added; } public <T extends ValueNode> T recursiveAppend(T v) { if (v.graph() != null) { return v; } T added = graph.addOrUniqueWithInputs(v); if (added == v) { updateLastInstruction(v); } return added; } private <T extends ValueNode> void updateLastInstruction(T v) { if (v instanceof FixedNode) { FixedNode fixedNode = (FixedNode) v; lastInstr.setNext(fixedNode); if (fixedNode instanceof FixedWithNextNode) { FixedWithNextNode fixedWithNextNode = (FixedWithNextNode) fixedNode; assert fixedWithNextNode.next() == null : "cannot append instruction to instruction which isn't end"; lastInstr = fixedWithNextNode; } else { lastInstr = null; } } } private Target checkLoopExit(FixedNode target, BciBlock targetBlock, FrameStateBuilder state) { if (currentBlock != null && !explodeLoops) { long exits = currentBlock.loops & ~targetBlock.loops; if (exits != 0) { LoopExitNode firstLoopExit = null; LoopExitNode lastLoopExit = null; int pos = 0; ArrayList<BciBlock> exitLoops = new ArrayList<>(Long.bitCount(exits)); do { long lMask = 1L << pos; if ((exits & lMask) != 0) { exitLoops.add(blockMap.getLoopHeader(pos)); exits &= ~lMask; } pos++; } while (exits != 0); Collections.sort(exitLoops, new Comparator<BciBlock>() { @Override public int compare(BciBlock o1, BciBlock o2) { return Long.bitCount(o2.loops) - Long.bitCount(o1.loops); } }); int bci = targetBlock.startBci; if (targetBlock instanceof ExceptionDispatchBlock) { bci = ((ExceptionDispatchBlock) targetBlock).deoptBci; } FrameStateBuilder newState = state.copy(); for (BciBlock loop : exitLoops) { LoopBeginNode loopBegin = (LoopBeginNode) getFirstInstruction(loop, this.getCurrentDimension()); LoopExitNode loopExit = graph.add(new LoopExitNode(loopBegin)); if (lastLoopExit != null) { lastLoopExit.setNext(loopExit); } if (firstLoopExit == null) { firstLoopExit = loopExit; } lastLoopExit = loopExit; Debug.log("Target %s Exits %s, scanning framestates...", targetBlock, loop); newState.insertLoopProxies(loopExit, getEntryState(loop, this.getCurrentDimension())); loopExit.setStateAfter(newState.create(bci, loopExit)); } lastLoopExit.setNext(target); return new Target(firstLoopExit, newState); } } return new Target(target, state); } private FrameStateBuilder getEntryState(BciBlock block, int dimension) { int id = block.id; if (dimension == 0) { return entryStateArray[id]; } else { return getEntryStateMultiDimension(dimension, id); } } private FrameStateBuilder getEntryStateMultiDimension(int dimension, int id) { if (entryStateMatrix != null && dimension - 1 < entryStateMatrix.length) { FrameStateBuilder[] entryStateArrayEntry = entryStateMatrix[dimension - 1]; if (entryStateArrayEntry == null) { return null; } return entryStateArrayEntry[id]; } else { return null; } } private void setEntryState(BciBlock block, int dimension, FrameStateBuilder entryState) { int id = block.id; if (dimension == 0) { this.entryStateArray[id] = entryState; } else { setEntryStateMultiDimension(dimension, entryState, id); } } private void setEntryStateMultiDimension(int dimension, FrameStateBuilder entryState, int id) { if (entryStateMatrix == null) { entryStateMatrix = new FrameStateBuilder[4][]; } if (dimension - 1 < entryStateMatrix.length) { // We are within bounds. } else { // We are out of bounds. entryStateMatrix = Arrays.copyOf(entryStateMatrix, Math.max(entryStateMatrix.length * 2, dimension)); } if (entryStateMatrix[dimension - 1] == null) { entryStateMatrix[dimension - 1] = new FrameStateBuilder[blockMap.getBlockCount()]; } entryStateMatrix[dimension - 1][id] = entryState; } private void setFirstInstruction(BciBlock block, int dimension, FixedWithNextNode firstInstruction) { int id = block.id; if (dimension == 0) { this.firstInstructionArray[id] = firstInstruction; } else { setFirstInstructionMultiDimension(dimension, firstInstruction, id); } } private void setFirstInstructionMultiDimension(int dimension, FixedWithNextNode firstInstruction, int id) { if (firstInstructionMatrix == null) { firstInstructionMatrix = new FixedWithNextNode[4][]; } if (dimension - 1 < firstInstructionMatrix.length) { // We are within bounds. } else { // We are out of bounds. firstInstructionMatrix = Arrays.copyOf(firstInstructionMatrix, Math.max(firstInstructionMatrix.length * 2, dimension)); } if (firstInstructionMatrix[dimension - 1] == null) { firstInstructionMatrix[dimension - 1] = new FixedWithNextNode[blockMap.getBlockCount()]; } firstInstructionMatrix[dimension - 1][id] = firstInstruction; } private FixedWithNextNode getFirstInstruction(BciBlock block, int dimension) { int id = block.id; if (dimension == 0) { return firstInstructionArray[id]; } else { return getFirstInstructionMultiDimension(dimension, id); } } private FixedWithNextNode getFirstInstructionMultiDimension(int dimension, int id) { if (firstInstructionMatrix != null && dimension - 1 < firstInstructionMatrix.length) { FixedWithNextNode[] firstInstructionArrayEntry = firstInstructionMatrix[dimension - 1]; if (firstInstructionArrayEntry == null) { return null; } return firstInstructionArrayEntry[id]; } else { return null; } } private FixedNode createTarget(double probability, BciBlock block, FrameStateBuilder stateAfter) { assert probability >= 0 && probability <= 1.01 : probability; if (isNeverExecutedCode(probability)) { return graph.add(new DeoptimizeNode(InvalidateReprofile, UnreachedCode)); } else { assert block != null; return createTarget(block, stateAfter); } } private FixedNode createTarget(BciBlock block, FrameStateBuilder state) { return createTarget(block, state, false, false); } private FixedNode createTarget(BciBlock block, FrameStateBuilder state, boolean canReuseInstruction, boolean canReuseState) { assert block != null && state != null; assert !block.isExceptionEntry || state.stackSize() == 1; int operatingDimension = findOperatingDimension(block, state); if (getFirstInstruction(block, operatingDimension) == null) { /* * This is the first time we see this block as a branch target. Create and return a * placeholder that later can be replaced with a MergeNode when we see this block again. */ FixedNode targetNode; if (canReuseInstruction && (block.getPredecessorCount() == 1 || !controlFlowSplit) && !block.isLoopHeader && (currentBlock.loops & ~block.loops) == 0) { setFirstInstruction(block, operatingDimension, lastInstr); lastInstr = null; } else { setFirstInstruction(block, operatingDimension, graph.add(new BeginNode())); } targetNode = getFirstInstruction(block, operatingDimension); Target target = checkLoopExit(targetNode, block, state); FixedNode result = target.fixed; FrameStateBuilder currentEntryState = target.state == state ? (canReuseState ? state : state.copy()) : target.state; setEntryState(block, operatingDimension, currentEntryState); currentEntryState.clearNonLiveLocals(block, liveness, true); Debug.log("createTarget %s: first visit, result: %s", block, targetNode); return result; } // We already saw this block before, so we have to merge states. if (!getEntryState(block, operatingDimension).isCompatibleWith(state)) { throw bailout("stacks do not match; bytecodes would not verify"); } if (getFirstInstruction(block, operatingDimension) instanceof LoopBeginNode) { assert this.explodeLoops || (block.isLoopHeader && currentBlock.getId() >= block.getId()) : "must be backward branch"; /* * Backward loop edge. We need to create a special LoopEndNode and merge with the loop * begin node created before. */ LoopBeginNode loopBegin = (LoopBeginNode) getFirstInstruction(block, operatingDimension); LoopEndNode loopEnd = graph.add(new LoopEndNode(loopBegin)); if (parsingIntrinsic()) { loopEnd.disableSafepoint(); } Target target = checkLoopExit(loopEnd, block, state); FixedNode result = target.fixed; getEntryState(block, operatingDimension).merge(loopBegin, target.state); Debug.log("createTarget %s: merging backward branch to loop header %s, result: %s", block, loopBegin, result); return result; } assert currentBlock == null || currentBlock.getId() < block.getId() || this.mergeExplosions : "must not be backward branch"; assert getFirstInstruction(block, operatingDimension).next() == null || this.mergeExplosions : "bytecodes already parsed for block"; if (getFirstInstruction(block, operatingDimension) instanceof AbstractBeginNode && !(getFirstInstruction(block, operatingDimension) instanceof AbstractMergeNode)) { /* * This is the second time we see this block. Create the actual MergeNode and the End * Node for the already existing edge. */ AbstractBeginNode beginNode = (AbstractBeginNode) getFirstInstruction(block, operatingDimension); // The EndNode for the already existing edge. EndNode end = graph.add(new EndNode()); // The MergeNode that replaces the placeholder. AbstractMergeNode mergeNode = graph.add(new MergeNode()); FixedNode next = beginNode.next(); if (beginNode.predecessor() instanceof ControlSplitNode) { beginNode.setNext(end); } else { beginNode.replaceAtPredecessor(end); beginNode.safeDelete(); } mergeNode.addForwardEnd(end); mergeNode.setNext(next); setFirstInstruction(block, operatingDimension, mergeNode); } AbstractMergeNode mergeNode = (AbstractMergeNode) getFirstInstruction(block, operatingDimension); // The EndNode for the newly merged edge. EndNode newEnd = graph.add(new EndNode()); Target target = checkLoopExit(newEnd, block, state); FixedNode result = target.fixed; getEntryState(block, operatingDimension).merge(mergeNode, target.state); mergeNode.addForwardEnd(newEnd); Debug.log("createTarget %s: merging state, result: %s", block, result); return result; } private int findOperatingDimension(BciBlock block, FrameStateBuilder state) { if (this.explodeLoops && this.explodeLoopsContext != null && !this.explodeLoopsContext.isEmpty()) { return findOperatingDimensionWithLoopExplosion(block, state); } return this.getCurrentDimension(); } private int findOperatingDimensionWithLoopExplosion(BciBlock block, FrameStateBuilder state) { for (ExplodedLoopContext context : explodeLoopsContext) { if (context.header == block) { if (this.mergeExplosions) { state.clearNonLiveLocals(block, liveness, true); Integer cachedDimension = mergeExplosionsMap.get(state); if (cachedDimension != null) { return cachedDimension; } } // We have a hit on our current explosion context loop begin. if (context.targetPeelIteration == null) { context.targetPeelIteration = new int[1]; } else { context.targetPeelIteration = Arrays.copyOf(context.targetPeelIteration, context.targetPeelIteration.length + 1); } // This is the first hit => allocate a new dimension and at the same // time mark the context loop begin as hit during the current // iteration. if (this.mergeExplosions) { this.addToMergeCache(state, nextPeelIteration); } context.targetPeelIteration[context.targetPeelIteration.length - 1] = nextPeelIteration++; if (nextPeelIteration > MaximumLoopExplosionCount.getValue()) { String message = "too many loop explosion iterations - does the explosion not terminate for method " + method + "?"; if (FailedLoopExplosionIsFatal.getValue()) { throw new RuntimeException(message); } else { throw bailout(message); } } // Operate on the target dimension. return context.targetPeelIteration[context.targetPeelIteration.length - 1]; } else if (block.getId() > context.header.getId() && block.getId() <= context.header.loopEnd) { // We hit the range of this context. return context.peelIteration; } } // No dimension found. return 0; } /** * Returns a block begin node with the specified state. If the specified probability is 0, the * block deoptimizes immediately. */ private AbstractBeginNode createBlockTarget(double probability, BciBlock block, FrameStateBuilder stateAfter) { FixedNode target = createTarget(probability, block, stateAfter); AbstractBeginNode begin = BeginNode.begin(target); assert !(target instanceof DeoptimizeNode && begin instanceof BeginStateSplitNode && ((BeginStateSplitNode) begin).stateAfter() != null) : "We are not allowed to set the stateAfter of the begin node, because we have to deoptimize " + "to a bci _before_ the actual if, so that the interpreter can update the profiling information."; return begin; } private ValueNode synchronizedObject(FrameStateBuilder state, ResolvedJavaMethod target) { if (target.isStatic()) { return appendConstant(target.getDeclaringClass().getJavaClass()); } else { return state.loadLocal(0, Kind.Object); } } protected void processBlock(BytecodeParser parser, BciBlock block) { // Ignore blocks that have no predecessors by the time their bytecodes are parsed int currentDimension = this.getCurrentDimension(); FixedWithNextNode firstInstruction = getFirstInstruction(block, currentDimension); if (firstInstruction == null) { Debug.log("Ignoring block %s", block); return; } try (Indent indent = Debug.logAndIndent("Parsing block %s firstInstruction: %s loopHeader: %b", block, firstInstruction, block.isLoopHeader)) { lastInstr = firstInstruction; frameState = getEntryState(block, currentDimension); frameState.cleanDeletedNodes(); parser.setCurrentFrameState(frameState); currentBlock = block; if (firstInstruction instanceof AbstractMergeNode) { setMergeStateAfter(block, firstInstruction); } if (block == blockMap.getReturnBlock()) { handleReturnBlock(); } else if (block == blockMap.getUnwindBlock()) { handleUnwindBlock(); } else if (block instanceof ExceptionDispatchBlock) { createExceptionDispatch((ExceptionDispatchBlock) block); } else { frameState.setRethrowException(false); iterateBytecodesForBlock(block); } } } private void handleUnwindBlock() { if (parent == null) { frameState.setRethrowException(false); createUnwind(); } else { ValueNode exception = frameState.pop(Kind.Object); this.unwindValue = exception; this.beforeUnwindNode = this.lastInstr; } } private void handleReturnBlock() { Kind returnKind = method.getSignature().getReturnKind().getStackKind(); ValueNode x = returnKind == Kind.Void ? null : frameState.pop(returnKind); assert frameState.stackSize() == 0; beforeReturn(x, returnKind); this.returnValue = x; this.beforeReturnNode = this.lastInstr; } private void setMergeStateAfter(BciBlock block, FixedWithNextNode firstInstruction) { AbstractMergeNode abstractMergeNode = (AbstractMergeNode) firstInstruction; if (abstractMergeNode.stateAfter() == null) { int bci = block.startBci; if (block instanceof ExceptionDispatchBlock) { bci = ((ExceptionDispatchBlock) block).deoptBci; } abstractMergeNode.setStateAfter(createFrameState(bci, abstractMergeNode)); } } private void createUnwind() { assert frameState.stackSize() == 1 : frameState; ValueNode exception = frameState.pop(Kind.Object); synchronizedEpilogue(BytecodeFrame.AFTER_EXCEPTION_BCI, null, null); append(new UnwindNode(exception)); } private void synchronizedEpilogue(int bci, ValueNode currentReturnValue, Kind currentReturnValueKind) { if (method.isSynchronized()) { if (currentReturnValue != null) { frameState.push(currentReturnValueKind, currentReturnValue); } genMonitorExit(methodSynchronizedObject, currentReturnValue, bci); assert !frameState.rethrowException(); } } private void createExceptionDispatch(ExceptionDispatchBlock block) { assert frameState.stackSize() == 1 : frameState; if (block.handler.isCatchAll()) { assert block.getSuccessorCount() == 1; appendGoto(block.getSuccessor(0)); return; } JavaType catchType = block.handler.getCatchType(); if (graphBuilderConfig.eagerResolving()) { catchType = lookupType(block.handler.catchTypeCPI(), INSTANCEOF); } boolean initialized = (catchType instanceof ResolvedJavaType); if (initialized && graphBuilderConfig.getSkippedExceptionTypes() != null) { ResolvedJavaType resolvedCatchType = (ResolvedJavaType) catchType; for (ResolvedJavaType skippedType : graphBuilderConfig.getSkippedExceptionTypes()) { if (skippedType.isAssignableFrom(resolvedCatchType)) { BciBlock nextBlock = block.getSuccessorCount() == 1 ? blockMap.getUnwindBlock() : block.getSuccessor(1); ValueNode exception = frameState.stack[0]; FixedNode trueSuccessor = graph.add(new DeoptimizeNode(InvalidateReprofile, UnreachedCode)); FixedNode nextDispatch = createTarget(nextBlock, frameState); append(new IfNode(graph.unique(new InstanceOfNode((ResolvedJavaType) catchType, exception, null)), trueSuccessor, nextDispatch, 0)); return; } } } if (initialized) { BciBlock nextBlock = block.getSuccessorCount() == 1 ? blockMap.getUnwindBlock() : block.getSuccessor(1); ValueNode exception = frameState.stack[0]; CheckCastNode checkCast = graph.add(new CheckCastNode((ResolvedJavaType) catchType, exception, null, false)); frameState.pop(Kind.Object); frameState.push(Kind.Object, checkCast); FixedNode catchSuccessor = createTarget(block.getSuccessor(0), frameState); frameState.pop(Kind.Object); frameState.push(Kind.Object, exception); FixedNode nextDispatch = createTarget(nextBlock, frameState); checkCast.setNext(catchSuccessor); append(new IfNode(graph.unique(new InstanceOfNode((ResolvedJavaType) catchType, exception, null)), checkCast, nextDispatch, 0.5)); } else { handleUnresolvedExceptionType(catchType); } } private void appendGoto(BciBlock successor) { FixedNode targetInstr = createTarget(successor, frameState, true, true); if (lastInstr != null && lastInstr != targetInstr) { lastInstr.setNext(targetInstr); } } protected void iterateBytecodesForBlock(BciBlock block) { if (block.isLoopHeader && !explodeLoops) { // Create the loop header block, which later will merge the backward branches of // the loop. controlFlowSplit = true; LoopBeginNode loopBegin = appendLoopBegin(this.lastInstr); lastInstr = loopBegin; // Create phi functions for all local variables and operand stack slots. frameState.insertLoopPhis(liveness, block.loopId, loopBegin, forceLoopPhis()); loopBegin.setStateAfter(createFrameState(block.startBci, loopBegin)); /* * We have seen all forward branches. All subsequent backward branches will merge to the * loop header. This ensures that the loop header has exactly one non-loop predecessor. */ setFirstInstruction(block, this.getCurrentDimension(), loopBegin); /* * We need to preserve the frame state builder of the loop header so that we can merge * values for phi functions, so make a copy of it. */ setEntryState(block, this.getCurrentDimension(), frameState.copy()); Debug.log(" created loop header %s", loopBegin); } else if (block.isLoopHeader && explodeLoops && this.mergeExplosions) { frameState = frameState.copy(); } assert lastInstr.next() == null : "instructions already appended at block " + block; Debug.log(" frameState: %s", frameState); lastInstr = finishInstruction(lastInstr, frameState); int endBCI = stream.endBCI(); stream.setBCI(block.startBci); int bci = block.startBci; BytecodesParsed.add(block.endBci - bci); /* Reset line number for new block */ if (graphBuilderConfig.insertSimpleDebugInfo()) { previousLineNumber = -1; } while (bci < endBCI) { if (graphBuilderConfig.insertNonSafepointDebugInfo() && !parsingIntrinsic()) { currentLineNumber = lnt != null ? lnt.getLineNumber(bci) : (graphBuilderConfig.insertFullDebugInfo() ? -1 : bci); if (currentLineNumber != previousLineNumber) { genInfoPointNode(InfopointReason.LINE_NUMBER, null); previousLineNumber = currentLineNumber; } } // read the opcode int opcode = stream.currentBC(); assert traceState(); assert traceInstruction(bci, opcode, bci == block.startBci); if (parent == null && bci == entryBCI) { if (block.getJsrScope() != JsrScope.EMPTY_SCOPE) { throw new BailoutException("OSR into a JSR scope is not supported"); } EntryMarkerNode x = append(new EntryMarkerNode()); frameState.insertProxies(value -> ProxyNode.forValue(value, x, graph)); x.setStateAfter(createFrameState(bci, x)); } try { processBytecode(bci, opcode); } catch (Throwable e) { throw asParserError(e); } if (lastInstr == null || lastInstr.next() != null) { break; } stream.next(); bci = stream.currentBCI(); assert block == currentBlock; assert checkLastInstruction(); lastInstr = finishInstruction(lastInstr, frameState); if (bci < endBCI) { if (bci > block.endBci) { assert !block.getSuccessor(0).isExceptionEntry; assert block.numNormalSuccessors() == 1; // we fell through to the next block, add a goto and break appendGoto(block.getSuccessor(0)); break; } } } } /* Also a hook for subclasses. */ protected boolean forceLoopPhis() { return graph.isOSR(); } protected boolean checkLastInstruction() { if (lastInstr instanceof BeginNode) { // ignore } else if (lastInstr instanceof StateSplit) { StateSplit stateSplit = (StateSplit) lastInstr; if (stateSplit.hasSideEffect()) { assert stateSplit.stateAfter() != null : "side effect " + lastInstr + " requires a non-null stateAfter"; } } return true; } private LoopBeginNode appendLoopBegin(FixedWithNextNode fixedWithNext) { EndNode preLoopEnd = graph.add(new EndNode()); LoopBeginNode loopBegin = graph.add(new LoopBeginNode()); fixedWithNext.setNext(preLoopEnd); // Add the single non-loop predecessor of the loop header. loopBegin.addForwardEnd(preLoopEnd); return loopBegin; } /** * Hook for subclasses to modify the last instruction or add other instructions. * * @param instr The last instruction (= fixed node) which was added. * @param state The current frame state. * @return Returns the (new) last instruction. */ protected FixedWithNextNode finishInstruction(FixedWithNextNode instr, FrameStateBuilder state) { return instr; } private void genInfoPointNode(InfopointReason reason, ValueNode escapedReturnValue) { if (!parsingIntrinsic()) { if (graphBuilderConfig.insertFullDebugInfo()) { append(new FullInfopointNode(reason, createFrameState(bci(), null), escapedReturnValue)); } else { BytecodePosition position = createBytecodePosition(); // Update the previous infopoint position if no new fixed nodes were inserted if (lastInstr instanceof SimpleInfopointNode) { SimpleInfopointNode lastInfopoint = (SimpleInfopointNode) lastInstr; if (lastInfopoint.getReason() == reason) { lastInfopoint.setPosition(position); } } append(new SimpleInfopointNode(reason, position)); } } } private boolean traceState() { if (Debug.isEnabled() && Options.TraceBytecodeParserLevel.getValue() >= TRACELEVEL_STATE && Debug.isLogEnabled()) { frameState.traceState(); } return true; } protected void genIf(ValueNode x, Condition cond, ValueNode y) { assert x.getKind().getStackKind() == y.getKind().getStackKind(); assert currentBlock.getSuccessorCount() == 2; BciBlock trueBlock = currentBlock.getSuccessor(0); BciBlock falseBlock = currentBlock.getSuccessor(1); if (trueBlock == falseBlock) { // The target block is the same independent of the condition. appendGoto(trueBlock); return; } ValueNode a = x; ValueNode b = y; // Check whether the condition needs to mirror the operands. if (cond.canonicalMirror()) { a = y; b = x; } // Create the logic node for the condition. LogicNode condition = createLogicNode(cond, a, b); // Check whether the condition needs to negate the result. boolean negate = cond.canonicalNegate(); // Remove a logic negation node and fold it into the negate boolean. if (condition instanceof LogicNegationNode) { LogicNegationNode logicNegationNode = (LogicNegationNode) condition; negate = !negate; condition = logicNegationNode.getValue(); } if (condition instanceof LogicConstantNode) { genConstantTargetIf(trueBlock, falseBlock, negate, condition); } else { if (condition.graph() == null) { condition = graph.unique(condition); } // Need to get probability based on current bci. double probability = branchProbability(); if (negate) { BciBlock tmpBlock = trueBlock; trueBlock = falseBlock; falseBlock = tmpBlock; probability = 1 - probability; } if (isNeverExecutedCode(probability)) { append(new FixedGuardNode(condition, UnreachedCode, InvalidateReprofile, true)); appendGoto(falseBlock); return; } else if (isNeverExecutedCode(1 - probability)) { append(new FixedGuardNode(condition, UnreachedCode, InvalidateReprofile, false)); appendGoto(trueBlock); return; } int oldBci = stream.currentBCI(); int trueBlockInt = checkPositiveIntConstantPushed(trueBlock); if (trueBlockInt != -1) { int falseBlockInt = checkPositiveIntConstantPushed(falseBlock); if (falseBlockInt != -1) { if (tryGenConditionalForIf(trueBlock, falseBlock, condition, oldBci, trueBlockInt, falseBlockInt)) { return; } } } this.controlFlowSplit = true; FixedNode trueSuccessor = createTarget(trueBlock, frameState, false, false); FixedNode falseSuccessor = createTarget(falseBlock, frameState, false, true); ValueNode ifNode = genIfNode(condition, trueSuccessor, falseSuccessor, probability); append(ifNode); if (parsingIntrinsic()) { if (x instanceof BranchProbabilityNode) { ((BranchProbabilityNode) x).simplify(null); } else if (y instanceof BranchProbabilityNode) { ((BranchProbabilityNode) y).simplify(null); } } } } private boolean tryGenConditionalForIf(BciBlock trueBlock, BciBlock falseBlock, LogicNode condition, int oldBci, int trueBlockInt, int falseBlockInt) { if (gotoOrFallThroughAfterConstant(trueBlock) && gotoOrFallThroughAfterConstant(falseBlock) && trueBlock.getSuccessor(0) == falseBlock.getSuccessor(0)) { genConditionalForIf(trueBlock, condition, oldBci, trueBlockInt, falseBlockInt, false); return true; } else if (this.parent != null && returnAfterConstant(trueBlock) && returnAfterConstant(falseBlock)) { genConditionalForIf(trueBlock, condition, oldBci, trueBlockInt, falseBlockInt, true); return true; } return false; } private void genConditionalForIf(BciBlock trueBlock, LogicNode condition, int oldBci, int trueBlockInt, int falseBlockInt, boolean genReturn) { ConstantNode trueValue = graph.unique(ConstantNode.forInt(trueBlockInt)); ConstantNode falseValue = graph.unique(ConstantNode.forInt(falseBlockInt)); ValueNode conditionalNode = ConditionalNode.create(condition, trueValue, falseValue); if (conditionalNode.graph() == null) { conditionalNode = graph.addOrUnique(conditionalNode); } if (genReturn) { Kind returnKind = method.getSignature().getReturnKind().getStackKind(); this.genReturn(conditionalNode, returnKind); } else { frameState.push(Kind.Int, conditionalNode); appendGoto(trueBlock.getSuccessor(0)); stream.setBCI(oldBci); } } private LogicNode createLogicNode(Condition cond, ValueNode a, ValueNode b) { LogicNode condition; assert !a.getKind().isNumericFloat(); if (cond == Condition.EQ || cond == Condition.NE) { if (a.getKind() == Kind.Object) { condition = genObjectEquals(a, b); } else { condition = genIntegerEquals(a, b); } } else { assert a.getKind() != Kind.Object && !cond.isUnsigned(); condition = genIntegerLessThan(a, b); } return condition; } private void genConstantTargetIf(BciBlock trueBlock, BciBlock falseBlock, boolean negate, LogicNode condition) { LogicConstantNode constantLogicNode = (LogicConstantNode) condition; boolean value = constantLogicNode.getValue(); if (negate) { value = !value; } BciBlock nextBlock = falseBlock; if (value) { nextBlock = trueBlock; } appendGoto(nextBlock); } private int checkPositiveIntConstantPushed(BciBlock block) { stream.setBCI(block.startBci); int currentBC = stream.currentBC(); if (currentBC >= Bytecodes.ICONST_0 && currentBC <= Bytecodes.ICONST_5) { int constValue = currentBC - Bytecodes.ICONST_0; return constValue; } return -1; } private boolean gotoOrFallThroughAfterConstant(BciBlock block) { stream.setBCI(block.startBci); int currentBCI = stream.nextBCI(); stream.setBCI(currentBCI); int currentBC = stream.currentBC(); return stream.currentBCI() > block.endBci || currentBC == Bytecodes.GOTO || currentBC == Bytecodes.GOTO_W; } private boolean returnAfterConstant(BciBlock block) { stream.setBCI(block.startBci); int currentBCI = stream.nextBCI(); stream.setBCI(currentBCI); int currentBC = stream.currentBC(); return currentBC == Bytecodes.IRETURN; } public StampProvider getStampProvider() { return stampProvider; } public MetaAccessProvider getMetaAccess() { return metaAccess; } public void push(Kind slotKind, ValueNode value) { assert value.isAlive(); frameState.push(slotKind, value); } private int getCurrentDimension() { if (this.explodeLoopsContext == null || this.explodeLoopsContext.isEmpty()) { return 0; } else { return this.explodeLoopsContext.peek().peelIteration; } } public ConstantReflectionProvider getConstantReflection() { return constantReflection; } /** * Gets the graph being processed by this builder. */ public StructuredGraph getGraph() { return graph; } public BytecodeParser getParent() { return parent; } public IntrinsicContext getIntrinsic() { return intrinsicContext; } @Override public String toString() { Formatter fmt = new Formatter(); BytecodeParser bp = this; String indent = ""; while (bp != null) { if (bp != this) { fmt.format("%n%s", indent); } fmt.format("%s [bci: %d, intrinsic: %s]", bp.method.asStackTraceElement(bp.bci()), bp.bci(), bp.parsingIntrinsic()); fmt.format("%n%s", new BytecodeDisassembler().disassemble(bp.method, bp.bci(), bp.bci() + 10)); bp = bp.parent; indent += " "; } return fmt.toString(); } public BailoutException bailout(String string) { FrameState currentFrameState = createFrameState(bci(), null); StackTraceElement[] elements = GraphUtil.approxSourceStackTraceElement(currentFrameState); BailoutException bailout = new BailoutException(string); throw GraphUtil.createBailoutException(string, bailout, elements); } private FrameState createFrameState(int bci, StateSplit forStateSplit) { if (currentBlock != null && bci > currentBlock.endBci) { frameState.clearNonLiveLocals(currentBlock, liveness, false); } return frameState.create(bci, forStateSplit); } public void setStateAfter(StateSplit sideEffect) { assert sideEffect.hasSideEffect(); FrameState stateAfter = createFrameState(stream.nextBCI(), sideEffect); sideEffect.setStateAfter(stateAfter); } private BytecodePosition createBytecodePosition() { return frameState.createBytecodePosition(bci()); } public void setCurrentFrameState(FrameStateBuilder frameState) { this.frameState = frameState; } protected final BytecodeStream getStream() { return stream; } public int bci() { return stream.currentBCI(); } public void loadLocal(int index, Kind kind) { ValueNode value = frameState.loadLocal(index, kind); frameState.push(kind, value); } public void storeLocal(Kind kind, int index) { ValueNode value = frameState.pop(kind); frameState.storeLocal(index, kind, value); } private void genLoadConstant(int cpi, int opcode) { Object con = lookupConstant(cpi, opcode); if (con instanceof JavaType) { // this is a load of class constant which might be unresolved JavaType type = (JavaType) con; if (type instanceof ResolvedJavaType) { frameState.push(Kind.Object, appendConstant(((ResolvedJavaType) type).getJavaClass())); } else { handleUnresolvedLoadConstant(type); } } else if (con instanceof JavaConstant) { JavaConstant constant = (JavaConstant) con; frameState.push(constant.getKind(), appendConstant(constant)); } else { throw new Error("lookupConstant returned an object of incorrect type"); } } private void genLoadIndexed(Kind kind) { ValueNode index = frameState.pop(Kind.Int); ValueNode array = emitExplicitExceptions(frameState.pop(Kind.Object), index); for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleLoadIndexed(this, array, index, kind)) { return; } } frameState.push(kind, append(genLoadIndexed(array, index, kind))); } private void genStoreIndexed(Kind kind) { ValueNode value = frameState.pop(kind); ValueNode index = frameState.pop(Kind.Int); ValueNode array = emitExplicitExceptions(frameState.pop(Kind.Object), index); for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleStoreIndexed(this, array, index, kind, value)) { return; } } genStoreIndexed(array, index, kind, value); } private void genArithmeticOp(Kind kind, int opcode) { ValueNode y = frameState.pop(kind); ValueNode x = frameState.pop(kind); ValueNode v; switch (opcode) { case IADD: case LADD: v = genIntegerAdd(x, y); break; case FADD: case DADD: v = genFloatAdd(x, y); break; case ISUB: case LSUB: v = genIntegerSub(x, y); break; case FSUB: case DSUB: v = genFloatSub(x, y); break; case IMUL: case LMUL: v = genIntegerMul(x, y); break; case FMUL: case DMUL: v = genFloatMul(x, y); break; case FDIV: case DDIV: v = genFloatDiv(x, y); break; case FREM: case DREM: v = genFloatRem(x, y); break; default: throw shouldNotReachHere(); } frameState.push(kind, append(v)); } private void genIntegerDivOp(Kind kind, int opcode) { ValueNode y = frameState.pop(kind); ValueNode x = frameState.pop(kind); ValueNode v; switch (opcode) { case IDIV: case LDIV: v = genIntegerDiv(x, y); break; case IREM: case LREM: v = genIntegerRem(x, y); break; default: throw shouldNotReachHere(); } frameState.push(kind, append(v)); } private void genNegateOp(Kind kind) { ValueNode x = frameState.pop(kind); frameState.push(kind, append(genNegateOp(x))); } private void genShiftOp(Kind kind, int opcode) { ValueNode s = frameState.pop(Kind.Int); ValueNode x = frameState.pop(kind); ValueNode v; switch (opcode) { case ISHL: case LSHL: v = genLeftShift(x, s); break; case ISHR: case LSHR: v = genRightShift(x, s); break; case IUSHR: case LUSHR: v = genUnsignedRightShift(x, s); break; default: throw shouldNotReachHere(); } frameState.push(kind, append(v)); } private void genLogicOp(Kind kind, int opcode) { ValueNode y = frameState.pop(kind); ValueNode x = frameState.pop(kind); ValueNode v; switch (opcode) { case IAND: case LAND: v = genAnd(x, y); break; case IOR: case LOR: v = genOr(x, y); break; case IXOR: case LXOR: v = genXor(x, y); break; default: throw shouldNotReachHere(); } frameState.push(kind, append(v)); } private void genCompareOp(Kind kind, boolean isUnorderedLess) { ValueNode y = frameState.pop(kind); ValueNode x = frameState.pop(kind); frameState.push(Kind.Int, append(genNormalizeCompare(x, y, isUnorderedLess))); } private void genFloatConvert(FloatConvert op, Kind from, Kind to) { ValueNode input = frameState.pop(from); frameState.push(to, append(genFloatConvert(op, input))); } private void genSignExtend(Kind from, Kind to) { ValueNode input = frameState.pop(from); if (from != from.getStackKind()) { input = append(genNarrow(input, from.getBitCount())); } frameState.push(to, append(genSignExtend(input, to.getBitCount()))); } private void genZeroExtend(Kind from, Kind to) { ValueNode input = frameState.pop(from); if (from != from.getStackKind()) { input = append(genNarrow(input, from.getBitCount())); } frameState.push(to, append(genZeroExtend(input, to.getBitCount()))); } private void genNarrow(Kind from, Kind to) { ValueNode input = frameState.pop(from); frameState.push(to, append(genNarrow(input, to.getBitCount()))); } private void genIncrement() { int index = getStream().readLocalIndex(); int delta = getStream().readIncrement(); ValueNode x = frameState.loadLocal(index, Kind.Int); ValueNode y = appendConstant(JavaConstant.forInt(delta)); frameState.storeLocal(index, Kind.Int, append(genIntegerAdd(x, y))); } private void genIfZero(Condition cond) { ValueNode y = appendConstant(JavaConstant.INT_0); ValueNode x = frameState.pop(Kind.Int); genIf(x, cond, y); } private void genIfNull(Condition cond) { ValueNode y = appendConstant(JavaConstant.NULL_POINTER); ValueNode x = frameState.pop(Kind.Object); genIf(x, cond, y); } private void genIfSame(Kind kind, Condition cond) { ValueNode y = frameState.pop(kind); ValueNode x = frameState.pop(kind); genIf(x, cond, y); } protected JavaType lookupType(int cpi, int bytecode) { maybeEagerlyResolve(cpi, bytecode); JavaType result = constantPool.lookupType(cpi, bytecode); assert !graphBuilderConfig.unresolvedIsError() || result instanceof ResolvedJavaType; return result; } private JavaMethod lookupMethod(int cpi, int opcode) { maybeEagerlyResolve(cpi, opcode); JavaMethod result = constantPool.lookupMethod(cpi, opcode); /* * In general, one cannot assume that the declaring class being initialized is useful, since * the actual concrete receiver may be a different class (except for static calls). Also, * interfaces are initialized only under special circumstances, so that this assertion would * often fail for interface calls. */ assert !graphBuilderConfig.unresolvedIsError() || (result instanceof ResolvedJavaMethod && (opcode != INVOKESTATIC || ((ResolvedJavaMethod) result).getDeclaringClass().isInitialized())) : result; return result; } private JavaField lookupField(int cpi, int opcode) { maybeEagerlyResolve(cpi, opcode); JavaField result = constantPool.lookupField(cpi, opcode); if (graphBuilderConfig.unresolvedIsError()) { assert result instanceof ResolvedJavaField : "Not resolved: " + result; ResolvedJavaType declaringClass = ((ResolvedJavaField) result).getDeclaringClass(); if (!declaringClass.isInitialized()) { assert declaringClass.isInterface() : "Declaring class not initialized but not an interface? " + declaringClass; declaringClass.initialize(); } } assert !graphBuilderConfig.unresolvedIsError() || (result instanceof ResolvedJavaField && ((ResolvedJavaField) result).getDeclaringClass().isInitialized()) : result; return result; } private Object lookupConstant(int cpi, int opcode) { maybeEagerlyResolve(cpi, opcode); Object result = constantPool.lookupConstant(cpi); assert !graphBuilderConfig.eagerResolving() || !(result instanceof JavaType) || (result instanceof ResolvedJavaType) : result; return result; } private void maybeEagerlyResolve(int cpi, int bytecode) { if (graphBuilderConfig.eagerResolving() || intrinsicContext != null) { constantPool.loadReferencedType(cpi, bytecode); } } private JavaTypeProfile getProfileForTypeCheck(ResolvedJavaType type) { if (parsingIntrinsic() || profilingInfo == null || !optimisticOpts.useTypeCheckHints() || !canHaveSubtype(type)) { return null; } else { return profilingInfo.getTypeProfile(bci()); } } private void genCheckCast() { int cpi = getStream().readCPI(); JavaType type = lookupType(cpi, CHECKCAST); ValueNode object = frameState.pop(Kind.Object); if (!(type instanceof ResolvedJavaType)) { handleUnresolvedCheckCast(type, object); return; } ResolvedJavaType resolvedType = (ResolvedJavaType) type; JavaTypeProfile profile = getProfileForTypeCheck(resolvedType); for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleCheckCast(this, object, resolvedType, profile)) { return; } } ValueNode checkCastNode = null; if (profile != null) { if (profile.getNullSeen().isFalse()) { object = appendNullCheck(object); ResolvedJavaType singleType = profile.asSingleType(); if (singleType != null) { LogicNode typeCheck = append(TypeCheckNode.create(singleType, object)); if (typeCheck.isTautology()) { checkCastNode = object; } else { FixedGuardNode fixedGuard = append(new FixedGuardNode(typeCheck, DeoptimizationReason.TypeCheckedInliningViolated, DeoptimizationAction.InvalidateReprofile, false)); checkCastNode = append(new PiNode(object, StampFactory.exactNonNull(singleType), fixedGuard)); } } } } if (checkCastNode == null) { checkCastNode = append(createCheckCast(resolvedType, object, profile, false)); } frameState.push(Kind.Object, checkCastNode); } private ValueNode appendNullCheck(ValueNode object) { IsNullNode isNull = append(new IsNullNode(object)); FixedGuardNode fixedGuard = append(new FixedGuardNode(isNull, DeoptimizationReason.NullCheckException, DeoptimizationAction.InvalidateReprofile, true)); return append(new PiNode(object, object.stamp().join(StampFactory.objectNonNull()), fixedGuard)); } private void genInstanceOf() { int cpi = getStream().readCPI(); JavaType type = lookupType(cpi, INSTANCEOF); ValueNode object = frameState.pop(Kind.Object); if (!(type instanceof ResolvedJavaType)) { handleUnresolvedInstanceOf(type, object); return; } ResolvedJavaType resolvedType = (ResolvedJavaType) type; JavaTypeProfile profile = getProfileForTypeCheck(resolvedType); for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleInstanceOf(this, object, resolvedType, profile)) { return; } } ValueNode instanceOfNode = null; if (profile != null) { if (profile.getNullSeen().isFalse()) { object = appendNullCheck(object); ResolvedJavaType singleType = profile.asSingleType(); if (singleType != null) { LogicNode typeCheck = append(TypeCheckNode.create(singleType, object)); append(new FixedGuardNode(typeCheck, DeoptimizationReason.TypeCheckedInliningViolated, DeoptimizationAction.InvalidateReprofile)); instanceOfNode = LogicConstantNode.forBoolean(resolvedType.isAssignableFrom(singleType)); } } } if (instanceOfNode == null) { instanceOfNode = createInstanceOf(resolvedType, object, profile); } frameState.push(Kind.Int, append(genConditional(genUnique(instanceOfNode)))); } void genNewInstance(int cpi) { JavaType type = lookupType(cpi, NEW); if (!(type instanceof ResolvedJavaType) || !((ResolvedJavaType) type).isInitialized()) { handleUnresolvedNewInstance(type); return; } ResolvedJavaType resolvedType = (ResolvedJavaType) type; ResolvedJavaType[] skippedExceptionTypes = this.graphBuilderConfig.getSkippedExceptionTypes(); if (skippedExceptionTypes != null) { for (ResolvedJavaType exceptionType : skippedExceptionTypes) { if (exceptionType.isAssignableFrom(resolvedType)) { append(new DeoptimizeNode(DeoptimizationAction.None, TransferToInterpreter)); return; } } } frameState.push(Kind.Object, append(createNewInstance(resolvedType, true))); } /** * Gets the kind of array elements for the array type code that appears in a * {@link Bytecodes#NEWARRAY} bytecode. * * @param code the array type code * @return the kind from the array type code */ private static Class<?> arrayTypeCodeToClass(int code) { switch (code) { case 4: return boolean.class; case 5: return char.class; case 6: return float.class; case 7: return double.class; case 8: return byte.class; case 9: return short.class; case 10: return int.class; case 11: return long.class; default: throw new IllegalArgumentException("unknown array type code: " + code); } } private void genNewPrimitiveArray(int typeCode) { ResolvedJavaType elementType = metaAccess.lookupJavaType(arrayTypeCodeToClass(typeCode)); ValueNode length = frameState.pop(Kind.Int); frameState.push(Kind.Object, append(createNewArray(elementType, length, true))); } private void genNewObjectArray(int cpi) { JavaType type = lookupType(cpi, ANEWARRAY); ValueNode length = frameState.pop(Kind.Int); if (!(type instanceof ResolvedJavaType)) { handleUnresolvedNewObjectArray(type, length); return; } ResolvedJavaType resolvedType = (ResolvedJavaType) type; frameState.push(Kind.Object, append(createNewArray(resolvedType, length, true))); } private void genNewMultiArray(int cpi) { JavaType type = lookupType(cpi, MULTIANEWARRAY); int rank = getStream().readUByte(bci() + 3); List<ValueNode> dims = new ArrayList<>(Collections.nCopies(rank, null)); for (int i = rank - 1; i >= 0; i--) { dims.set(i, frameState.pop(Kind.Int)); } if (!(type instanceof ResolvedJavaType)) { handleUnresolvedNewMultiArray(type, dims); return; } ResolvedJavaType resolvedType = (ResolvedJavaType) type; frameState.push(Kind.Object, append(createNewMultiArray(resolvedType, dims))); } private void genGetField(JavaField field) { ValueNode receiver = emitExplicitExceptions(frameState.pop(Kind.Object), null); if (!(field instanceof ResolvedJavaField) || !((ResolvedJavaField) field).getDeclaringClass().isInitialized()) { handleUnresolvedLoadField(field, receiver); return; } ResolvedJavaField resolvedField = (ResolvedJavaField) field; for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleLoadField(this, receiver, resolvedField)) { return; } } frameState.push(field.getKind(), append(genLoadField(receiver, resolvedField))); } /** * @param receiver the receiver of an object based operation * @param index the index of an array based operation that is to be tested for out of bounds. * This is null for a non-array operation. * @return the receiver value possibly modified to have a tighter stamp */ protected ValueNode emitExplicitExceptions(ValueNode receiver, ValueNode index) { assert receiver != null; if (graphBuilderConfig.omitAllExceptionEdges() || profilingInfo == null || (optimisticOpts.useExceptionProbabilityForOperations() && profilingInfo.getExceptionSeen(bci()) == TriState.FALSE && !GraalOptions.StressExplicitExceptionCode.getValue())) { return receiver; } ValueNode nonNullReceiver = emitExplicitNullCheck(receiver); if (index != null) { ValueNode length = append(genArrayLength(nonNullReceiver)); emitExplicitBoundsCheck(index, length); } EXPLICIT_EXCEPTIONS.increment(); return nonNullReceiver; } private void genPutField(JavaField field) { ValueNode value = frameState.pop(field.getKind()); ValueNode receiver = emitExplicitExceptions(frameState.pop(Kind.Object), null); if (!(field instanceof ResolvedJavaField) || !((ResolvedJavaField) field).getDeclaringClass().isInitialized()) { handleUnresolvedStoreField(field, value, receiver); return; } ResolvedJavaField resolvedField = (ResolvedJavaField) field; for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleStoreField(this, receiver, resolvedField, value)) { return; } } genStoreField(receiver, resolvedField, value); } private void genGetStatic(JavaField field) { if (!(field instanceof ResolvedJavaField) || !((ResolvedJavaType) field.getDeclaringClass()).isInitialized()) { handleUnresolvedLoadField(field, null); return; } ResolvedJavaField resolvedField = (ResolvedJavaField) field; /* * Javac does not allow use of "$assertionsDisabled" for a field name but Eclipse does, in * which case a suffix is added to the generated field. */ if ((parsingIntrinsic() || graphBuilderConfig.omitAssertions()) && resolvedField.isSynthetic() && resolvedField.getName().startsWith("$assertionsDisabled")) { frameState.push(field.getKind(), ConstantNode.forBoolean(true, graph)); return; } for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleLoadStaticField(this, resolvedField)) { return; } } frameState.push(field.getKind(), append(genLoadField(null, resolvedField))); } private void genPutStatic(JavaField field) { ValueNode value = frameState.pop(field.getKind()); if (!(field instanceof ResolvedJavaField) || !((ResolvedJavaType) field.getDeclaringClass()).isInitialized()) { handleUnresolvedStoreField(field, value, null); return; } ResolvedJavaField resolvedField = (ResolvedJavaField) field; for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) { if (plugin.handleStoreStaticField(this, resolvedField, value)) { return; } } genStoreField(null, resolvedField, value); } private double[] switchProbability(int numberOfCases, int bci) { double[] prob = (profilingInfo == null ? null : profilingInfo.getSwitchProbabilities(bci)); if (prob != null) { assert prob.length == numberOfCases; } else { Debug.log("Missing probability (switch) in %s at bci %d", method, bci); prob = new double[numberOfCases]; for (int i = 0; i < numberOfCases; i++) { prob[i] = 1.0d / numberOfCases; } } assert allPositive(prob); return prob; } private static boolean allPositive(double[] a) { for (double d : a) { if (d < 0) { return false; } } return true; } static class SuccessorInfo { final int blockIndex; int actualIndex; public SuccessorInfo(int blockSuccessorIndex) { this.blockIndex = blockSuccessorIndex; actualIndex = -1; } } private void genSwitch(BytecodeSwitch bs) { int bci = bci(); ValueNode value = frameState.pop(Kind.Int); int nofCases = bs.numberOfCases(); double[] keyProbabilities = switchProbability(nofCases + 1, bci); Map<Integer, SuccessorInfo> bciToBlockSuccessorIndex = new HashMap<>(); for (int i = 0; i < currentBlock.getSuccessorCount(); i++) { assert !bciToBlockSuccessorIndex.containsKey(currentBlock.getSuccessor(i).startBci); if (!bciToBlockSuccessorIndex.containsKey(currentBlock.getSuccessor(i).startBci)) { bciToBlockSuccessorIndex.put(currentBlock.getSuccessor(i).startBci, new SuccessorInfo(i)); } } ArrayList<BciBlock> actualSuccessors = new ArrayList<>(); int[] keys = new int[nofCases]; int[] keySuccessors = new int[nofCases + 1]; int deoptSuccessorIndex = -1; int nextSuccessorIndex = 0; boolean constantValue = value.isConstant(); for (int i = 0; i < nofCases + 1; i++) { if (i < nofCases) { keys[i] = bs.keyAt(i); } if (!constantValue && isNeverExecutedCode(keyProbabilities[i])) { if (deoptSuccessorIndex < 0) { deoptSuccessorIndex = nextSuccessorIndex++; actualSuccessors.add(null); } keySuccessors[i] = deoptSuccessorIndex; } else { int targetBci = i >= nofCases ? bs.defaultTarget() : bs.targetAt(i); SuccessorInfo info = bciToBlockSuccessorIndex.get(targetBci); if (info.actualIndex < 0) { info.actualIndex = nextSuccessorIndex++; actualSuccessors.add(currentBlock.getSuccessor(info.blockIndex)); } keySuccessors[i] = info.actualIndex; } } genIntegerSwitch(value, actualSuccessors, keys, keyProbabilities, keySuccessors); } protected boolean isNeverExecutedCode(double probability) { return probability == 0 && optimisticOpts.removeNeverExecutedCode(); } protected double branchProbability() { if (profilingInfo == null) { return 0.5; } assert assertAtIfBytecode(); double probability = profilingInfo.getBranchTakenProbability(bci()); if (probability < 0) { assert probability == -1 : "invalid probability"; Debug.log("missing probability in %s at bci %d", method, bci()); probability = 0.5; } if (!optimisticOpts.removeNeverExecutedCode()) { if (probability == 0) { probability = 0.0000001; } else if (probability == 1) { probability = 0.999999; } } return probability; } private boolean assertAtIfBytecode() { int bytecode = stream.currentBC(); switch (bytecode) { case IFEQ: case IFNE: case IFLT: case IFGE: case IFGT: case IFLE: case IF_ICMPEQ: case IF_ICMPNE: case IF_ICMPLT: case IF_ICMPGE: case IF_ICMPGT: case IF_ICMPLE: case IF_ACMPEQ: case IF_ACMPNE: case IFNULL: case IFNONNULL: return true; } assert false : String.format("%x is not an if bytecode", bytecode); return true; } public final void processBytecode(int bci, int opcode) { int cpi; // @formatter:off // Checkstyle: stop switch (opcode) { case NOP : /* nothing to do */ break; case ACONST_NULL : frameState.push(Kind.Object, appendConstant(JavaConstant.NULL_POINTER)); break; case ICONST_M1 : // fall through case ICONST_0 : // fall through case ICONST_1 : // fall through case ICONST_2 : // fall through case ICONST_3 : // fall through case ICONST_4 : // fall through case ICONST_5 : frameState.push(Kind.Int, appendConstant(JavaConstant.forInt(opcode - ICONST_0))); break; case LCONST_0 : // fall through case LCONST_1 : frameState.push(Kind.Long, appendConstant(JavaConstant.forLong(opcode - LCONST_0))); break; case FCONST_0 : // fall through case FCONST_1 : // fall through case FCONST_2 : frameState.push(Kind.Float, appendConstant(JavaConstant.forFloat(opcode - FCONST_0))); break; case DCONST_0 : // fall through case DCONST_1 : frameState.push(Kind.Double, appendConstant(JavaConstant.forDouble(opcode - DCONST_0))); break; case BIPUSH : frameState.push(Kind.Int, appendConstant(JavaConstant.forInt(stream.readByte()))); break; case SIPUSH : frameState.push(Kind.Int, appendConstant(JavaConstant.forInt(stream.readShort()))); break; case LDC : // fall through case LDC_W : // fall through case LDC2_W : genLoadConstant(stream.readCPI(), opcode); break; case ILOAD : loadLocal(stream.readLocalIndex(), Kind.Int); break; case LLOAD : loadLocal(stream.readLocalIndex(), Kind.Long); break; case FLOAD : loadLocal(stream.readLocalIndex(), Kind.Float); break; case DLOAD : loadLocal(stream.readLocalIndex(), Kind.Double); break; case ALOAD : loadLocal(stream.readLocalIndex(), Kind.Object); break; case ILOAD_0 : // fall through case ILOAD_1 : // fall through case ILOAD_2 : // fall through case ILOAD_3 : loadLocal(opcode - ILOAD_0, Kind.Int); break; case LLOAD_0 : // fall through case LLOAD_1 : // fall through case LLOAD_2 : // fall through case LLOAD_3 : loadLocal(opcode - LLOAD_0, Kind.Long); break; case FLOAD_0 : // fall through case FLOAD_1 : // fall through case FLOAD_2 : // fall through case FLOAD_3 : loadLocal(opcode - FLOAD_0, Kind.Float); break; case DLOAD_0 : // fall through case DLOAD_1 : // fall through case DLOAD_2 : // fall through case DLOAD_3 : loadLocal(opcode - DLOAD_0, Kind.Double); break; case ALOAD_0 : // fall through case ALOAD_1 : // fall through case ALOAD_2 : // fall through case ALOAD_3 : loadLocal(opcode - ALOAD_0, Kind.Object); break; case IALOAD : genLoadIndexed(Kind.Int ); break; case LALOAD : genLoadIndexed(Kind.Long ); break; case FALOAD : genLoadIndexed(Kind.Float ); break; case DALOAD : genLoadIndexed(Kind.Double); break; case AALOAD : genLoadIndexed(Kind.Object); break; case BALOAD : genLoadIndexed(Kind.Byte ); break; case CALOAD : genLoadIndexed(Kind.Char ); break; case SALOAD : genLoadIndexed(Kind.Short ); break; case ISTORE : storeLocal(Kind.Int, stream.readLocalIndex()); break; case LSTORE : storeLocal(Kind.Long, stream.readLocalIndex()); break; case FSTORE : storeLocal(Kind.Float, stream.readLocalIndex()); break; case DSTORE : storeLocal(Kind.Double, stream.readLocalIndex()); break; case ASTORE : storeLocal(Kind.Object, stream.readLocalIndex()); break; case ISTORE_0 : // fall through case ISTORE_1 : // fall through case ISTORE_2 : // fall through case ISTORE_3 : storeLocal(Kind.Int, opcode - ISTORE_0); break; case LSTORE_0 : // fall through case LSTORE_1 : // fall through case LSTORE_2 : // fall through case LSTORE_3 : storeLocal(Kind.Long, opcode - LSTORE_0); break; case FSTORE_0 : // fall through case FSTORE_1 : // fall through case FSTORE_2 : // fall through case FSTORE_3 : storeLocal(Kind.Float, opcode - FSTORE_0); break; case DSTORE_0 : // fall through case DSTORE_1 : // fall through case DSTORE_2 : // fall through case DSTORE_3 : storeLocal(Kind.Double, opcode - DSTORE_0); break; case ASTORE_0 : // fall through case ASTORE_1 : // fall through case ASTORE_2 : // fall through case ASTORE_3 : storeLocal(Kind.Object, opcode - ASTORE_0); break; case IASTORE : genStoreIndexed(Kind.Int ); break; case LASTORE : genStoreIndexed(Kind.Long ); break; case FASTORE : genStoreIndexed(Kind.Float ); break; case DASTORE : genStoreIndexed(Kind.Double); break; case AASTORE : genStoreIndexed(Kind.Object); break; case BASTORE : genStoreIndexed(Kind.Byte ); break; case CASTORE : genStoreIndexed(Kind.Char ); break; case SASTORE : genStoreIndexed(Kind.Short ); break; case POP : // fall through case POP2 : // fall through case DUP : // fall through case DUP_X1 : // fall through case DUP_X2 : // fall through case DUP2 : // fall through case DUP2_X1 : // fall through case DUP2_X2 : // fall through case SWAP : frameState.stackOp(opcode); break; case IADD : // fall through case ISUB : // fall through case IMUL : genArithmeticOp(Kind.Int, opcode); break; case IDIV : // fall through case IREM : genIntegerDivOp(Kind.Int, opcode); break; case LADD : // fall through case LSUB : // fall through case LMUL : genArithmeticOp(Kind.Long, opcode); break; case LDIV : // fall through case LREM : genIntegerDivOp(Kind.Long, opcode); break; case FADD : // fall through case FSUB : // fall through case FMUL : // fall through case FDIV : // fall through case FREM : genArithmeticOp(Kind.Float, opcode); break; case DADD : // fall through case DSUB : // fall through case DMUL : // fall through case DDIV : // fall through case DREM : genArithmeticOp(Kind.Double, opcode); break; case INEG : genNegateOp(Kind.Int); break; case LNEG : genNegateOp(Kind.Long); break; case FNEG : genNegateOp(Kind.Float); break; case DNEG : genNegateOp(Kind.Double); break; case ISHL : // fall through case ISHR : // fall through case IUSHR : genShiftOp(Kind.Int, opcode); break; case IAND : // fall through case IOR : // fall through case IXOR : genLogicOp(Kind.Int, opcode); break; case LSHL : // fall through case LSHR : // fall through case LUSHR : genShiftOp(Kind.Long, opcode); break; case LAND : // fall through case LOR : // fall through case LXOR : genLogicOp(Kind.Long, opcode); break; case IINC : genIncrement(); break; case I2F : genFloatConvert(FloatConvert.I2F, Kind.Int, Kind.Float); break; case I2D : genFloatConvert(FloatConvert.I2D, Kind.Int, Kind.Double); break; case L2F : genFloatConvert(FloatConvert.L2F, Kind.Long, Kind.Float); break; case L2D : genFloatConvert(FloatConvert.L2D, Kind.Long, Kind.Double); break; case F2I : genFloatConvert(FloatConvert.F2I, Kind.Float, Kind.Int); break; case F2L : genFloatConvert(FloatConvert.F2L, Kind.Float, Kind.Long); break; case F2D : genFloatConvert(FloatConvert.F2D, Kind.Float, Kind.Double); break; case D2I : genFloatConvert(FloatConvert.D2I, Kind.Double, Kind.Int); break; case D2L : genFloatConvert(FloatConvert.D2L, Kind.Double, Kind.Long); break; case D2F : genFloatConvert(FloatConvert.D2F, Kind.Double, Kind.Float); break; case L2I : genNarrow(Kind.Long, Kind.Int); break; case I2L : genSignExtend(Kind.Int, Kind.Long); break; case I2B : genSignExtend(Kind.Byte, Kind.Int); break; case I2S : genSignExtend(Kind.Short, Kind.Int); break; case I2C : genZeroExtend(Kind.Char, Kind.Int); break; case LCMP : genCompareOp(Kind.Long, false); break; case FCMPL : genCompareOp(Kind.Float, true); break; case FCMPG : genCompareOp(Kind.Float, false); break; case DCMPL : genCompareOp(Kind.Double, true); break; case DCMPG : genCompareOp(Kind.Double, false); break; case IFEQ : genIfZero(Condition.EQ); break; case IFNE : genIfZero(Condition.NE); break; case IFLT : genIfZero(Condition.LT); break; case IFGE : genIfZero(Condition.GE); break; case IFGT : genIfZero(Condition.GT); break; case IFLE : genIfZero(Condition.LE); break; case IF_ICMPEQ : genIfSame(Kind.Int, Condition.EQ); break; case IF_ICMPNE : genIfSame(Kind.Int, Condition.NE); break; case IF_ICMPLT : genIfSame(Kind.Int, Condition.LT); break; case IF_ICMPGE : genIfSame(Kind.Int, Condition.GE); break; case IF_ICMPGT : genIfSame(Kind.Int, Condition.GT); break; case IF_ICMPLE : genIfSame(Kind.Int, Condition.LE); break; case IF_ACMPEQ : genIfSame(Kind.Object, Condition.EQ); break; case IF_ACMPNE : genIfSame(Kind.Object, Condition.NE); break; case GOTO : genGoto(); break; case JSR : genJsr(stream.readBranchDest()); break; case RET : genRet(stream.readLocalIndex()); break; case TABLESWITCH : genSwitch(new BytecodeTableSwitch(getStream(), bci())); break; case LOOKUPSWITCH : genSwitch(new BytecodeLookupSwitch(getStream(), bci())); break; case IRETURN : genReturn(frameState.pop(Kind.Int), Kind.Int); break; case LRETURN : genReturn(frameState.pop(Kind.Long), Kind.Long); break; case FRETURN : genReturn(frameState.pop(Kind.Float), Kind.Float); break; case DRETURN : genReturn(frameState.pop(Kind.Double), Kind.Double); break; case ARETURN : genReturn(frameState.pop(Kind.Object), Kind.Object); break; case RETURN : genReturn(null, Kind.Void); break; case GETSTATIC : cpi = stream.readCPI(); genGetStatic(lookupField(cpi, opcode)); break; case PUTSTATIC : cpi = stream.readCPI(); genPutStatic(lookupField(cpi, opcode)); break; case GETFIELD : cpi = stream.readCPI(); genGetField(lookupField(cpi, opcode)); break; case PUTFIELD : cpi = stream.readCPI(); genPutField(lookupField(cpi, opcode)); break; case INVOKEVIRTUAL : cpi = stream.readCPI(); genInvokeVirtual(lookupMethod(cpi, opcode)); break; case INVOKESPECIAL : cpi = stream.readCPI(); genInvokeSpecial(lookupMethod(cpi, opcode)); break; case INVOKESTATIC : cpi = stream.readCPI(); genInvokeStatic(lookupMethod(cpi, opcode)); break; case INVOKEINTERFACE: cpi = stream.readCPI(); genInvokeInterface(lookupMethod(cpi, opcode)); break; case INVOKEDYNAMIC : cpi = stream.readCPI4(); genInvokeDynamic(lookupMethod(cpi, opcode)); break; case NEW : genNewInstance(stream.readCPI()); break; case NEWARRAY : genNewPrimitiveArray(stream.readLocalIndex()); break; case ANEWARRAY : genNewObjectArray(stream.readCPI()); break; case ARRAYLENGTH : genArrayLength(); break; case ATHROW : genThrow(); break; case CHECKCAST : genCheckCast(); break; case INSTANCEOF : genInstanceOf(); break; case MONITORENTER : genMonitorEnter(frameState.pop(Kind.Object), stream.nextBCI()); break; case MONITOREXIT : genMonitorExit(frameState.pop(Kind.Object), null, stream.nextBCI()); break; case MULTIANEWARRAY : genNewMultiArray(stream.readCPI()); break; case IFNULL : genIfNull(Condition.EQ); break; case IFNONNULL : genIfNull(Condition.NE); break; case GOTO_W : genGoto(); break; case JSR_W : genJsr(stream.readBranchDest()); break; case BREAKPOINT : throw new BailoutException("concurrent setting of breakpoint"); default : throw new BailoutException("Unsupported opcode %d (%s) [bci=%d]", opcode, nameOf(opcode), bci); } // @formatter:on // Checkstyle: resume } private void genArrayLength() { frameState.push(Kind.Int, append(genArrayLength(frameState.pop(Kind.Object)))); } public ResolvedJavaMethod getMethod() { return method; } public FrameStateBuilder getFrameStateBuilder() { return frameState; } protected boolean traceInstruction(int bci, int opcode, boolean blockStart) { if (Debug.isEnabled() && Options.TraceBytecodeParserLevel.getValue() >= TRACELEVEL_INSTRUCTIONS && Debug.isLogEnabled()) { traceInstructionHelper(bci, opcode, blockStart); } return true; } private void traceInstructionHelper(int bci, int opcode, boolean blockStart) { StringBuilder sb = new StringBuilder(40); sb.append(blockStart ? '+' : '|'); if (bci < 10) { sb.append(" "); } else if (bci < 100) { sb.append(' '); } sb.append(bci).append(": ").append(Bytecodes.nameOf(opcode)); for (int i = bci + 1; i < stream.nextBCI(); ++i) { sb.append(' ').append(stream.readUByte(i)); } if (!currentBlock.getJsrScope().isEmpty()) { sb.append(' ').append(currentBlock.getJsrScope()); } Debug.log("%s", sb); } public boolean parsingIntrinsic() { return intrinsicContext != null; } public BytecodeParser getNonIntrinsicAncestor() { BytecodeParser ancestor = parent; while (ancestor != null && ancestor.parsingIntrinsic()) { ancestor = ancestor.parent; } return ancestor; } static String nSpaces(int n) { return n == 0 ? "" : format("%" + n + "s", ""); } @SuppressWarnings("all") private static boolean assertionsEnabled() { boolean assertionsEnabled = false; assert assertionsEnabled = true; return assertionsEnabled; } }