src/jdk.internal.vm.compiler/share/classes/org.graalvm.compiler.java/src/org/graalvm/compiler/java/BytecodeParser.java
/*
* Copyright (c) 2009, 2017, 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 org.graalvm.compiler.java;
import static java.lang.String.format;
import static java.lang.reflect.Modifier.STATIC;
import static java.lang.reflect.Modifier.SYNCHRONIZED;
import static jdk.vm.ci.meta.DeoptimizationAction.InvalidateRecompile;
import static jdk.vm.ci.meta.DeoptimizationAction.InvalidateReprofile;
import static jdk.vm.ci.meta.DeoptimizationAction.None;
import static jdk.vm.ci.meta.DeoptimizationReason.ClassCastException;
import static jdk.vm.ci.meta.DeoptimizationReason.JavaSubroutineMismatch;
import static jdk.vm.ci.meta.DeoptimizationReason.NullCheckException;
import static jdk.vm.ci.meta.DeoptimizationReason.RuntimeConstraint;
import static jdk.vm.ci.meta.DeoptimizationReason.TypeCheckedInliningViolated;
import static jdk.vm.ci.meta.DeoptimizationReason.UnreachedCode;
import static jdk.vm.ci.meta.DeoptimizationReason.Unresolved;
import static jdk.vm.ci.runtime.JVMCICompiler.INVOCATION_ENTRY_BCI;
import static org.graalvm.compiler.bytecode.Bytecodes.AALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.AASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.ACONST_NULL;
import static org.graalvm.compiler.bytecode.Bytecodes.ALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.ALOAD_0;
import static org.graalvm.compiler.bytecode.Bytecodes.ALOAD_1;
import static org.graalvm.compiler.bytecode.Bytecodes.ALOAD_2;
import static org.graalvm.compiler.bytecode.Bytecodes.ALOAD_3;
import static org.graalvm.compiler.bytecode.Bytecodes.ANEWARRAY;
import static org.graalvm.compiler.bytecode.Bytecodes.ARETURN;
import static org.graalvm.compiler.bytecode.Bytecodes.ARRAYLENGTH;
import static org.graalvm.compiler.bytecode.Bytecodes.ASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.ASTORE_0;
import static org.graalvm.compiler.bytecode.Bytecodes.ASTORE_1;
import static org.graalvm.compiler.bytecode.Bytecodes.ASTORE_2;
import static org.graalvm.compiler.bytecode.Bytecodes.ASTORE_3;
import static org.graalvm.compiler.bytecode.Bytecodes.ATHROW;
import static org.graalvm.compiler.bytecode.Bytecodes.BALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.BASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.BIPUSH;
import static org.graalvm.compiler.bytecode.Bytecodes.BREAKPOINT;
import static org.graalvm.compiler.bytecode.Bytecodes.CALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.CASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.CHECKCAST;
import static org.graalvm.compiler.bytecode.Bytecodes.D2F;
import static org.graalvm.compiler.bytecode.Bytecodes.D2I;
import static org.graalvm.compiler.bytecode.Bytecodes.D2L;
import static org.graalvm.compiler.bytecode.Bytecodes.DADD;
import static org.graalvm.compiler.bytecode.Bytecodes.DALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.DASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.DCMPG;
import static org.graalvm.compiler.bytecode.Bytecodes.DCMPL;
import static org.graalvm.compiler.bytecode.Bytecodes.DCONST_0;
import static org.graalvm.compiler.bytecode.Bytecodes.DCONST_1;
import static org.graalvm.compiler.bytecode.Bytecodes.DDIV;
import static org.graalvm.compiler.bytecode.Bytecodes.DLOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.DLOAD_0;
import static org.graalvm.compiler.bytecode.Bytecodes.DLOAD_1;
import static org.graalvm.compiler.bytecode.Bytecodes.DLOAD_2;
import static org.graalvm.compiler.bytecode.Bytecodes.DLOAD_3;
import static org.graalvm.compiler.bytecode.Bytecodes.DMUL;
import static org.graalvm.compiler.bytecode.Bytecodes.DNEG;
import static org.graalvm.compiler.bytecode.Bytecodes.DREM;
import static org.graalvm.compiler.bytecode.Bytecodes.DRETURN;
import static org.graalvm.compiler.bytecode.Bytecodes.DSTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.DSTORE_0;
import static org.graalvm.compiler.bytecode.Bytecodes.DSTORE_1;
import static org.graalvm.compiler.bytecode.Bytecodes.DSTORE_2;
import static org.graalvm.compiler.bytecode.Bytecodes.DSTORE_3;
import static org.graalvm.compiler.bytecode.Bytecodes.DSUB;
import static org.graalvm.compiler.bytecode.Bytecodes.DUP;
import static org.graalvm.compiler.bytecode.Bytecodes.DUP2;
import static org.graalvm.compiler.bytecode.Bytecodes.DUP2_X1;
import static org.graalvm.compiler.bytecode.Bytecodes.DUP2_X2;
import static org.graalvm.compiler.bytecode.Bytecodes.DUP_X1;
import static org.graalvm.compiler.bytecode.Bytecodes.DUP_X2;
import static org.graalvm.compiler.bytecode.Bytecodes.F2D;
import static org.graalvm.compiler.bytecode.Bytecodes.F2I;
import static org.graalvm.compiler.bytecode.Bytecodes.F2L;
import static org.graalvm.compiler.bytecode.Bytecodes.FADD;
import static org.graalvm.compiler.bytecode.Bytecodes.FALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.FASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.FCMPG;
import static org.graalvm.compiler.bytecode.Bytecodes.FCMPL;
import static org.graalvm.compiler.bytecode.Bytecodes.FCONST_0;
import static org.graalvm.compiler.bytecode.Bytecodes.FCONST_1;
import static org.graalvm.compiler.bytecode.Bytecodes.FCONST_2;
import static org.graalvm.compiler.bytecode.Bytecodes.FDIV;
import static org.graalvm.compiler.bytecode.Bytecodes.FLOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.FLOAD_0;
import static org.graalvm.compiler.bytecode.Bytecodes.FLOAD_1;
import static org.graalvm.compiler.bytecode.Bytecodes.FLOAD_2;
import static org.graalvm.compiler.bytecode.Bytecodes.FLOAD_3;
import static org.graalvm.compiler.bytecode.Bytecodes.FMUL;
import static org.graalvm.compiler.bytecode.Bytecodes.FNEG;
import static org.graalvm.compiler.bytecode.Bytecodes.FREM;
import static org.graalvm.compiler.bytecode.Bytecodes.FRETURN;
import static org.graalvm.compiler.bytecode.Bytecodes.FSTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.FSTORE_0;
import static org.graalvm.compiler.bytecode.Bytecodes.FSTORE_1;
import static org.graalvm.compiler.bytecode.Bytecodes.FSTORE_2;
import static org.graalvm.compiler.bytecode.Bytecodes.FSTORE_3;
import static org.graalvm.compiler.bytecode.Bytecodes.FSUB;
import static org.graalvm.compiler.bytecode.Bytecodes.GETFIELD;
import static org.graalvm.compiler.bytecode.Bytecodes.GETSTATIC;
import static org.graalvm.compiler.bytecode.Bytecodes.GOTO;
import static org.graalvm.compiler.bytecode.Bytecodes.GOTO_W;
import static org.graalvm.compiler.bytecode.Bytecodes.I2B;
import static org.graalvm.compiler.bytecode.Bytecodes.I2C;
import static org.graalvm.compiler.bytecode.Bytecodes.I2D;
import static org.graalvm.compiler.bytecode.Bytecodes.I2F;
import static org.graalvm.compiler.bytecode.Bytecodes.I2L;
import static org.graalvm.compiler.bytecode.Bytecodes.I2S;
import static org.graalvm.compiler.bytecode.Bytecodes.IADD;
import static org.graalvm.compiler.bytecode.Bytecodes.IALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.IAND;
import static org.graalvm.compiler.bytecode.Bytecodes.IASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_0;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_1;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_2;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_3;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_4;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_5;
import static org.graalvm.compiler.bytecode.Bytecodes.ICONST_M1;
import static org.graalvm.compiler.bytecode.Bytecodes.IDIV;
import static org.graalvm.compiler.bytecode.Bytecodes.IFEQ;
import static org.graalvm.compiler.bytecode.Bytecodes.IFGE;
import static org.graalvm.compiler.bytecode.Bytecodes.IFGT;
import static org.graalvm.compiler.bytecode.Bytecodes.IFLE;
import static org.graalvm.compiler.bytecode.Bytecodes.IFLT;
import static org.graalvm.compiler.bytecode.Bytecodes.IFNE;
import static org.graalvm.compiler.bytecode.Bytecodes.IFNONNULL;
import static org.graalvm.compiler.bytecode.Bytecodes.IFNULL;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ACMPEQ;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ACMPNE;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ICMPEQ;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ICMPGE;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ICMPGT;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ICMPLE;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ICMPLT;
import static org.graalvm.compiler.bytecode.Bytecodes.IF_ICMPNE;
import static org.graalvm.compiler.bytecode.Bytecodes.IINC;
import static org.graalvm.compiler.bytecode.Bytecodes.ILOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.ILOAD_0;
import static org.graalvm.compiler.bytecode.Bytecodes.ILOAD_1;
import static org.graalvm.compiler.bytecode.Bytecodes.ILOAD_2;
import static org.graalvm.compiler.bytecode.Bytecodes.ILOAD_3;
import static org.graalvm.compiler.bytecode.Bytecodes.IMUL;
import static org.graalvm.compiler.bytecode.Bytecodes.INEG;
import static org.graalvm.compiler.bytecode.Bytecodes.INSTANCEOF;
import static org.graalvm.compiler.bytecode.Bytecodes.INVOKEDYNAMIC;
import static org.graalvm.compiler.bytecode.Bytecodes.INVOKEINTERFACE;
import static org.graalvm.compiler.bytecode.Bytecodes.INVOKESPECIAL;
import static org.graalvm.compiler.bytecode.Bytecodes.INVOKESTATIC;
import static org.graalvm.compiler.bytecode.Bytecodes.INVOKEVIRTUAL;
import static org.graalvm.compiler.bytecode.Bytecodes.IOR;
import static org.graalvm.compiler.bytecode.Bytecodes.IREM;
import static org.graalvm.compiler.bytecode.Bytecodes.IRETURN;
import static org.graalvm.compiler.bytecode.Bytecodes.ISHL;
import static org.graalvm.compiler.bytecode.Bytecodes.ISHR;
import static org.graalvm.compiler.bytecode.Bytecodes.ISTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.ISTORE_0;
import static org.graalvm.compiler.bytecode.Bytecodes.ISTORE_1;
import static org.graalvm.compiler.bytecode.Bytecodes.ISTORE_2;
import static org.graalvm.compiler.bytecode.Bytecodes.ISTORE_3;
import static org.graalvm.compiler.bytecode.Bytecodes.ISUB;
import static org.graalvm.compiler.bytecode.Bytecodes.IUSHR;
import static org.graalvm.compiler.bytecode.Bytecodes.IXOR;
import static org.graalvm.compiler.bytecode.Bytecodes.JSR;
import static org.graalvm.compiler.bytecode.Bytecodes.JSR_W;
import static org.graalvm.compiler.bytecode.Bytecodes.L2D;
import static org.graalvm.compiler.bytecode.Bytecodes.L2F;
import static org.graalvm.compiler.bytecode.Bytecodes.L2I;
import static org.graalvm.compiler.bytecode.Bytecodes.LADD;
import static org.graalvm.compiler.bytecode.Bytecodes.LALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.LAND;
import static org.graalvm.compiler.bytecode.Bytecodes.LASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.LCMP;
import static org.graalvm.compiler.bytecode.Bytecodes.LCONST_0;
import static org.graalvm.compiler.bytecode.Bytecodes.LCONST_1;
import static org.graalvm.compiler.bytecode.Bytecodes.LDC;
import static org.graalvm.compiler.bytecode.Bytecodes.LDC2_W;
import static org.graalvm.compiler.bytecode.Bytecodes.LDC_W;
import static org.graalvm.compiler.bytecode.Bytecodes.LDIV;
import static org.graalvm.compiler.bytecode.Bytecodes.LLOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.LLOAD_0;
import static org.graalvm.compiler.bytecode.Bytecodes.LLOAD_1;
import static org.graalvm.compiler.bytecode.Bytecodes.LLOAD_2;
import static org.graalvm.compiler.bytecode.Bytecodes.LLOAD_3;
import static org.graalvm.compiler.bytecode.Bytecodes.LMUL;
import static org.graalvm.compiler.bytecode.Bytecodes.LNEG;
import static org.graalvm.compiler.bytecode.Bytecodes.LOOKUPSWITCH;
import static org.graalvm.compiler.bytecode.Bytecodes.LOR;
import static org.graalvm.compiler.bytecode.Bytecodes.LREM;
import static org.graalvm.compiler.bytecode.Bytecodes.LRETURN;
import static org.graalvm.compiler.bytecode.Bytecodes.LSHL;
import static org.graalvm.compiler.bytecode.Bytecodes.LSHR;
import static org.graalvm.compiler.bytecode.Bytecodes.LSTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.LSTORE_0;
import static org.graalvm.compiler.bytecode.Bytecodes.LSTORE_1;
import static org.graalvm.compiler.bytecode.Bytecodes.LSTORE_2;
import static org.graalvm.compiler.bytecode.Bytecodes.LSTORE_3;
import static org.graalvm.compiler.bytecode.Bytecodes.LSUB;
import static org.graalvm.compiler.bytecode.Bytecodes.LUSHR;
import static org.graalvm.compiler.bytecode.Bytecodes.LXOR;
import static org.graalvm.compiler.bytecode.Bytecodes.MONITORENTER;
import static org.graalvm.compiler.bytecode.Bytecodes.MONITOREXIT;
import static org.graalvm.compiler.bytecode.Bytecodes.MULTIANEWARRAY;
import static org.graalvm.compiler.bytecode.Bytecodes.NEW;
import static org.graalvm.compiler.bytecode.Bytecodes.NEWARRAY;
import static org.graalvm.compiler.bytecode.Bytecodes.NOP;
import static org.graalvm.compiler.bytecode.Bytecodes.POP;
import static org.graalvm.compiler.bytecode.Bytecodes.POP2;
import static org.graalvm.compiler.bytecode.Bytecodes.PUTFIELD;
import static org.graalvm.compiler.bytecode.Bytecodes.PUTSTATIC;
import static org.graalvm.compiler.bytecode.Bytecodes.RET;
import static org.graalvm.compiler.bytecode.Bytecodes.RETURN;
import static org.graalvm.compiler.bytecode.Bytecodes.SALOAD;
import static org.graalvm.compiler.bytecode.Bytecodes.SASTORE;
import static org.graalvm.compiler.bytecode.Bytecodes.SIPUSH;
import static org.graalvm.compiler.bytecode.Bytecodes.SWAP;
import static org.graalvm.compiler.bytecode.Bytecodes.TABLESWITCH;
import static org.graalvm.compiler.bytecode.Bytecodes.nameOf;
import static org.graalvm.compiler.core.common.GraalOptions.DeoptALot;
import static org.graalvm.compiler.core.common.GraalOptions.GeneratePIC;
import static org.graalvm.compiler.core.common.GraalOptions.HotSpotPrintInlining;
import static org.graalvm.compiler.core.common.GraalOptions.PrintProfilingInformation;
import static org.graalvm.compiler.core.common.GraalOptions.ResolveClassBeforeStaticInvoke;
import static org.graalvm.compiler.core.common.GraalOptions.StressExplicitExceptionCode;
import static org.graalvm.compiler.core.common.GraalOptions.StressInvokeWithExceptionNode;
import static org.graalvm.compiler.core.common.type.StampFactory.objectNonNull;
import static org.graalvm.compiler.debug.GraalError.guarantee;
import static org.graalvm.compiler.debug.GraalError.shouldNotReachHere;
import static org.graalvm.compiler.java.BytecodeParserOptions.InlinePartialIntrinsicExitDuringParsing;
import static org.graalvm.compiler.java.BytecodeParserOptions.TraceBytecodeParserLevel;
import static org.graalvm.compiler.java.BytecodeParserOptions.TraceInlineDuringParsing;
import static org.graalvm.compiler.java.BytecodeParserOptions.TraceParserPlugins;
import static org.graalvm.compiler.java.BytecodeParserOptions.UseGuardedIntrinsics;
import static org.graalvm.compiler.nodes.extended.BranchProbabilityNode.FAST_PATH_PROBABILITY;
import static org.graalvm.compiler.nodes.extended.BranchProbabilityNode.SLOW_PATH_PROBABILITY;
import static org.graalvm.compiler.nodes.graphbuilderconf.IntrinsicContext.CompilationContext.INLINE_DURING_PARSING;
import static org.graalvm.compiler.nodes.type.StampTool.isPointerNonNull;
import java.util.ArrayList;
import java.util.Collections;
import java.util.Comparator;
import java.util.Formatter;
import java.util.List;
import org.graalvm.compiler.api.replacements.Snippet;
import org.graalvm.compiler.bytecode.Bytecode;
import org.graalvm.compiler.bytecode.BytecodeDisassembler;
import org.graalvm.compiler.bytecode.BytecodeLookupSwitch;
import org.graalvm.compiler.bytecode.BytecodeProvider;
import org.graalvm.compiler.bytecode.BytecodeStream;
import org.graalvm.compiler.bytecode.BytecodeSwitch;
import org.graalvm.compiler.bytecode.BytecodeTableSwitch;
import org.graalvm.compiler.bytecode.Bytecodes;
import org.graalvm.compiler.bytecode.Bytes;
import org.graalvm.compiler.bytecode.ResolvedJavaMethodBytecode;
import org.graalvm.compiler.bytecode.ResolvedJavaMethodBytecodeProvider;
import org.graalvm.compiler.core.common.PermanentBailoutException;
import org.graalvm.compiler.core.common.calc.Condition;
import org.graalvm.compiler.core.common.calc.FloatConvert;
import org.graalvm.compiler.core.common.spi.ConstantFieldProvider;
import org.graalvm.compiler.core.common.type.ObjectStamp;
import org.graalvm.compiler.core.common.type.Stamp;
import org.graalvm.compiler.core.common.type.StampFactory;
import org.graalvm.compiler.core.common.type.StampPair;
import org.graalvm.compiler.core.common.type.TypeReference;
import org.graalvm.compiler.core.common.util.Util;
import org.graalvm.compiler.debug.Assertions;
import org.graalvm.compiler.debug.CounterKey;
import org.graalvm.compiler.debug.DebugCloseable;
import org.graalvm.compiler.debug.DebugContext;
import org.graalvm.compiler.debug.GraalError;
import org.graalvm.compiler.debug.Indent;
import org.graalvm.compiler.debug.TTY;
import org.graalvm.compiler.graph.Graph.Mark;
import org.graalvm.compiler.graph.Node;
import org.graalvm.compiler.graph.NodeSourcePosition;
import org.graalvm.compiler.graph.iterators.NodeIterable;
import org.graalvm.compiler.java.BciBlockMapping.BciBlock;
import org.graalvm.compiler.java.BciBlockMapping.ExceptionDispatchBlock;
import org.graalvm.compiler.nodes.AbstractBeginNode;
import org.graalvm.compiler.nodes.AbstractMergeNode;
import org.graalvm.compiler.nodes.BeginNode;
import org.graalvm.compiler.nodes.BeginStateSplitNode;
import org.graalvm.compiler.nodes.CallTargetNode;
import org.graalvm.compiler.nodes.CallTargetNode.InvokeKind;
import org.graalvm.compiler.nodes.ConstantNode;
import org.graalvm.compiler.nodes.ControlSplitNode;
import org.graalvm.compiler.nodes.DeoptimizeNode;
import org.graalvm.compiler.nodes.EndNode;
import org.graalvm.compiler.nodes.EntryMarkerNode;
import org.graalvm.compiler.nodes.EntryProxyNode;
import org.graalvm.compiler.nodes.FieldLocationIdentity;
import org.graalvm.compiler.nodes.FixedGuardNode;
import org.graalvm.compiler.nodes.FixedNode;
import org.graalvm.compiler.nodes.FixedWithNextNode;
import org.graalvm.compiler.nodes.FrameState;
import org.graalvm.compiler.nodes.FullInfopointNode;
import org.graalvm.compiler.nodes.IfNode;
import org.graalvm.compiler.nodes.Invoke;
import org.graalvm.compiler.nodes.InvokeNode;
import org.graalvm.compiler.nodes.InvokeWithExceptionNode;
import org.graalvm.compiler.nodes.KillingBeginNode;
import org.graalvm.compiler.nodes.LogicConstantNode;
import org.graalvm.compiler.nodes.LogicNegationNode;
import org.graalvm.compiler.nodes.LogicNode;
import org.graalvm.compiler.nodes.LoopBeginNode;
import org.graalvm.compiler.nodes.LoopEndNode;
import org.graalvm.compiler.nodes.LoopExitNode;
import org.graalvm.compiler.nodes.MergeNode;
import org.graalvm.compiler.nodes.NodeView;
import org.graalvm.compiler.nodes.ParameterNode;
import org.graalvm.compiler.nodes.PiNode;
import org.graalvm.compiler.nodes.ReturnNode;
import org.graalvm.compiler.nodes.StartNode;
import org.graalvm.compiler.nodes.StateSplit;
import org.graalvm.compiler.nodes.StructuredGraph;
import org.graalvm.compiler.nodes.UnwindNode;
import org.graalvm.compiler.nodes.ValueNode;
import org.graalvm.compiler.nodes.calc.AddNode;
import org.graalvm.compiler.nodes.calc.AndNode;
import org.graalvm.compiler.nodes.calc.CompareNode;
import org.graalvm.compiler.nodes.calc.ConditionalNode;
import org.graalvm.compiler.nodes.calc.FloatDivNode;
import org.graalvm.compiler.nodes.calc.FloatConvertNode;
import org.graalvm.compiler.nodes.calc.IntegerBelowNode;
import org.graalvm.compiler.nodes.calc.IntegerEqualsNode;
import org.graalvm.compiler.nodes.calc.IntegerLessThanNode;
import org.graalvm.compiler.nodes.calc.IsNullNode;
import org.graalvm.compiler.nodes.calc.LeftShiftNode;
import org.graalvm.compiler.nodes.calc.MulNode;
import org.graalvm.compiler.nodes.calc.NarrowNode;
import org.graalvm.compiler.nodes.calc.NegateNode;
import org.graalvm.compiler.nodes.calc.NormalizeCompareNode;
import org.graalvm.compiler.nodes.calc.ObjectEqualsNode;
import org.graalvm.compiler.nodes.calc.OrNode;
import org.graalvm.compiler.nodes.calc.RemNode;
import org.graalvm.compiler.nodes.calc.RightShiftNode;
import org.graalvm.compiler.nodes.calc.SignExtendNode;
import org.graalvm.compiler.nodes.calc.SignedDivNode;
import org.graalvm.compiler.nodes.calc.SignedRemNode;
import org.graalvm.compiler.nodes.calc.SubNode;
import org.graalvm.compiler.nodes.calc.UnsignedRightShiftNode;
import org.graalvm.compiler.nodes.calc.XorNode;
import org.graalvm.compiler.nodes.calc.ZeroExtendNode;
import org.graalvm.compiler.nodes.extended.AnchoringNode;
import org.graalvm.compiler.nodes.extended.BranchProbabilityNode;
import org.graalvm.compiler.nodes.extended.BytecodeExceptionNode;
import org.graalvm.compiler.nodes.extended.IntegerSwitchNode;
import org.graalvm.compiler.nodes.extended.LoadHubNode;
import org.graalvm.compiler.nodes.extended.LoadMethodNode;
import org.graalvm.compiler.nodes.extended.MembarNode;
import org.graalvm.compiler.nodes.extended.StateSplitProxyNode;
import org.graalvm.compiler.nodes.extended.ValueAnchorNode;
import org.graalvm.compiler.nodes.graphbuilderconf.ClassInitializationPlugin;
import org.graalvm.compiler.nodes.graphbuilderconf.GraphBuilderConfiguration;
import org.graalvm.compiler.nodes.graphbuilderconf.GraphBuilderConfiguration.BytecodeExceptionMode;
import org.graalvm.compiler.nodes.graphbuilderconf.GraphBuilderContext;
import org.graalvm.compiler.nodes.graphbuilderconf.InlineInvokePlugin;
import org.graalvm.compiler.nodes.graphbuilderconf.InlineInvokePlugin.InlineInfo;
import org.graalvm.compiler.nodes.graphbuilderconf.IntrinsicContext;
import org.graalvm.compiler.nodes.graphbuilderconf.InvocationPlugin;
import org.graalvm.compiler.nodes.graphbuilderconf.InvocationPlugins.InvocationPluginReceiver;
import org.graalvm.compiler.nodes.graphbuilderconf.InvokeDynamicPlugin;
import org.graalvm.compiler.nodes.graphbuilderconf.NodePlugin;
import org.graalvm.compiler.nodes.graphbuilderconf.ProfilingPlugin;
import org.graalvm.compiler.nodes.java.ArrayLengthNode;
import org.graalvm.compiler.nodes.java.ExceptionObjectNode;
import org.graalvm.compiler.nodes.java.FinalFieldBarrierNode;
import org.graalvm.compiler.nodes.java.InstanceOfNode;
import org.graalvm.compiler.nodes.java.LoadFieldNode;
import org.graalvm.compiler.nodes.java.LoadIndexedNode;
import org.graalvm.compiler.nodes.java.MethodCallTargetNode;
import org.graalvm.compiler.nodes.java.MonitorEnterNode;
import org.graalvm.compiler.nodes.java.MonitorExitNode;
import org.graalvm.compiler.nodes.java.MonitorIdNode;
import org.graalvm.compiler.nodes.java.NewArrayNode;
import org.graalvm.compiler.nodes.java.NewInstanceNode;
import org.graalvm.compiler.nodes.java.NewMultiArrayNode;
import org.graalvm.compiler.nodes.java.RegisterFinalizerNode;
import org.graalvm.compiler.nodes.java.StoreFieldNode;
import org.graalvm.compiler.nodes.java.StoreIndexedNode;
import org.graalvm.compiler.nodes.spi.StampProvider;
import org.graalvm.compiler.nodes.type.StampTool;
import org.graalvm.compiler.nodes.util.GraphUtil;
import org.graalvm.compiler.options.OptionValues;
import org.graalvm.compiler.phases.OptimisticOptimizations;
import org.graalvm.compiler.phases.util.ValueMergeUtil;
import org.graalvm.util.EconomicMap;
import org.graalvm.util.Equivalence;
import org.graalvm.word.LocationIdentity;
import jdk.vm.ci.code.BailoutException;
import jdk.vm.ci.code.BytecodeFrame;
import jdk.vm.ci.code.CodeUtil;
import jdk.vm.ci.code.site.InfopointReason;
import jdk.vm.ci.meta.ConstantPool;
import jdk.vm.ci.meta.ConstantReflectionProvider;
import jdk.vm.ci.meta.DeoptimizationAction;
import jdk.vm.ci.meta.DeoptimizationReason;
import jdk.vm.ci.meta.JavaConstant;
import jdk.vm.ci.meta.JavaField;
import jdk.vm.ci.meta.JavaKind;
import jdk.vm.ci.meta.JavaMethod;
import jdk.vm.ci.meta.JavaType;
import jdk.vm.ci.meta.JavaTypeProfile;
import jdk.vm.ci.meta.JavaTypeProfile.ProfiledType;
import jdk.vm.ci.meta.LineNumberTable;
import jdk.vm.ci.meta.MetaAccessProvider;
import jdk.vm.ci.meta.ProfilingInfo;
import jdk.vm.ci.meta.RawConstant;
import jdk.vm.ci.meta.ResolvedJavaField;
import jdk.vm.ci.meta.ResolvedJavaMethod;
import jdk.vm.ci.meta.ResolvedJavaType;
import jdk.vm.ci.meta.Signature;
import jdk.vm.ci.meta.TriState;
import org.graalvm.compiler.core.common.type.IntegerStamp;
/**
* The {@code GraphBuilder} class parses the bytecode of a method and builds the IR graph.
*/
public class BytecodeParser implements GraphBuilderContext {
/**
* The minimum value to which {@link BytecodeParserOptions#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 BytecodeParserOptions#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 CounterKey BytecodesParsed = DebugContext.counter("BytecodesParsed");
protected static final CounterKey EXPLICIT_EXCEPTIONS = DebugContext.counter("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;
List<ReturnToCallerData> returnDataList;
/**
* Creates a scope for root parsing an intrinsic.
*
* @param parser the parsing context of the intrinsic
*/
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
*/
IntrinsicScope(BytecodeParser parser, JavaKind[] argSlotKinds, ValueNode[] args) {
assert !parser.parsingIntrinsic();
this.parser = parser;
mark = parser.getGraph().getMark();
stateBefore = parser.frameState.create(parser.bci(), parser.getNonIntrinsicAncestor(), false, argSlotKinds, args);
}
@Override
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) {
StructuredGraph graph = parser.getGraph();
graph.getDebug().dump(DebugContext.DETAILED_LEVEL, graph, "Before processPlaceholderFrameStates in %s", parser.method);
boolean sawInvalidFrameState = false;
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) {
if (parser.getInvokeReturnType() == null) {
// A frame state in a root compiled intrinsic.
assert intrinsic.isCompilationRoot();
FrameState newFrameState = graph.add(new FrameState(BytecodeFrame.INVALID_FRAMESTATE_BCI));
frameState.replaceAndDelete(newFrameState);
} else {
JavaKind returnKind = parser.getInvokeReturnType().getJavaKind();
FrameStateBuilder frameStateBuilder = parser.frameState;
assert !frameState.rethrowException();
if (frameState.stackSize() != 0) {
ValueNode returnVal = frameState.stackAt(0);
if (!ReturnToCallerData.containsReturnValue(returnDataList, returnVal)) {
throw new GraalError("AFTER_BCI frame state within an intrinsic has a non-return value on the stack: %s", returnVal);
}
// Swap the top-of-stack value with the return value
ValueNode tos = frameStateBuilder.pop(returnKind);
assert tos.getStackKind() == returnVal.getStackKind();
FrameState newFrameState = frameStateBuilder.create(parser.stream.nextBCI(), parser.getNonIntrinsicAncestor(), false, new JavaKind[]{returnKind},
new ValueNode[]{returnVal});
frameState.replaceAndDelete(newFrameState);
newFrameState.setNodeSourcePosition(frameState.getNodeSourcePosition());
frameStateBuilder.push(returnKind, tos);
} else if (returnKind != JavaKind.Void) {
// If the intrinsic returns a non-void value, then any frame
// state with an empty stack is invalid as it cannot
// be used to deoptimize to just after the call returns.
// These invalid frame states are expected to be removed
// by later compilation stages.
FrameState newFrameState = graph.add(new FrameState(BytecodeFrame.INVALID_FRAMESTATE_BCI));
newFrameState.setNodeSourcePosition(frameState.getNodeSourcePosition());
frameState.replaceAndDelete(newFrameState);
sawInvalidFrameState = true;
} else {
// An intrinsic for a void method.
FrameState newFrameState = frameStateBuilder.create(parser.stream.nextBCI(), null);
newFrameState.setNodeSourcePosition(frameState.getNodeSourcePosition());
frameState.replaceAndDelete(newFrameState);
}
}
} else if (frameState.bci == BytecodeFrame.BEFORE_BCI) {
if (stateBefore == null) {
stateBefore = graph.start().stateAfter();
}
if (stateBefore != frameState) {
frameState.replaceAndDelete(stateBefore);
}
} else if (frameState.bci == BytecodeFrame.AFTER_EXCEPTION_BCI) {
// This is a frame state for the entry point to an exception
// dispatcher in an intrinsic. For example, the invoke denoting
// a partial intrinsic exit will have an edge to such a
// dispatcher if the profile for the original invoke being
// intrinsified indicates an exception was seen. As per JVM
// bytecode semantics, the interpreter expects a single
// value on the stack on entry to an exception handler,
// namely the exception object.
assert frameState.rethrowException();
ExceptionObjectNode exceptionObject = (ExceptionObjectNode) frameState.stackAt(0);
FrameStateBuilder dispatchState = parser.frameState.copy();
dispatchState.clearStack();
dispatchState.push(JavaKind.Object, exceptionObject);
dispatchState.setRethrowException(true);
FrameState newFrameState = dispatchState.create(parser.bci(), exceptionObject);
frameState.replaceAndDelete(newFrameState);
newFrameState.setNodeSourcePosition(frameState.getNodeSourcePosition());
} else {
assert frameState.bci == BytecodeFrame.INVALID_FRAMESTATE_BCI;
}
}
}
}
if (sawInvalidFrameState) {
JavaKind returnKind = parser.getInvokeReturnType().getJavaKind();
FrameStateBuilder frameStateBuilder = parser.frameState;
ValueNode returnValue = frameStateBuilder.pop(returnKind);
StateSplitProxyNode proxy = graph.add(new StateSplitProxyNode(returnValue));
parser.lastInstr.setNext(proxy);
frameStateBuilder.push(returnKind, proxy);
proxy.setStateAfter(parser.createFrameState(parser.stream.nextBCI(), proxy));
parser.lastInstr = proxy;
}
graph.getDebug().dump(DebugContext.DETAILED_LEVEL, graph, "After processPlaceholderFrameStates in %s", parser.method);
}
}
private static class Target {
FixedNode fixed;
FrameStateBuilder state;
Target(FixedNode fixed, FrameStateBuilder state) {
this.fixed = fixed;
this.state = state;
}
}
@SuppressWarnings("serial")
public static class BytecodeParserError extends GraalError {
public BytecodeParserError(Throwable cause) {
super(cause);
}
public BytecodeParserError(String msg, Object... args) {
super(msg, args);
}
}
protected static class ReturnToCallerData {
protected final ValueNode returnValue;
protected final FixedWithNextNode beforeReturnNode;
protected ReturnToCallerData(ValueNode returnValue, FixedWithNextNode beforeReturnNode) {
this.returnValue = returnValue;
this.beforeReturnNode = beforeReturnNode;
}
static boolean containsReturnValue(List<ReturnToCallerData> list, ValueNode value) {
for (ReturnToCallerData e : list) {
if (e.returnValue == value) {
return true;
}
}
return false;
}
}
private final GraphBuilderPhase.Instance graphBuilderInstance;
protected final StructuredGraph graph;
protected final OptionValues options;
protected final DebugContext debug;
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 List<ReturnToCallerData> returnDataList;
private ValueNode unwindValue;
private FixedWithNextNode beforeUnwindNode;
protected FixedWithNextNode lastInstr; // the last instruction added
private boolean controlFlowSplit;
private final InvocationPluginReceiver invocationPluginReceiver = new InvocationPluginReceiver(this);
private FixedWithNextNode[] firstInstructionArray;
private FrameStateBuilder[] entryStateArray;
private boolean finalBarrierRequired;
private ValueNode originalReceiver;
protected BytecodeParser(GraphBuilderPhase.Instance graphBuilderInstance, StructuredGraph graph, BytecodeParser parent, ResolvedJavaMethod method,
int entryBCI, IntrinsicContext intrinsicContext) {
this.bytecodeProvider = intrinsicContext == null ? new ResolvedJavaMethodBytecodeProvider() : intrinsicContext.getBytecodeProvider();
this.code = bytecodeProvider.getBytecode(method);
this.method = code.getMethod();
this.graphBuilderInstance = graphBuilderInstance;
this.graph = graph;
this.options = graph.getOptions();
this.debug = graph.getDebug();
this.graphBuilderConfig = graphBuilderInstance.graphBuilderConfig;
this.optimisticOpts = graphBuilderInstance.optimisticOpts;
this.metaAccess = graphBuilderInstance.metaAccess;
this.stampProvider = graphBuilderInstance.stampProvider;
this.constantReflection = graphBuilderInstance.constantReflection;
this.constantFieldProvider = graphBuilderInstance.constantFieldProvider;
this.stream = new BytecodeStream(code.getCode());
this.profilingInfo = graph.useProfilingInfo() ? code.getProfilingInfo() : null;
this.constantPool = code.getConstantPool();
this.intrinsicContext = intrinsicContext;
this.entryBCI = entryBCI;
this.parent = parent;
assert code.getCode() != null : "method must contain bytecodes: " + method;
if (graphBuilderConfig.insertFullInfopoints() && !parsingIntrinsic()) {
lnt = code.getLineNumberTable();
previousLineNumber = -1;
}
}
protected GraphBuilderPhase.Instance getGraphBuilderInstance() {
return graphBuilderInstance;
}
public ValueNode getUnwindValue() {
return unwindValue;
}
public FixedWithNextNode getBeforeUnwindNode() {
return this.beforeUnwindNode;
}
@SuppressWarnings("try")
protected void buildRootMethod() {
FrameStateBuilder startFrameState = new FrameStateBuilder(this, code, graph);
startFrameState.initializeForMethodStart(graph.getAssumptions(), graphBuilderConfig.eagerResolving() || intrinsicContext != null, graphBuilderConfig.getPlugins());
try (IntrinsicScope s = intrinsicContext != null ? new IntrinsicScope(this) : null) {
build(graph.start(), startFrameState);
}
cleanupFinalGraph();
ComputeLoopFrequenciesClosure.compute(graph);
}
@SuppressWarnings("try")
protected void build(FixedWithNextNode startInstruction, FrameStateBuilder startFrameState) {
if (PrintProfilingInformation.getValue(options) && profilingInfo != null) {
TTY.println("Profiling info for " + method.format("%H.%n(%p)"));
TTY.println(Util.indent(profilingInfo.toString(method, CodeUtil.NEW_LINE), " "));
}
try (Indent indent = debug.logAndIndent("build graph for %s", method)) {
if (bytecodeProvider.shouldRecordMethodDependencies()) {
assert getParent() != null || method.equals(graph.method());
// Record method dependency in the graph
graph.recordMethod(method);
}
// compute the block map, setup exception handlers and get the entrypoint(s)
BciBlockMapping newMapping = BciBlockMapping.create(stream, code, options, graph.getDebug());
this.blockMap = newMapping;
this.firstInstructionArray = new FixedWithNextNode[blockMap.getBlockCount()];
this.entryStateArray = new FrameStateBuilder[blockMap.getBlockCount()];
if (!method.isStatic()) {
originalReceiver = startFrameState.loadLocal(0, JavaKind.Object);
}
/*
* 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 (DebugContext.Scope s = debug.scope("LivenessAnalysis")) {
int maxLocals = method.getMaxLocals();
liveness = LocalLiveness.compute(debug, 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()) {
finishPrepare(lastInstr, BytecodeFrame.BEFORE_BCI);
// add a monitor enter to the start block
methodSynchronizedObject = synchronizedObject(frameState, method);
frameState.clearNonLiveLocals(startBlock, liveness, true);
assert bci() == 0;
genMonitorEnter(methodSynchronizedObject, bci());
}
ProfilingPlugin profilingPlugin = this.graphBuilderConfig.getPlugins().getProfilingPlugin();
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
profilingPlugin.profileInvoke(this, method, stateBefore);
}
finishPrepare(lastInstr, 0);
genInfoPointNode(InfopointReason.METHOD_START, null);
currentBlock = blockMap.getStartBlock();
setEntryState(startBlock, frameState);
if (startBlock.isLoopHeader) {
appendGoto(startBlock);
} else {
setFirstInstruction(startBlock, lastInstr);
}
BciBlock[] blocks = blockMap.getBlocks();
for (BciBlock block : blocks) {
processBlock(block);
}
}
}
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 synthetic code (start nodes and unwind nodes).
*
* @param instruction the current last instruction
* @param bci the current bci
*/
protected void finishPrepare(FixedWithNextNode instruction, int bci) {
}
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.
for (BeginNode beginNode : graph.getNodes(BeginNode.TYPE)) {
Node predecessor = beginNode.predecessor();
if (predecessor instanceof ControlSplitNode) {
// The begin node is necessary.
} else if (!beginNode.hasUsages()) {
GraphUtil.unlinkFixedNode(beginNode);
beginNode.safeDelete();
}
}
}
/**
* 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;
}
} 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, new ResolvedJavaMethodBytecode(original), 0, locals, stack, stackSize, locks, monitorIds, false, false));
}
return stateAfterStart;
}
/**
* @param type the unresolved type of the constant
*/
protected void handleUnresolvedLoadConstant(JavaType type) {
assert !graphBuilderConfig.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
/*
* Track source position for deopt nodes even if
* GraphBuilderConfiguration.trackNodeSourcePosition is not set.
*/
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @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.unresolvedIsError();
append(new FixedGuardNode(graph.addOrUniqueWithInputs(IsNullNode.create(object)), Unresolved, InvalidateRecompile));
frameState.push(JavaKind.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.unresolvedIsError();
AbstractBeginNode successor = graph.add(new BeginNode());
DeoptimizeNode deopt = graph.add(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
append(new IfNode(graph.addOrUniqueWithInputs(IsNullNode.create(object)), successor, deopt, 1));
lastInstr = successor;
frameState.push(JavaKind.Int, appendConstant(JavaConstant.INT_0));
}
/**
* @param type the type being instantiated
*/
protected void handleUnresolvedNewInstance(JavaType type) {
assert !graphBuilderConfig.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @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.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @param type the type being instantiated
* @param dims the dimensions for the multi-array
*/
protected void handleUnresolvedNewMultiArray(JavaType type, ValueNode[] dims) {
assert !graphBuilderConfig.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @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.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @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.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @param type
*/
protected void handleUnresolvedExceptionType(JavaType type) {
assert !graphBuilderConfig.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
/**
* @param javaMethod
* @param invokeKind
*/
protected void handleUnresolvedInvoke(JavaMethod javaMethod, InvokeKind invokeKind) {
assert !graphBuilderConfig.unresolvedIsError();
DeoptimizeNode deopt = append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
deopt.updateNodeSourcePosition(() -> createBytecodePosition());
}
private AbstractBeginNode handleException(ValueNode exceptionObject, int bci, boolean deoptimizeOnly) {
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)));
FrameStateBuilder dispatchState = frameState.copy();
dispatchState.clearStack();
AbstractBeginNode dispatchBegin;
if (exceptionObject == null) {
ExceptionObjectNode newExceptionObject = graph.add(new ExceptionObjectNode(metaAccess));
dispatchBegin = newExceptionObject;
dispatchState.push(JavaKind.Object, dispatchBegin);
dispatchState.setRethrowException(true);
newExceptionObject.setStateAfter(dispatchState.create(bci, newExceptionObject));
} else {
dispatchBegin = graph.add(new BeginNode());
dispatchState.push(JavaKind.Object, exceptionObject);
dispatchState.setRethrowException(true);
}
this.controlFlowSplit = true;
FixedWithNextNode finishedDispatch = finishInstruction(dispatchBegin, dispatchState);
if (deoptimizeOnly) {
DeoptimizeNode deoptimizeNode = graph.add(new DeoptimizeNode(DeoptimizationAction.None, DeoptimizationReason.TransferToInterpreter));
dispatchBegin.setNext(BeginNode.begin(deoptimizeNode));
} else {
createHandleExceptionTarget(finishedDispatch, bci, dispatchState);
}
return dispatchBegin;
}
protected void createHandleExceptionTarget(FixedWithNextNode finishedDispatch, int bci, FrameStateBuilder dispatchState) {
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();
}
FixedNode target = createTarget(dispatchBlock, dispatchState);
finishedDispatch.setNext(target);
}
protected ValueNode genLoadIndexed(ValueNode array, ValueNode index, JavaKind kind) {
return LoadIndexedNode.create(graph.getAssumptions(), array, index, kind, metaAccess, constantReflection);
}
protected void genStoreIndexed(ValueNode array, ValueNode index, JavaKind kind, ValueNode value) {
add(new StoreIndexedNode(array, index, kind, value));
}
protected ValueNode genIntegerAdd(ValueNode x, ValueNode y) {
return AddNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genIntegerSub(ValueNode x, ValueNode y) {
return SubNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genIntegerMul(ValueNode x, ValueNode y) {
return MulNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genFloatAdd(ValueNode x, ValueNode y) {
return AddNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genFloatSub(ValueNode x, ValueNode y) {
return SubNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genFloatMul(ValueNode x, ValueNode y) {
return MulNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genFloatDiv(ValueNode x, ValueNode y) {
return FloatDivNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genFloatRem(ValueNode x, ValueNode y) {
return RemNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genIntegerDiv(ValueNode x, ValueNode y) {
return SignedDivNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genIntegerRem(ValueNode x, ValueNode y) {
return SignedRemNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genNegateOp(ValueNode x) {
return NegateNode.create(x, NodeView.DEFAULT);
}
protected ValueNode genLeftShift(ValueNode x, ValueNode y) {
return LeftShiftNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genRightShift(ValueNode x, ValueNode y) {
return RightShiftNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genUnsignedRightShift(ValueNode x, ValueNode y) {
return UnsignedRightShiftNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genAnd(ValueNode x, ValueNode y) {
return AndNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genOr(ValueNode x, ValueNode y) {
return OrNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genXor(ValueNode x, ValueNode y) {
return XorNode.create(x, y, NodeView.DEFAULT);
}
protected ValueNode genNormalizeCompare(ValueNode x, ValueNode y, boolean isUnorderedLess) {
return NormalizeCompareNode.create(x, y, isUnorderedLess, JavaKind.Int, constantReflection);
}
protected ValueNode genFloatConvert(FloatConvert op, ValueNode input) {
return FloatConvertNode.create(op, input, NodeView.DEFAULT);
}
protected ValueNode genNarrow(ValueNode input, int bitCount) {
return NarrowNode.create(input, bitCount, NodeView.DEFAULT);
}
protected ValueNode genSignExtend(ValueNode input, int bitCount) {
return SignExtendNode.create(input, bitCount, NodeView.DEFAULT);
}
protected ValueNode genZeroExtend(ValueNode input, int bitCount) {
return ZeroExtendNode.create(input, bitCount, NodeView.DEFAULT);
}
protected void genGoto() {
ProfilingPlugin profilingPlugin = this.graphBuilderConfig.getPlugins().getProfilingPlugin();
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
int targetBci = currentBlock.getSuccessor(0).startBci;
profilingPlugin.profileGoto(this, method, bci(), targetBci, stateBefore);
}
appendGoto(currentBlock.getSuccessor(0));
assert currentBlock.numNormalSuccessors() == 1;
}
protected LogicNode genObjectEquals(ValueNode x, ValueNode y) {
return ObjectEqualsNode.create(constantReflection, metaAccess, options, x, y, NodeView.DEFAULT);
}
protected LogicNode genIntegerEquals(ValueNode x, ValueNode y) {
return IntegerEqualsNode.create(constantReflection, metaAccess, options, null, x, y, NodeView.DEFAULT);
}
protected LogicNode genIntegerLessThan(ValueNode x, ValueNode y) {
return IntegerLessThanNode.create(constantReflection, metaAccess, options, null, x, y, NodeView.DEFAULT);
}
protected ValueNode genUnique(ValueNode x) {
return graph.addOrUniqueWithInputs(x);
}
protected LogicNode genUnique(LogicNode x) {
return graph.addOrUniqueWithInputs(x);
}
protected ValueNode genIfNode(LogicNode condition, FixedNode falseSuccessor, FixedNode trueSuccessor, double d) {
return new IfNode(condition, falseSuccessor, trueSuccessor, d);
}
protected void genThrow() {
genInfoPointNode(InfopointReason.BYTECODE_POSITION, null);
ValueNode exception = frameState.pop(JavaKind.Object);
FixedGuardNode nullCheck = append(new FixedGuardNode(graph.addOrUniqueWithInputs(IsNullNode.create(exception)), NullCheckException, InvalidateReprofile, true));
ValueNode nonNullException = graph.maybeAddOrUnique(PiNode.create(exception, exception.stamp(NodeView.DEFAULT).join(objectNonNull()), nullCheck));
lastInstr.setNext(handleException(nonNullException, bci(), false));
}
protected LogicNode createInstanceOf(TypeReference type, ValueNode object) {
return InstanceOfNode.create(type, object);
}
protected AnchoringNode createAnchor(JavaTypeProfile profile) {
if (profile == null || profile.getNotRecordedProbability() > 0.0) {
return null;
} else {
return append(new ValueAnchorNode(null));
}
}
protected LogicNode createInstanceOf(TypeReference type, ValueNode object, JavaTypeProfile profile) {
return InstanceOfNode.create(type, object, profile, createAnchor(profile));
}
protected LogicNode createInstanceOfAllowNull(TypeReference type, ValueNode object, JavaTypeProfile profile) {
return InstanceOfNode.createAllowNull(type, object, profile, createAnchor(profile));
}
protected ValueNode genConditional(ValueNode x) {
return ConditionalNode.create((LogicNode) x, NodeView.DEFAULT);
}
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, ValueNode[] dimensions) {
return new NewMultiArrayNode(type, dimensions);
}
protected ValueNode genLoadField(ValueNode receiver, ResolvedJavaField field) {
StampPair stamp = graphBuilderConfig.getPlugins().getOverridingStamp(this, field.getType(), false);
if (stamp == null) {
return LoadFieldNode.create(getConstantFieldProvider(), getConstantReflection(), getMetaAccess(), getOptions(),
getAssumptions(), receiver, field, false, false);
} else {
return LoadFieldNode.createOverrideStamp(getConstantFieldProvider(), getConstantReflection(), getMetaAccess(), getOptions(),
stamp, receiver, field, false, false);
}
}
protected StateSplitProxyNode genVolatileFieldReadProxy(ValueNode fieldRead) {
return new StateSplitProxyNode(fieldRead);
}
protected ValueNode emitExplicitNullCheck(ValueNode receiver) {
if (StampTool.isPointerNonNull(receiver.stamp(NodeView.DEFAULT))) {
return receiver;
}
BytecodeExceptionNode exception = graph.add(new BytecodeExceptionNode(metaAccess, NullPointerException.class));
AbstractBeginNode falseSucc = graph.add(new BeginNode());
ValueNode nonNullReceiver = graph.addOrUniqueWithInputs(PiNode.create(receiver, objectNonNull(), falseSucc));
append(new IfNode(graph.addOrUniqueWithInputs(IsNullNode.create(receiver)), exception, falseSucc, SLOW_PATH_PROBABILITY));
lastInstr = falseSucc;
exception.setStateAfter(createFrameState(bci(), exception));
exception.setNext(handleException(exception, bci(), false));
EXPLICIT_EXCEPTIONS.increment(debug);
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(genUnique(IntegerBelowNode.create(constantReflection, metaAccess, options, null, index, length, NodeView.DEFAULT)), trueSucc, exception, FAST_PATH_PROBABILITY));
lastInstr = trueSucc;
exception.setStateAfter(createFrameState(bci(), exception));
exception.setNext(handleException(exception, bci(), false));
}
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(int cpi, int opcode) {
JavaMethod target = lookupMethod(cpi, opcode);
genInvokeStatic(target);
}
void genInvokeStatic(JavaMethod target) {
if (callTargetIsResolved(target)) {
ResolvedJavaMethod resolvedTarget = (ResolvedJavaMethod) target;
ResolvedJavaType holder = resolvedTarget.getDeclaringClass();
if (!holder.isInitialized() && ResolveClassBeforeStaticInvoke.getValue(options)) {
handleUnresolvedInvoke(target, InvokeKind.Static);
} else {
ValueNode classInit = null;
ClassInitializationPlugin classInitializationPlugin = graphBuilderConfig.getPlugins().getClassInitializationPlugin();
if (classInitializationPlugin != null && classInitializationPlugin.shouldApply(this, resolvedTarget.getDeclaringClass())) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
classInit = classInitializationPlugin.apply(this, resolvedTarget.getDeclaringClass(), stateBefore);
}
ValueNode[] args = frameState.popArguments(resolvedTarget.getSignature().getParameterCount(false));
Invoke invoke = appendInvoke(InvokeKind.Static, resolvedTarget, args);
if (invoke != null) {
invoke.setClassInit(classInit);
}
}
} else {
handleUnresolvedInvoke(target, InvokeKind.Static);
}
}
protected void genInvokeInterface(int cpi, int opcode) {
JavaMethod target = lookupMethod(cpi, opcode);
genInvokeInterface(target);
}
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(int cpi, int opcode) {
JavaMethod target = lookupMethod(cpi, opcode);
genInvokeDynamic(target);
}
void genInvokeDynamic(JavaMethod target) {
if (!(target instanceof ResolvedJavaMethod) || !genDynamicInvokeHelper((ResolvedJavaMethod) target, stream.readCPI4(), INVOKEDYNAMIC)) {
handleUnresolvedInvoke(target, InvokeKind.Static);
}
}
protected void genInvokeVirtual(int cpi, int opcode) {
JavaMethod target = lookupMethod(cpi, opcode);
genInvokeVirtual(target);
}
private boolean genDynamicInvokeHelper(ResolvedJavaMethod target, int cpi, int opcode) {
assert opcode == INVOKEDYNAMIC || opcode == INVOKEVIRTUAL;
InvokeDynamicPlugin invokeDynamicPlugin = graphBuilderConfig.getPlugins().getInvokeDynamicPlugin();
if (opcode == INVOKEVIRTUAL && invokeDynamicPlugin != null && !invokeDynamicPlugin.isResolvedDynamicInvoke(this, cpi, opcode)) {
// regular invokevirtual, let caller handle it
return false;
}
if (GeneratePIC.getValue(options) && (invokeDynamicPlugin == null || !invokeDynamicPlugin.supportsDynamicInvoke(this, cpi, opcode))) {
// bail out if static compiler and no dynamic type support
append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
return true;
}
JavaConstant appendix = constantPool.lookupAppendix(cpi, opcode);
ValueNode appendixNode = null;
if (appendix != null) {
if (invokeDynamicPlugin != null) {
invokeDynamicPlugin.recordDynamicMethod(this, cpi, opcode, target);
// Will perform runtime type checks and static initialization
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
appendixNode = invokeDynamicPlugin.genAppendixNode(this, cpi, opcode, appendix, stateBefore);
} else {
appendixNode = ConstantNode.forConstant(appendix, metaAccess, graph);
}
frameState.push(JavaKind.Object, appendixNode);
} else if (GeneratePIC.getValue(options)) {
// Need to emit runtime guard and perform static initialization.
// Not implemented yet.
append(new DeoptimizeNode(InvalidateRecompile, Unresolved));
return true;
}
boolean hasReceiver = (opcode == INVOKEDYNAMIC) ? false : !target.isStatic();
ValueNode[] args = frameState.popArguments(target.getSignature().getParameterCount(hasReceiver));
if (hasReceiver) {
appendInvoke(InvokeKind.Virtual, target, args);
} else {
appendInvoke(InvokeKind.Static, target, args);
}
return true;
}
void genInvokeVirtual(JavaMethod target) {
if (!genInvokeVirtualHelper(target)) {
handleUnresolvedInvoke(target, InvokeKind.Virtual);
}
}
private boolean genInvokeVirtualHelper(JavaMethod target) {
if (!callTargetIsResolved(target)) {
return false;
}
ResolvedJavaMethod resolvedTarget = (ResolvedJavaMethod) target;
int cpi = stream.readCPI();
/*
* Special handling for runtimes that rewrite an invocation of MethodHandle.invoke(...) or
* MethodHandle.invokeExact(...) to a static adapter. HotSpot does this - see
* https://wiki.openjdk.java.net/display/HotSpot/Method+handles+and+invokedynamic
*/
if (genDynamicInvokeHelper(resolvedTarget, cpi, INVOKEVIRTUAL)) {
return true;
}
ValueNode[] args = frameState.popArguments(target.getSignature().getParameterCount(true));
appendInvoke(InvokeKind.Virtual, (ResolvedJavaMethod) target, args);
return true;
}
protected void genInvokeSpecial(int cpi, int opcode) {
JavaMethod target = lookupMethod(cpi, opcode);
genInvokeSpecial(target);
}
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);
}
}
static class CurrentInvoke {
final ValueNode[] args;
final InvokeKind kind;
final JavaType returnType;
CurrentInvoke(ValueNode[] args, InvokeKind kind, JavaType returnType) {
this.args = args;
this.kind = kind;
this.returnType = returnType;
}
}
private CurrentInvoke currentInvoke;
protected FrameStateBuilder frameState;
protected BciBlock currentBlock;
protected final BytecodeStream stream;
protected final GraphBuilderConfiguration graphBuilderConfig;
protected final ResolvedJavaMethod method;
protected final Bytecode code;
protected final BytecodeProvider bytecodeProvider;
protected final ProfilingInfo profilingInfo;
protected final OptimisticOptimizations optimisticOpts;
protected final ConstantPool constantPool;
protected final MetaAccessProvider metaAccess;
private final ConstantReflectionProvider constantReflection;
private final ConstantFieldProvider constantFieldProvider;
private final StampProvider stampProvider;
protected final IntrinsicContext intrinsicContext;
@Override
public InvokeKind getInvokeKind() {
return currentInvoke == null ? null : currentInvoke.kind;
}
@Override
public JavaType getInvokeReturnType() {
return currentInvoke == null ? null : currentInvoke.returnType;
}
private boolean forceInliningEverything;
@Override
public void handleReplacedInvoke(InvokeKind invokeKind, ResolvedJavaMethod targetMethod, ValueNode[] args, boolean inlineEverything) {
boolean previous = forceInliningEverything;
forceInliningEverything = previous || inlineEverything;
try {
appendInvoke(invokeKind, targetMethod, args);
} finally {
forceInliningEverything = previous;
}
}
@Override
public void handleReplacedInvoke(CallTargetNode callTarget, JavaKind resultType) {
BytecodeParser intrinsicCallSiteParser = getNonIntrinsicAncestor();
ExceptionEdgeAction exceptionEdgeAction = intrinsicCallSiteParser == null ? getActionForInvokeExceptionEdge(null) : intrinsicCallSiteParser.getActionForInvokeExceptionEdge(null);
createNonInlinedInvoke(exceptionEdgeAction, bci(), callTarget, resultType);
}
protected Invoke 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;
}
}
JavaKind resultType = targetMethod.getSignature().getReturnKind();
if (!parsingIntrinsic() && DeoptALot.getValue(options)) {
append(new DeoptimizeNode(DeoptimizationAction.None, RuntimeConstraint));
frameState.pushReturn(resultType, ConstantNode.defaultForKind(resultType, graph));
return null;
}
JavaType returnType = targetMethod.getSignature().getReturnType(method.getDeclaringClass());
if (graphBuilderConfig.eagerResolving() || parsingIntrinsic()) {
returnType = returnType.resolve(targetMethod.getDeclaringClass());
}
if (invokeKind.hasReceiver()) {
args[0] = emitExplicitExceptions(args[0]);
}
if (initialInvokeKind == InvokeKind.Special && !targetMethod.isConstructor()) {
emitCheckForInvokeSuperSpecial(args);
}
InlineInfo inlineInfo = null;
try {
currentInvoke = new CurrentInvoke(args, invokeKind, returnType);
if (tryNodePluginForInvocation(args, targetMethod)) {
if (TraceParserPlugins.getValue(options)) {
traceWithContext("used node plugin for %s", targetMethod.format("%h.%n(%p)"));
}
return null;
}
if (invokeKind.hasReceiver() && args[0].isNullConstant()) {
append(new DeoptimizeNode(InvalidateRecompile, NullCheckException));
return null;
}
if (!invokeKind.isIndirect() || (UseGuardedIntrinsics.getValue(options) && !GeneratePIC.getValue(options))) {
if (tryInvocationPlugin(invokeKind, args, targetMethod, resultType, returnType)) {
if (TraceParserPlugins.getValue(options)) {
traceWithContext("used invocation plugin for %s", targetMethod.format("%h.%n(%p)"));
}
return null;
}
}
if (invokeKind.isDirect()) {
inlineInfo = tryInline(args, targetMethod);
if (inlineInfo == SUCCESSFULLY_INLINED) {
return null;
}
}
} finally {
currentInvoke = null;
}
int invokeBci = bci();
JavaTypeProfile profile = getProfileForInvoke(invokeKind);
ExceptionEdgeAction edgeAction = getActionForInvokeExceptionEdge(inlineInfo);
boolean partialIntrinsicExit = false;
if (intrinsicContext != null && intrinsicContext.isCallToOriginal(targetMethod)) {
partialIntrinsicExit = true;
ResolvedJavaMethod originalMethod = intrinsicContext.getOriginalMethod();
BytecodeParser intrinsicCallSiteParser = getNonIntrinsicAncestor();
if (intrinsicCallSiteParser != null) {
// When exiting a partial intrinsic, the invoke to the original
// must use the same context as the call to the intrinsic.
invokeBci = intrinsicCallSiteParser.bci();
profile = intrinsicCallSiteParser.getProfileForInvoke(invokeKind);
edgeAction = intrinsicCallSiteParser.getActionForInvokeExceptionEdge(inlineInfo);
} else {
// We are parsing the intrinsic for the root compilation or for inlining,
// This call is a partial intrinsic exit, and we do not have profile information
// for this callsite. We also have to assume that the call needs an exception
// edge. Finally, we know that this intrinsic is parsed for late inlining,
// so the bci must be set to unknown, so that the inliner patches it later.
assert intrinsicContext.isPostParseInlined();
invokeBci = BytecodeFrame.UNKNOWN_BCI;
profile = null;
edgeAction = graph.method().getAnnotation(Snippet.class) == null ? ExceptionEdgeAction.INCLUDE_AND_HANDLE : ExceptionEdgeAction.OMIT;
}
if (originalMethod.isStatic()) {
invokeKind = InvokeKind.Static;
} else {
// The original call to the intrinsic must have been devirtualized
// otherwise we wouldn't be here.
invokeKind = InvokeKind.Special;
}
Signature sig = originalMethod.getSignature();
returnType = sig.getReturnType(method.getDeclaringClass());
resultType = sig.getReturnKind();
assert intrinsicContext.allowPartialIntrinsicArgumentMismatch() || checkPartialIntrinsicExit(intrinsicCallSiteParser == null ? null : intrinsicCallSiteParser.currentInvoke.args, args);
targetMethod = originalMethod;
}
Invoke invoke = createNonInlinedInvoke(edgeAction, invokeBci, args, targetMethod, invokeKind, resultType, returnType, profile);
if (partialIntrinsicExit) {
// This invoke must never be later inlined as it might select the intrinsic graph.
// Until there is a mechanism to guarantee that any late inlining will not select
// the intrinsic graph, prevent this invoke from being inlined.
invoke.setUseForInlining(false);
}
return invoke;
}
/**
* Checks that the class of the receiver of an {@link Bytecodes#INVOKESPECIAL} in a method
* declared in an interface (i.e., a default method) is assignable to the interface. If not,
* then deoptimize so that the interpreter can throw an {@link IllegalAccessError}.
*
* This is a check not performed by the verifier and so must be performed at runtime.
*
* @param args arguments to an {@link Bytecodes#INVOKESPECIAL} implementing a direct call to a
* method in a super class
*/
protected void emitCheckForInvokeSuperSpecial(ValueNode[] args) {
ResolvedJavaType callingClass = method.getDeclaringClass();
if (callingClass.getHostClass() != null) {
callingClass = callingClass.getHostClass();
}
if (callingClass.isInterface()) {
ValueNode receiver = args[0];
TypeReference checkedType = TypeReference.createTrusted(graph.getAssumptions(), callingClass);
LogicNode condition = genUnique(createInstanceOf(checkedType, receiver, null));
FixedGuardNode fixedGuard = append(new FixedGuardNode(condition, ClassCastException, None, false));
args[0] = append(PiNode.create(receiver, StampFactory.object(checkedType, true), fixedGuard));
}
}
protected JavaTypeProfile getProfileForInvoke(InvokeKind invokeKind) {
if (invokeKind.isIndirect() && profilingInfo != null && this.optimisticOpts.useTypeCheckHints(getOptions())) {
return profilingInfo.getTypeProfile(bci());
}
return null;
}
/**
* A partial intrinsic exits by (effectively) calling the intrinsified method. This call must
* use exactly the arguments to the call being intrinsified.
*
* @param originalArgs arguments of original call to intrinsified method
* @param recursiveArgs arguments of recursive call to intrinsified method
*/
private static boolean checkPartialIntrinsicExit(ValueNode[] originalArgs, ValueNode[] recursiveArgs) {
if (originalArgs != null) {
for (int i = 0; i < originalArgs.length; i++) {
ValueNode arg = GraphUtil.unproxify(recursiveArgs[i]);
ValueNode icArg = GraphUtil.unproxify(originalArgs[i]);
assert arg == icArg : String.format("argument %d of call denoting partial intrinsic exit should be %s, not %s", i, icArg, arg);
}
} else {
for (int i = 0; i < recursiveArgs.length; i++) {
ValueNode arg = GraphUtil.unproxify(recursiveArgs[i]);
assert arg instanceof ParameterNode && ((ParameterNode) arg).index() == i : String.format("argument %d of call denoting partial intrinsic exit should be a %s with index %d, not %s",
i, ParameterNode.class.getSimpleName(), i, arg);
}
}
return true;
}
protected Invoke createNonInlinedInvoke(ExceptionEdgeAction exceptionEdge, int invokeBci, ValueNode[] invokeArgs, ResolvedJavaMethod targetMethod,
InvokeKind invokeKind, JavaKind resultType, JavaType returnType, JavaTypeProfile profile) {
StampPair returnStamp = graphBuilderConfig.getPlugins().getOverridingStamp(this, returnType, false);
if (returnStamp == null) {
returnStamp = StampFactory.forDeclaredType(graph.getAssumptions(), returnType, false);
}
MethodCallTargetNode callTarget = graph.add(createMethodCallTarget(invokeKind, targetMethod, invokeArgs, returnStamp, profile));
Invoke invoke = createNonInlinedInvoke(exceptionEdge, invokeBci, callTarget, resultType);
for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) {
plugin.notifyNotInlined(this, targetMethod, invoke);
}
return invoke;
}
protected Invoke createNonInlinedInvoke(ExceptionEdgeAction exceptionEdge, int invokeBci, CallTargetNode callTarget, JavaKind resultType) {
if (exceptionEdge == ExceptionEdgeAction.OMIT) {
return createInvoke(invokeBci, callTarget, resultType);
} else {
Invoke invoke = createInvokeWithException(invokeBci, callTarget, resultType, exceptionEdge);
AbstractBeginNode beginNode = graph.add(KillingBeginNode.create(LocationIdentity.any()));
invoke.setNext(beginNode);
lastInstr = beginNode;
return invoke;
}
}
/**
* Describes what should be done with the exception edge of an invocation. The edge can be
* omitted or included. An included edge can handle the exception or transfer execution to the
* interpreter for handling (deoptimize).
*/
protected enum ExceptionEdgeAction {
OMIT,
INCLUDE_AND_HANDLE,
INCLUDE_AND_DEOPTIMIZE
}
protected ExceptionEdgeAction getActionForInvokeExceptionEdge(InlineInfo lastInlineInfo) {
if (lastInlineInfo == InlineInfo.DO_NOT_INLINE_WITH_EXCEPTION) {
return ExceptionEdgeAction.INCLUDE_AND_HANDLE;
} else if (lastInlineInfo == InlineInfo.DO_NOT_INLINE_NO_EXCEPTION) {
return ExceptionEdgeAction.OMIT;
} else if (lastInlineInfo == InlineInfo.DO_NOT_INLINE_DEOPTIMIZE_ON_EXCEPTION) {
return ExceptionEdgeAction.INCLUDE_AND_DEOPTIMIZE;
} else if (graphBuilderConfig.getBytecodeExceptionMode() == BytecodeExceptionMode.CheckAll) {
return ExceptionEdgeAction.INCLUDE_AND_HANDLE;
} else if (graphBuilderConfig.getBytecodeExceptionMode() == BytecodeExceptionMode.ExplicitOnly) {
return ExceptionEdgeAction.INCLUDE_AND_HANDLE;
} else if (graphBuilderConfig.getBytecodeExceptionMode() == BytecodeExceptionMode.OmitAll) {
return ExceptionEdgeAction.OMIT;
} else {
assert graphBuilderConfig.getBytecodeExceptionMode() == BytecodeExceptionMode.Profile;
// be conservative if information was not recorded (could result in endless
// recompiles otherwise)
if (!StressInvokeWithExceptionNode.getValue(options)) {
if (optimisticOpts.useExceptionProbability(getOptions())) {
if (profilingInfo != null) {
TriState exceptionSeen = profilingInfo.getExceptionSeen(bci());
if (exceptionSeen == TriState.FALSE) {
return ExceptionEdgeAction.OMIT;
}
}
}
}
return ExceptionEdgeAction.INCLUDE_AND_HANDLE;
}
}
/**
* 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 JavaKind resultType;
final int beforeStackSize;
final boolean needsNullCheck;
final int nodeCount;
final Mark mark;
InvocationPluginAssertions(InvocationPlugin plugin, ValueNode[] args, ResolvedJavaMethod targetMethod, JavaKind resultType) {
guarantee(Assertions.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].getStackKind() == JavaKind.Object && !StampTool.isPointerNonNull(args[0].stamp(NodeView.DEFAULT));
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(NodeView.DEFAULT)) : 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;
}
}
protected static class IntrinsicGuard {
final FixedWithNextNode lastInstr;
final Mark mark;
final AbstractBeginNode nonIntrinsicBranch;
final ValueNode receiver;
final JavaTypeProfile profile;
public IntrinsicGuard(FixedWithNextNode lastInstr, ValueNode receiver, Mark mark, AbstractBeginNode nonIntrinsicBranch, JavaTypeProfile profile) {
this.lastInstr = lastInstr;
this.receiver = receiver;
this.mark = mark;
this.nonIntrinsicBranch = nonIntrinsicBranch;
this.profile = profile;
}
}
/**
* Weaves a test of the receiver type to ensure the dispatch will select {@code targetMethod}
* and not another method that overrides it. This should only be called if there is an intrinsic
* (i.e., an {@link InvocationPlugin}) for {@code targetMethod} and the invocation is indirect.
*
* The control flow woven around the intrinsic is as follows:
*
* <pre>
* if (LoadMethod(LoadHub(receiver)) == targetMethod) {
* <intrinsic for targetMethod>
* } else {
* <virtual call to targetMethod>
* }
* </pre>
*
* The {@code else} branch is woven by {@link #afterInvocationPluginExecution}.
*
* @return {@code null} if the intrinsic cannot be used otherwise an object to be used by
* {@link #afterInvocationPluginExecution} to weave code for the non-intrinsic branch
*/
protected IntrinsicGuard guardIntrinsic(ValueNode[] args, ResolvedJavaMethod targetMethod, InvocationPluginReceiver pluginReceiver) {
ValueNode intrinsicReceiver = args[0];
ResolvedJavaType receiverType = StampTool.typeOrNull(intrinsicReceiver);
if (receiverType == null) {
// The verifier guarantees it to be at least type declaring targetMethod
receiverType = targetMethod.getDeclaringClass();
}
ResolvedJavaMethod resolvedMethod = receiverType.resolveMethod(targetMethod, method.getDeclaringClass());
if (resolvedMethod == null || resolvedMethod.equals(targetMethod)) {
assert resolvedMethod == null || targetMethod.getDeclaringClass().isAssignableFrom(resolvedMethod.getDeclaringClass());
Mark mark = graph.getMark();
FixedWithNextNode currentLastInstr = lastInstr;
ValueNode nonNullReceiver = pluginReceiver.get();
Stamp methodStamp = stampProvider.createMethodStamp();
LoadHubNode hub = graph.unique(new LoadHubNode(stampProvider, nonNullReceiver));
LoadMethodNode actual = append(new LoadMethodNode(methodStamp, targetMethod, receiverType, method.getDeclaringClass(), hub));
ConstantNode expected = graph.unique(ConstantNode.forConstant(methodStamp, targetMethod.getEncoding(), getMetaAccess()));
LogicNode compare = graph.addOrUniqueWithInputs(CompareNode.createCompareNode(constantReflection, metaAccess, options, null, Condition.EQ, actual, expected, NodeView.DEFAULT));
JavaTypeProfile profile = null;
if (profilingInfo != null && this.optimisticOpts.useTypeCheckHints(getOptions())) {
profile = profilingInfo.getTypeProfile(bci());
if (profile != null) {
JavaTypeProfile newProfile = adjustProfileForInvocationPlugin(profile, targetMethod);
if (newProfile != profile) {
if (newProfile.getTypes().length == 0) {
// All profiled types select the intrinsic so
// emit a fixed guard instead of an if-then-else.
lastInstr = append(new FixedGuardNode(compare, TypeCheckedInliningViolated, InvalidateReprofile, false));
return new IntrinsicGuard(currentLastInstr, intrinsicReceiver, mark, null, null);
}
} else {
// No profiled types select the intrinsic so emit a virtual call
return null;
}
profile = newProfile;
}
}
AbstractBeginNode intrinsicBranch = graph.add(new BeginNode());
AbstractBeginNode nonIntrinsicBranch = graph.add(new BeginNode());
append(new IfNode(compare, intrinsicBranch, nonIntrinsicBranch, FAST_PATH_PROBABILITY));
lastInstr = intrinsicBranch;
return new IntrinsicGuard(currentLastInstr, intrinsicReceiver, mark, nonIntrinsicBranch, profile);
} else {
// Receiver selects an overriding method so emit a virtual call
return null;
}
}
/**
* Adjusts the profile for an indirect invocation of a virtual method for which there is an
* intrinsic. The adjustment made by this method is to remove all types from the profile that do
* not override {@code targetMethod}.
*
* @param profile the profile to adjust
* @param targetMethod the virtual method for which there is an intrinsic
* @return the adjusted profile or the original {@code profile} object if no adjustment was made
*/
protected JavaTypeProfile adjustProfileForInvocationPlugin(JavaTypeProfile profile, ResolvedJavaMethod targetMethod) {
if (profile.getTypes().length > 0) {
List<ProfiledType> retained = new ArrayList<>();
double notRecordedProbability = profile.getNotRecordedProbability();
for (ProfiledType ptype : profile.getTypes()) {
if (!ptype.getType().resolveMethod(targetMethod, method.getDeclaringClass()).equals(targetMethod)) {
retained.add(ptype);
} else {
notRecordedProbability += ptype.getProbability();
}
}
if (!retained.isEmpty()) {
if (retained.size() != profile.getTypes().length) {
return new JavaTypeProfile(profile.getNullSeen(), notRecordedProbability, retained.toArray(new ProfiledType[retained.size()]));
}
} else {
return new JavaTypeProfile(profile.getNullSeen(), notRecordedProbability, new ProfiledType[0]);
}
}
return profile;
}
/**
* Performs any action required after execution of an invocation plugin. This includes
* {@linkplain InvocationPluginAssertions#check checking} invocation plugin invariants as well
* as weaving the {@code else} branch of the code woven by {@link #guardIntrinsic} if
* {@code guard != null}.
*/
protected void afterInvocationPluginExecution(boolean pluginHandledInvoke, InvocationPluginAssertions assertions, IntrinsicGuard intrinsicGuard,
InvokeKind invokeKind, ValueNode[] args, ResolvedJavaMethod targetMethod, JavaKind resultType, JavaType returnType) {
assert assertions.check(pluginHandledInvoke);
if (intrinsicGuard != null) {
if (pluginHandledInvoke) {
if (intrinsicGuard.nonIntrinsicBranch != null) {
// Intrinsic emitted: emit a virtual call to the target method and
// merge it with the intrinsic branch
EndNode intrinsicEnd = append(new EndNode());
FrameStateBuilder intrinsicState = null;
FrameStateBuilder nonIntrinisicState = null;
if (resultType != JavaKind.Void) {
intrinsicState = frameState.copy();
frameState.pop(resultType);
nonIntrinisicState = frameState;
}
lastInstr = intrinsicGuard.nonIntrinsicBranch;
createNonInlinedInvoke(getActionForInvokeExceptionEdge(null), bci(), args, targetMethod, invokeKind, resultType, returnType, intrinsicGuard.profile);
EndNode nonIntrinsicEnd = append(new EndNode());
AbstractMergeNode mergeNode = graph.add(new MergeNode());
mergeNode.addForwardEnd(intrinsicEnd);
if (intrinsicState != null) {
intrinsicState.merge(mergeNode, nonIntrinisicState);
frameState = intrinsicState;
}
mergeNode.addForwardEnd(nonIntrinsicEnd);
mergeNode.setStateAfter(frameState.create(stream.nextBCI(), mergeNode));
lastInstr = mergeNode;
}
} else {
// Intrinsic was not applied: remove intrinsic guard
// and restore the original receiver node in the arguments array
intrinsicGuard.lastInstr.setNext(null);
GraphUtil.removeNewNodes(graph, intrinsicGuard.mark);
lastInstr = intrinsicGuard.lastInstr;
args[0] = intrinsicGuard.receiver;
}
}
}
protected boolean tryInvocationPlugin(InvokeKind invokeKind, ValueNode[] args, ResolvedJavaMethod targetMethod, JavaKind resultType, JavaType returnType) {
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;
}
InvocationPluginReceiver pluginReceiver = invocationPluginReceiver.init(targetMethod, args);
IntrinsicGuard intrinsicGuard = null;
if (invokeKind.isIndirect()) {
intrinsicGuard = guardIntrinsic(args, targetMethod, pluginReceiver);
if (intrinsicGuard == null) {
return false;
} else if (intrinsicGuard.nonIntrinsicBranch == null) {
assert lastInstr instanceof FixedGuardNode;
}
}
InvocationPluginAssertions assertions = Assertions.assertionsEnabled() ? new InvocationPluginAssertions(plugin, args, targetMethod, resultType) : null;
if (plugin.execute(this, targetMethod, pluginReceiver, args)) {
afterInvocationPluginExecution(true, assertions, intrinsicGuard, invokeKind, args, targetMethod, resultType, returnType);
return true;
} else {
afterInvocationPluginExecution(false, assertions, intrinsicGuard, invokeKind, args, targetMethod, resultType, returnType);
}
}
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 static final InlineInfo SUCCESSFULLY_INLINED = InlineInfo.createStandardInlineInfo(null);
/**
* Try to inline a method. If the method was inlined, returns {@link #SUCCESSFULLY_INLINED}.
* Otherwise, it returns the {@link InlineInfo} that lead to the decision to not inline it, or
* {@code null} if there is no {@link InlineInfo} for this method.
*/
private InlineInfo tryInline(ValueNode[] args, ResolvedJavaMethod targetMethod) {
boolean canBeInlined = forceInliningEverything || parsingIntrinsic() || targetMethod.canBeInlined();
if (!canBeInlined) {
return null;
}
if (forceInliningEverything) {
if (inline(targetMethod, targetMethod, null, args)) {
return SUCCESSFULLY_INLINED;
} else {
return null;
}
}
for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) {
InlineInfo inlineInfo = plugin.shouldInlineInvoke(this, targetMethod, args);
if (inlineInfo != null) {
if (inlineInfo.getMethodToInline() != null) {
if (inline(targetMethod, inlineInfo.getMethodToInline(), inlineInfo.getIntrinsicBytecodeProvider(), args)) {
return SUCCESSFULLY_INLINED;
}
inlineInfo = null;
}
/* Do not inline, and do not ask the remaining plugins. */
return inlineInfo;
}
}
// There was no inline plugin with a definite answer to whether or not
// to inline. If we're parsing an intrinsic, then we need to enforce the
// invariant here that methods are always force inlined in intrinsics/snippets.
if (parsingIntrinsic()) {
if (inline(targetMethod, targetMethod, this.bytecodeProvider, args)) {
return SUCCESSFULLY_INLINED;
}
}
return null;
}
private static final int ACCESSOR_BYTECODE_LENGTH = 5;
/**
* Tries to inline {@code targetMethod} if it is an instance field accessor. This avoids the
* overhead of creating and using a nested {@link BytecodeParser} object.
*/
private boolean tryFastInlineAccessor(ValueNode[] args, ResolvedJavaMethod targetMethod) {
byte[] bytecode = targetMethod.getCode();
if (bytecode != null && bytecode.length == ACCESSOR_BYTECODE_LENGTH &&
Bytes.beU1(bytecode, 0) == ALOAD_0 &&
Bytes.beU1(bytecode, 1) == GETFIELD) {
int b4 = Bytes.beU1(bytecode, 4);
if (b4 >= IRETURN && b4 <= ARETURN) {
int cpi = Bytes.beU2(bytecode, 2);
JavaField field = targetMethod.getConstantPool().lookupField(cpi, targetMethod, GETFIELD);
if (field instanceof ResolvedJavaField) {
ValueNode receiver = invocationPluginReceiver.init(targetMethod, args).get();
ResolvedJavaField resolvedField = (ResolvedJavaField) field;
genGetField(resolvedField, receiver);
notifyBeforeInline(targetMethod);
printInlining(targetMethod, targetMethod, true, "inline accessor method (bytecode parsing)");
notifyAfterInline(targetMethod);
return true;
}
}
}
return false;
}
@Override
public boolean intrinsify(BytecodeProvider intrinsicBytecodeProvider, ResolvedJavaMethod targetMethod, ResolvedJavaMethod substitute, InvocationPlugin.Receiver receiver, ValueNode[] args) {
if (receiver != null) {
receiver.get();
}
boolean res = inline(targetMethod, substitute, intrinsicBytecodeProvider, args);
assert res : "failed to inline " + substitute;
return res;
}
private boolean inline(ResolvedJavaMethod targetMethod, ResolvedJavaMethod inlinedMethod, BytecodeProvider intrinsicBytecodeProvider, ValueNode[] args) {
IntrinsicContext intrinsic = this.intrinsicContext;
if (intrinsic == null && !graphBuilderConfig.insertFullInfopoints() &&
targetMethod.equals(inlinedMethod) &&
(targetMethod.getModifiers() & (STATIC | SYNCHRONIZED)) == 0 &&
tryFastInlineAccessor(args, targetMethod)) {
return true;
}
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));
printInlining(targetMethod, inlinedMethod, true, "compilation root (bytecode parsing)");
return true;
} else {
if (intrinsic.getOriginalMethod().isNative()) {
printInlining(targetMethod, inlinedMethod, false, "native method (bytecode parsing)");
return false;
}
if (canInlinePartialIntrinsicExit() && InlinePartialIntrinsicExitDuringParsing.getValue(options)) {
// Otherwise inline the original method. Any frame state created
// during the inlining will exclude frame(s) in the
// intrinsic method (see FrameStateBuilder.create(int bci)).
notifyBeforeInline(inlinedMethod);
printInlining(targetMethod, inlinedMethod, true, "partial intrinsic exit (bytecode parsing)");
parseAndInlineCallee(intrinsic.getOriginalMethod(), args, null);
notifyAfterInline(inlinedMethod);
return true;
} else {
printInlining(targetMethod, inlinedMethod, false, "partial intrinsic exit (bytecode parsing)");
return false;
}
}
} else {
boolean isIntrinsic = intrinsicBytecodeProvider != null;
if (intrinsic == null && isIntrinsic) {
assert !inlinedMethod.equals(targetMethod);
intrinsic = new IntrinsicContext(targetMethod, inlinedMethod, intrinsicBytecodeProvider, INLINE_DURING_PARSING);
}
if (inlinedMethod.hasBytecodes()) {
notifyBeforeInline(inlinedMethod);
printInlining(targetMethod, inlinedMethod, true, "inline method (bytecode parsing)");
parseAndInlineCallee(inlinedMethod, args, intrinsic);
notifyAfterInline(inlinedMethod);
} else {
printInlining(targetMethod, inlinedMethod, false, "no bytecodes (abstract or native) (bytecode parsing)");
return false;
}
}
return true;
}
protected void notifyBeforeInline(ResolvedJavaMethod inlinedMethod) {
for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) {
plugin.notifyBeforeInline(inlinedMethod);
}
}
protected void notifyAfterInline(ResolvedJavaMethod inlinedMethod) {
for (InlineInvokePlugin plugin : graphBuilderConfig.getPlugins().getInlineInvokePlugins()) {
plugin.notifyAfterInline(inlinedMethod);
}
}
/**
* Determines if a partial intrinsic exit (i.e., a call to the original method within an
* intrinsic) can be inlined.
*/
protected boolean canInlinePartialIntrinsicExit() {
return true;
}
private void printInlining(ResolvedJavaMethod targetMethod, ResolvedJavaMethod inlinedMethod, boolean success, String msg) {
if (success) {
if (TraceInlineDuringParsing.getValue(options) || TraceParserPlugins.getValue(options)) {
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)"));
}
}
}
if (HotSpotPrintInlining.getValue(options)) {
if (targetMethod.equals(inlinedMethod)) {
Util.printInlining(inlinedMethod, bci(), getDepth(), success, "%s", msg);
} else {
Util.printInlining(inlinedMethod, bci(), getDepth(), success, "%s intrinsic for %s", msg, targetMethod.format("%h.%n(%p)"));
}
}
}
/**
* 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 = code.asStackTraceElement(bci());
String s = format("%s%s (%s:%d) %s", nSpaces(getDepth()), method.isConstructor() ? method.format("%h.%n") : method.getName(), where.getFileName(), where.getLineNumber(),
format(format, args));
TTY.println(s);
}
protected RuntimeException throwParserError(Throwable e) {
if (e instanceof BytecodeParserError) {
throw (BytecodeParserError) e;
}
BytecodeParser bp = this;
BytecodeParserError res = new BytecodeParserError(e);
while (bp != null) {
res.addContext("parsing " + bp.code.asStackTraceElement(bp.bci()));
bp = bp.parent;
}
throw res;
}
protected 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, parser.code, graph);
if (!targetMethod.isStatic()) {
args[0] = nullCheckedValue(args[0]);
}
startFrameState.initializeFromArgumentsArray(args);
parser.build(this.lastInstr, startFrameState);
if (parser.returnDataList == null) {
/* Callee does not return. */
lastInstr = null;
} else {
ValueNode calleeReturnValue;
MergeNode returnMergeNode = null;
if (s != null) {
s.returnDataList = parser.returnDataList;
}
if (parser.returnDataList.size() == 1) {
/* Callee has a single return, we can continue parsing at that point. */
ReturnToCallerData singleReturnData = parser.returnDataList.get(0);
lastInstr = singleReturnData.beforeReturnNode;
calleeReturnValue = singleReturnData.returnValue;
} else {
assert parser.returnDataList.size() > 1;
/* Callee has multiple returns, we need to insert a control flow merge. */
returnMergeNode = graph.add(new MergeNode());
calleeReturnValue = ValueMergeUtil.mergeValueProducers(returnMergeNode, parser.returnDataList, returnData -> returnData.beforeReturnNode, returnData -> returnData.returnValue);
}
if (calleeReturnValue != null) {
frameState.push(targetMethod.getSignature().getReturnKind().getStackKind(), calleeReturnValue);
}
if (returnMergeNode != null) {
returnMergeNode.setStateAfter(createFrameState(stream.nextBCI(), returnMergeNode));
lastInstr = finishInstruction(returnMergeNode, frameState);
}
}
/*
* Propagate any side effects into the caller when parsing intrinsics.
*/
if (parser.frameState.isAfterSideEffect() && parsingIntrinsic()) {
for (StateSplit sideEffect : parser.frameState.sideEffects()) {
frameState.addSideEffect(sideEffect);
}
}
FixedWithNextNode calleeBeforeUnwindNode = parser.getBeforeUnwindNode();
if (calleeBeforeUnwindNode != null) {
ValueNode calleeUnwindValue = parser.getUnwindValue();
assert calleeUnwindValue != null;
calleeBeforeUnwindNode.setNext(handleException(calleeUnwindValue, bci(), false));
}
}
}
public MethodCallTargetNode createMethodCallTarget(InvokeKind invokeKind, ResolvedJavaMethod targetMethod, ValueNode[] args, StampPair returnStamp, JavaTypeProfile profile) {
return new MethodCallTargetNode(invokeKind, targetMethod, args, returnStamp, profile);
}
protected InvokeNode createInvoke(int invokeBci, CallTargetNode callTarget, JavaKind resultType) {
InvokeNode invoke = append(new InvokeNode(callTarget, invokeBci));
frameState.pushReturn(resultType, invoke);
invoke.setStateAfter(createFrameState(stream.nextBCI(), invoke));
return invoke;
}
protected InvokeWithExceptionNode createInvokeWithException(int invokeBci, CallTargetNode callTarget, JavaKind resultType, ExceptionEdgeAction exceptionEdgeAction) {
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);
}
AbstractBeginNode exceptionEdge = handleException(null, bci(), exceptionEdgeAction == ExceptionEdgeAction.INCLUDE_AND_DEOPTIMIZE);
InvokeWithExceptionNode invoke = append(new InvokeWithExceptionNode(callTarget, exceptionEdge, invokeBci));
frameState.pushReturn(resultType, invoke);
invoke.setStateAfter(createFrameState(stream.nextBCI(), invoke));
return invoke;
}
protected void genReturn(ValueNode returnVal, JavaKind 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;
}
}
}
ValueNode realReturnVal = processReturnValue(returnVal, returnKind);
frameState.setRethrowException(false);
frameState.clearStack();
beforeReturn(realReturnVal, returnKind);
if (parent == null) {
append(new ReturnNode(realReturnVal));
} else {
if (returnDataList == null) {
returnDataList = new ArrayList<>();
}
returnDataList.add(new ReturnToCallerData(realReturnVal, lastInstr));
lastInstr = null;
}
}
private ValueNode processReturnValue(ValueNode value, JavaKind kind) {
JavaKind returnKind = method.getSignature().getReturnKind();
if (kind != returnKind) {
// sub-word integer
assert returnKind.isNumericInteger() && returnKind.getStackKind() == JavaKind.Int;
IntegerStamp stamp = (IntegerStamp) value.stamp(NodeView.DEFAULT);
// the bytecode verifier doesn't check that the value is in the correct range
if (stamp.lowerBound() < returnKind.getMinValue() || returnKind.getMaxValue() < stamp.upperBound()) {
ValueNode narrow = append(genNarrow(value, returnKind.getBitCount()));
if (returnKind.isUnsigned()) {
return append(genZeroExtend(narrow, 32));
} else {
return append(genSignExtend(narrow, 32));
}
}
}
return value;
}
private void beforeReturn(ValueNode x, JavaKind kind) {
if (graph.method() != null && graph.method().isJavaLangObjectInit()) {
/*
* Get the receiver from the initial state since bytecode rewriting could do arbitrary
* things to the state of the locals.
*/
ValueNode receiver = graph.start().stateAfter().localAt(0);
assert receiver != null && receiver.getStackKind() == JavaKind.Object;
if (RegisterFinalizerNode.mayHaveFinalizer(receiver, graph.getAssumptions())) {
append(new RegisterFinalizerNode(receiver));
}
}
genInfoPointNode(InfopointReason.METHOD_END, x);
if (finalBarrierRequired) {
assert originalReceiver != null;
/*
* When compiling an OSR with a final field store, don't bother tracking the original
* receiver since the receiver cannot be EA'ed.
*/
append(new FinalFieldBarrierNode(entryBCI == INVOCATION_ENTRY_BCI ? originalReceiver : null));
}
synchronizedEpilogue(BytecodeFrame.AFTER_BCI, x, kind);
}
protected MonitorEnterNode createMonitorEnterNode(ValueNode x, MonitorIdNode monitorId) {
return new MonitorEnterNode(x, monitorId);
}
protected void genMonitorEnter(ValueNode x, int bci) {
MonitorIdNode monitorId = graph.add(new MonitorIdNode(frameState.lockDepth(true)));
MonitorEnterNode monitorEnter = append(createMonitorEnterNode(x, monitorId));
frameState.pushLock(x, monitorId);
monitorEnter.setStateAfter(createFrameState(bci, monitorEnter));
}
protected void genMonitorExit(ValueNode x, ValueNode escapedReturnValue, int bci) {
if (frameState.lockDepth(false) == 0) {
throw bailout("unbalanced monitors: too many exits");
}
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(lockedObject, 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(JavaKind.Object, nextBciNode);
appendGoto(successor);
}
protected void genRet(int localIndex) {
BciBlock successor = currentBlock.getRetSuccessor();
ValueNode local = frameState.loadLocal(localIndex, JavaKind.Object);
JsrScope scope = currentBlock.getJsrScope();
int retAddress = scope.nextReturnAddress();
ConstantNode returnBciNode = getJsrConstant(retAddress);
LogicNode guard = IntegerEqualsNode.create(constantReflection, metaAccess, options, null, local, returnBciNode, NodeView.DEFAULT);
guard = graph.addOrUniqueWithInputs(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.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) {
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);
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.clearNonLiveLocals(targetBlock, liveness, true);
newState.insertLoopProxies(loopExit, getEntryState(loop));
loopExit.setStateAfter(newState.create(bci, loopExit));
}
lastLoopExit.setNext(target);
return new Target(firstLoopExit, newState);
}
}
return new Target(target, state);
}
private FrameStateBuilder getEntryState(BciBlock block) {
return entryStateArray[block.id];
}
private void setEntryState(BciBlock block, FrameStateBuilder entryState) {
this.entryStateArray[block.id] = entryState;
}
private void setFirstInstruction(BciBlock block, FixedWithNextNode firstInstruction) {
this.firstInstructionArray[block.id] = firstInstruction;
}
private FixedWithNextNode getFirstInstruction(BciBlock block) {
return firstInstructionArray[block.id];
}
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;
if (getFirstInstruction(block) == 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, lastInstr);
lastInstr = null;
} else {
setFirstInstruction(block, graph.add(new BeginNode()));
}
targetNode = getFirstInstruction(block);
Target target = checkLoopExit(targetNode, block, state);
FixedNode result = target.fixed;
FrameStateBuilder currentEntryState = target.state == state ? (canReuseState ? state : state.copy()) : target.state;
setEntryState(block, 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).isCompatibleWith(state)) {
throw bailout("stacks do not match; bytecodes would not verify");
}
if (getFirstInstruction(block) instanceof LoopBeginNode) {
assert (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);
LoopEndNode loopEnd = graph.add(new LoopEndNode(loopBegin));
Target target = checkLoopExit(loopEnd, block, state);
FixedNode result = target.fixed;
getEntryState(block).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() : "must not be backward branch";
assert getFirstInstruction(block).next() == null : "bytecodes already parsed for block";
if (getFirstInstruction(block) instanceof AbstractBeginNode && !(getFirstInstruction(block) 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);
// 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, mergeNode);
}
AbstractMergeNode mergeNode = (AbstractMergeNode) getFirstInstruction(block);
// 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).merge(mergeNode, target.state);
mergeNode.addForwardEnd(newEnd);
debug.log("createTarget %s: merging state, result: %s", block, result);
return result;
}
/**
* 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(getConstantReflection().asJavaClass(target.getDeclaringClass()));
} else {
return state.loadLocal(0, JavaKind.Object);
}
}
@SuppressWarnings("try")
protected void processBlock(BciBlock block) {
// Ignore blocks that have no predecessors by the time their bytecodes are parsed
FixedWithNextNode firstInstruction = getFirstInstruction(block);
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);
setCurrentFrameState(frameState);
currentBlock = block;
if (firstInstruction instanceof AbstractMergeNode) {
setMergeStateAfter(block, firstInstruction);
}
if (block == blockMap.getUnwindBlock()) {
handleUnwindBlock((ExceptionDispatchBlock) block);
} else if (block instanceof ExceptionDispatchBlock) {
createExceptionDispatch((ExceptionDispatchBlock) block);
} else {
frameState.setRethrowException(false);
iterateBytecodesForBlock(block);
}
}
}
private void handleUnwindBlock(ExceptionDispatchBlock block) {
if (parent == null) {
finishPrepare(lastInstr, block.deoptBci);
frameState.setRethrowException(false);
createUnwind();
} else {
ValueNode exception = frameState.pop(JavaKind.Object);
this.unwindValue = exception;
this.beforeUnwindNode = 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;
synchronizedEpilogue(BytecodeFrame.AFTER_EXCEPTION_BCI, null, null);
ValueNode exception = frameState.pop(JavaKind.Object);
append(new UnwindNode(exception));
}
private void synchronizedEpilogue(int bci, ValueNode currentReturnValue, JavaKind currentReturnValueKind) {
if (method.isSynchronized()) {
if (currentReturnValue != null) {
frameState.push(currentReturnValueKind, currentReturnValue);
}
genMonitorExit(methodSynchronizedObject, currentReturnValue, bci);
assert !frameState.rethrowException();
finishPrepare(lastInstr, bci);
}
if (frameState.lockDepth(false) != 0) {
throw bailout("unbalanced monitors: too few exits exiting frame");
}
}
private void createExceptionDispatch(ExceptionDispatchBlock block) {
lastInstr = finishInstruction(lastInstr, frameState);
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);
}
if (catchType instanceof ResolvedJavaType) {
TypeReference checkedCatchType = TypeReference.createTrusted(graph.getAssumptions(), (ResolvedJavaType) catchType);
if (graphBuilderConfig.getSkippedExceptionTypes() != null) {
for (ResolvedJavaType skippedType : graphBuilderConfig.getSkippedExceptionTypes()) {
if (skippedType.isAssignableFrom(checkedCatchType.getType())) {
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.addOrUniqueWithInputs(createInstanceOf(checkedCatchType, exception)), trueSuccessor, nextDispatch, 0));
return;
}
}
}
BciBlock nextBlock = block.getSuccessorCount() == 1 ? blockMap.getUnwindBlock() : block.getSuccessor(1);
ValueNode exception = frameState.stack[0];
/* Anchor for the piNode, which must be before any LoopExit inserted by createTarget. */
BeginNode piNodeAnchor = graph.add(new BeginNode());
ObjectStamp checkedStamp = StampFactory.objectNonNull(checkedCatchType);
PiNode piNode = graph.addWithoutUnique(new PiNode(exception, checkedStamp));
frameState.pop(JavaKind.Object);
frameState.push(JavaKind.Object, piNode);
FixedNode catchSuccessor = createTarget(block.getSuccessor(0), frameState);
frameState.pop(JavaKind.Object);
frameState.push(JavaKind.Object, exception);
FixedNode nextDispatch = createTarget(nextBlock, frameState);
piNodeAnchor.setNext(catchSuccessor);
IfNode ifNode = append(new IfNode(graph.unique(createInstanceOf(checkedCatchType, exception)), piNodeAnchor, nextDispatch, 0.5));
assert ifNode.trueSuccessor() == piNodeAnchor;
piNode.setGuard(ifNode.trueSuccessor());
} else {
handleUnresolvedExceptionType(catchType);
}
}
private void appendGoto(BciBlock successor) {
FixedNode targetInstr = createTarget(successor, frameState, true, true);
if (lastInstr != null && lastInstr != targetInstr) {
lastInstr.setNext(targetInstr);
}
}
@SuppressWarnings("try")
protected void iterateBytecodesForBlock(BciBlock block) {
if (block.isLoopHeader) {
// 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(), stampFromValueForForcedPhis());
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, 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, frameState.copy());
debug.log(" created loop header %s", loopBegin);
} else if (lastInstr instanceof MergeNode) {
/*
* All inputs of non-loop phi nodes are known by now. We can infer the stamp for the
* phi, so that parsing continues with more precise type information.
*/
frameState.inferPhiStamps((AbstractMergeNode) lastInstr);
}
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(debug, block.endBci - bci);
/* Reset line number for new block */
if (graphBuilderConfig.insertFullInfopoints()) {
previousLineNumber = -1;
}
while (bci < endBCI) {
if (graphBuilderConfig.insertFullInfopoints() && !parsingIntrinsic()) {
currentLineNumber = lnt != null ? lnt.getLineNumber(bci) : -1;
if (currentLineNumber != previousLineNumber) {
genInfoPointNode(InfopointReason.BYTECODE_POSITION, 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 JsrNotSupportedBailout("OSR into a JSR scope is not supported");
}
EntryMarkerNode x = append(new EntryMarkerNode());
frameState.insertProxies(value -> graph.unique(new EntryProxyNode(value, x)));
x.setStateAfter(createFrameState(bci, x));
}
try (DebugCloseable context = openNodeContext()) {
processBytecode(bci, opcode);
} catch (BailoutException e) {
// Don't wrap bailouts as parser errors
throw e;
} catch (Throwable e) {
throw throwParserError(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;
}
}
}
}
private DebugCloseable openNodeContext() {
if ((graphBuilderConfig.trackNodeSourcePosition() || debug.isDumpEnabledForMethod()) && !parsingIntrinsic()) {
return graph.withNodeSourcePosition(createBytecodePosition());
}
return null;
}
/* Also a hook for subclasses. */
protected boolean forceLoopPhis() {
return graph.isOSR();
}
/* Hook for subclasses. */
protected boolean stampFromValueForForcedPhis() {
return false;
}
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;
}
/* Also a hook for subclasses. */
protected boolean disableLoopSafepoint() {
return parsingIntrinsic();
}
private LoopBeginNode appendLoopBegin(FixedWithNextNode fixedWithNext) {
EndNode preLoopEnd = graph.add(new EndNode());
LoopBeginNode loopBegin = graph.add(new LoopBeginNode());
if (disableLoopSafepoint()) {
loopBegin.disableSafepoint();
}
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() && graphBuilderConfig.insertFullInfopoints()) {
append(new FullInfopointNode(reason, createFrameState(bci(), null), escapedReturnValue));
}
}
private boolean traceState() {
if (debug.isLogEnabled() && TraceBytecodeParserLevel.getValue(options) >= TRACELEVEL_STATE) {
frameState.traceState();
}
return true;
}
protected void genIf(ValueNode x, Condition cond, ValueNode y) {
assert x.getStackKind() == y.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();
genIf(condition, negate, trueBlock, falseBlock);
}
protected void genIf(LogicNode conditionInput, boolean negateCondition, BciBlock trueBlockInput, BciBlock falseBlockInput) {
BciBlock trueBlock = trueBlockInput;
BciBlock falseBlock = falseBlockInput;
LogicNode condition = conditionInput;
FrameState stateBefore = null;
ProfilingPlugin profilingPlugin = this.graphBuilderConfig.getPlugins().getProfilingPlugin();
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
}
// Remove a logic negation node and fold it into the negate boolean.
boolean negate = negateCondition;
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 = genUnique(condition);
}
// Need to get probability based on current bci.
double probability = branchProbability(condition);
if (negate) {
BciBlock tmpBlock = trueBlock;
trueBlock = falseBlock;
falseBlock = tmpBlock;
probability = 1 - probability;
}
if (isNeverExecutedCode(probability)) {
append(new FixedGuardNode(condition, UnreachedCode, InvalidateReprofile, true));
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
profilingPlugin.profileGoto(this, method, bci(), falseBlock.startBci, stateBefore);
}
appendGoto(falseBlock);
return;
} else if (isNeverExecutedCode(1 - probability)) {
append(new FixedGuardNode(condition, UnreachedCode, InvalidateReprofile, false));
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
profilingPlugin.profileGoto(this, method, bci(), trueBlock.startBci, stateBefore);
}
appendGoto(trueBlock);
return;
}
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
profilingPlugin.profileIf(this, method, bci(), condition, trueBlock.startBci, falseBlock.startBci, stateBefore);
}
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);
postProcessIfNode(ifNode);
append(ifNode);
}
}
/**
* Hook for subclasses to generate custom nodes before an IfNode.
*/
@SuppressWarnings("unused")
protected void postProcessIfNode(ValueNode node) {
}
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, NodeView.DEFAULT);
if (conditionalNode.graph() == null) {
conditionalNode = graph.addOrUniqueWithInputs(conditionalNode);
}
if (genReturn) {
JavaKind returnKind = method.getSignature().getReturnKind().getStackKind();
this.genReturn(conditionalNode, returnKind);
} else {
frameState.push(JavaKind.Int, conditionalNode);
appendGoto(trueBlock.getSuccessor(0));
stream.setBCI(oldBci);
}
}
private LogicNode createLogicNode(Condition cond, ValueNode a, ValueNode b) {
LogicNode condition;
assert !a.getStackKind().isNumericFloat();
if (cond == Condition.EQ || cond == Condition.NE) {
if (a.getStackKind() == JavaKind.Object) {
condition = genObjectEquals(a, b);
} else {
condition = genIntegerEquals(a, b);
}
} else {
assert a.getStackKind() != JavaKind.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;
}
int startBci = nextBlock.startBci;
int targetAtStart = stream.readUByte(startBci);
if (targetAtStart == Bytecodes.GOTO && nextBlock.getPredecessorCount() == 1) {
// This is an empty block. Skip it.
BciBlock successorBlock = nextBlock.successors.get(0);
ProfilingPlugin profilingPlugin = graphBuilderConfig.getPlugins().getProfilingPlugin();
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
profilingPlugin.profileGoto(this, method, bci(), successorBlock.startBci, stateBefore);
}
appendGoto(successorBlock);
assert nextBlock.numNormalSuccessors() == 1;
} else {
ProfilingPlugin profilingPlugin = graphBuilderConfig.getPlugins().getProfilingPlugin();
if (profilingPlugin != null && profilingPlugin.shouldProfile(this, method)) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
profilingPlugin.profileGoto(this, method, bci(), nextBlock.startBci, stateBefore);
}
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;
}
@Override
public StampProvider getStampProvider() {
return stampProvider;
}
@Override
public MetaAccessProvider getMetaAccess() {
return metaAccess;
}
@Override
public void push(JavaKind slotKind, ValueNode value) {
assert value.isAlive();
frameState.push(slotKind, value);
}
@Override
public ConstantReflectionProvider getConstantReflection() {
return constantReflection;
}
@Override
public ConstantFieldProvider getConstantFieldProvider() {
return constantFieldProvider;
}
/**
* Gets the graph being processed by this builder.
*/
@Override
public StructuredGraph getGraph() {
return graph;
}
@Override
public BytecodeParser getParent() {
return parent;
}
@Override
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.code.asStackTraceElement(bp.bci()), bp.bci(), bp.parsingIntrinsic());
fmt.format("%n%s", new BytecodeDisassembler().disassemble(bp.code, bp.bci(), bp.bci() + 10));
bp = bp.parent;
indent += " ";
}
return fmt.toString();
}
@Override
public BailoutException bailout(String string) {
FrameState currentFrameState = createFrameState(bci(), null);
StackTraceElement[] elements = GraphUtil.approxSourceStackTraceElement(currentFrameState);
BailoutException bailout = new PermanentBailoutException(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);
}
@Override
public void setStateAfter(StateSplit sideEffect) {
assert sideEffect.hasSideEffect();
FrameState stateAfter = createFrameState(stream.nextBCI(), sideEffect);
sideEffect.setStateAfter(stateAfter);
}
protected NodeSourcePosition createBytecodePosition() {
return frameState.createBytecodePosition(bci());
}
public void setCurrentFrameState(FrameStateBuilder frameState) {
this.frameState = frameState;
}
protected final BytecodeStream getStream() {
return stream;
}
@Override
public int bci() {
return stream.currentBCI();
}
public void loadLocal(int index, JavaKind kind) {
ValueNode value = frameState.loadLocal(index, kind);
frameState.push(kind, value);
}
public void loadLocalObject(int index) {
ValueNode value = frameState.loadLocal(index, JavaKind.Object);
int nextBCI = stream.nextBCI();
int nextBC = stream.readUByte(nextBCI);
if (nextBCI <= currentBlock.endBci && nextBC == Bytecodes.GETFIELD) {
stream.next();
genGetField(stream.readCPI(), Bytecodes.GETFIELD, value);
} else {
frameState.push(JavaKind.Object, value);
}
}
public void storeLocal(JavaKind 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(JavaKind.Object, appendConstant(getConstantReflection().asJavaClass((ResolvedJavaType) type)));
} else {
handleUnresolvedLoadConstant(type);
}
} else if (con instanceof JavaConstant) {
JavaConstant constant = (JavaConstant) con;
frameState.push(constant.getJavaKind(), appendConstant(constant));
} else {
throw new Error("lookupConstant returned an object of incorrect type");
}
}
private void genLoadIndexed(JavaKind kind) {
ValueNode index = frameState.pop(JavaKind.Int);
ValueNode array = emitExplicitExceptions(frameState.pop(JavaKind.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(JavaKind kind) {
ValueNode value = frameState.pop(kind);
ValueNode index = frameState.pop(JavaKind.Int);
ValueNode array = emitExplicitExceptions(frameState.pop(JavaKind.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(JavaKind 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(JavaKind 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(JavaKind kind) {
ValueNode x = frameState.pop(kind);
frameState.push(kind, append(genNegateOp(x)));
}
private void genShiftOp(JavaKind kind, int opcode) {
ValueNode s = frameState.pop(JavaKind.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(JavaKind 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(JavaKind kind, boolean isUnorderedLess) {
ValueNode y = frameState.pop(kind);
ValueNode x = frameState.pop(kind);
frameState.push(JavaKind.Int, append(genNormalizeCompare(x, y, isUnorderedLess)));
}
private void genFloatConvert(FloatConvert op, JavaKind from, JavaKind to) {
ValueNode input = frameState.pop(from);
frameState.push(to, append(genFloatConvert(op, input)));
}
private void genSignExtend(JavaKind from, JavaKind 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(JavaKind from, JavaKind 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(JavaKind from, JavaKind 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, JavaKind.Int);
ValueNode y = appendConstant(JavaConstant.forInt(delta));
frameState.storeLocal(index, JavaKind.Int, append(genIntegerAdd(x, y)));
}
private void genIfZero(Condition cond) {
ValueNode y = appendConstant(JavaConstant.INT_0);
ValueNode x = frameState.pop(JavaKind.Int);
genIf(x, cond, y);
}
private void genIfNull(Condition cond) {
ValueNode y = appendConstant(JavaConstant.NULL_POINTER);
ValueNode x = frameState.pop(JavaKind.Object);
genIf(x, cond, y);
}
private void genIfSame(JavaKind 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;
}
protected JavaField lookupField(int cpi, int opcode) {
maybeEagerlyResolve(cpi, opcode);
JavaField result = constantPool.lookupField(cpi, method, opcode);
if (graphBuilderConfig.eagerResolving()) {
assert !graphBuilderConfig.unresolvedIsError() || result instanceof ResolvedJavaField : "Not resolved: " + result;
if (result instanceof ResolvedJavaField) {
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.unresolvedIsError() || !(result instanceof JavaType) || (result instanceof ResolvedJavaType) : result;
return result;
}
protected void maybeEagerlyResolve(int cpi, int bytecode) {
if (intrinsicContext != null) {
constantPool.loadReferencedType(cpi, bytecode);
} else if (graphBuilderConfig.eagerResolving()) {
/*
* Since we're potentially triggering class initialization here, we need synchronization
* to mitigate the potential for class initialization related deadlock being caused by
* the compiler (e.g., https://github.com/graalvm/graal-core/pull/232/files#r90788550).
*/
synchronized (BytecodeParser.class) {
constantPool.loadReferencedType(cpi, bytecode);
}
}
}
private JavaTypeProfile getProfileForTypeCheck(TypeReference type) {
if (parsingIntrinsic() || profilingInfo == null || !optimisticOpts.useTypeCheckHints(getOptions()) || type.isExact()) {
return null;
} else {
return profilingInfo.getTypeProfile(bci());
}
}
private void genCheckCast() {
int cpi = getStream().readCPI();
JavaType type = lookupType(cpi, CHECKCAST);
ValueNode object = frameState.pop(JavaKind.Object);
if (!(type instanceof ResolvedJavaType)) {
handleUnresolvedCheckCast(type, object);
return;
}
TypeReference checkedType = TypeReference.createTrusted(graph.getAssumptions(), (ResolvedJavaType) type);
JavaTypeProfile profile = getProfileForTypeCheck(checkedType);
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleCheckCast(this, object, checkedType.getType(), profile)) {
return;
}
}
ValueNode castNode = null;
if (profile != null) {
if (profile.getNullSeen().isFalse()) {
object = nullCheckedValue(object);
ResolvedJavaType singleType = profile.asSingleType();
if (singleType != null && checkedType.getType().isAssignableFrom(singleType)) {
LogicNode typeCheck = append(createInstanceOf(TypeReference.createExactTrusted(singleType), object, profile));
if (typeCheck.isTautology()) {
castNode = object;
} else {
FixedGuardNode fixedGuard = append(new FixedGuardNode(typeCheck, DeoptimizationReason.TypeCheckedInliningViolated, DeoptimizationAction.InvalidateReprofile, false));
castNode = append(PiNode.create(object, StampFactory.objectNonNull(TypeReference.createExactTrusted(singleType)), fixedGuard));
}
}
}
}
boolean nonNull = ((ObjectStamp) object.stamp(NodeView.DEFAULT)).nonNull();
if (castNode == null) {
LogicNode condition = genUnique(createInstanceOfAllowNull(checkedType, object, null));
if (condition.isTautology()) {
castNode = object;
} else {
FixedGuardNode fixedGuard = append(new FixedGuardNode(condition, DeoptimizationReason.ClassCastException, DeoptimizationAction.InvalidateReprofile, false));
castNode = append(PiNode.create(object, StampFactory.object(checkedType, nonNull), fixedGuard));
}
}
frameState.push(JavaKind.Object, castNode);
}
private void genInstanceOf() {
int cpi = getStream().readCPI();
JavaType type = lookupType(cpi, INSTANCEOF);
ValueNode object = frameState.pop(JavaKind.Object);
if (!(type instanceof ResolvedJavaType)) {
handleUnresolvedInstanceOf(type, object);
return;
}
TypeReference resolvedType = TypeReference.createTrusted(graph.getAssumptions(), (ResolvedJavaType) type);
JavaTypeProfile profile = getProfileForTypeCheck(resolvedType);
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleInstanceOf(this, object, resolvedType.getType(), profile)) {
return;
}
}
LogicNode instanceOfNode = null;
if (profile != null) {
if (profile.getNullSeen().isFalse()) {
object = nullCheckedValue(object);
ResolvedJavaType singleType = profile.asSingleType();
if (singleType != null) {
LogicNode typeCheck = append(createInstanceOf(TypeReference.createExactTrusted(singleType), object, profile));
if (!typeCheck.isTautology()) {
append(new FixedGuardNode(typeCheck, DeoptimizationReason.TypeCheckedInliningViolated, DeoptimizationAction.InvalidateReprofile));
}
instanceOfNode = LogicConstantNode.forBoolean(resolvedType.getType().isAssignableFrom(singleType));
}
}
}
if (instanceOfNode == null) {
instanceOfNode = createInstanceOf(resolvedType, object, null);
}
LogicNode logicNode = genUnique(instanceOfNode);
int next = getStream().nextBCI();
int value = getStream().readUByte(next);
if (next <= currentBlock.endBci && (value == Bytecodes.IFEQ || value == Bytecodes.IFNE)) {
getStream().next();
BciBlock firstSucc = currentBlock.getSuccessor(0);
BciBlock secondSucc = currentBlock.getSuccessor(1);
if (firstSucc != secondSucc) {
genIf(instanceOfNode, value != Bytecodes.IFNE, firstSucc, secondSucc);
} else {
appendGoto(firstSucc);
}
} else {
// Most frequent for value is IRETURN, followed by ISTORE.
frameState.push(JavaKind.Int, append(genConditional(logicNode)));
}
}
protected void genNewInstance(int cpi) {
JavaType type = lookupType(cpi, NEW);
genNewInstance(type);
}
void genNewInstance(JavaType type) {
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.InvalidateRecompile, RuntimeConstraint));
return;
}
}
}
ClassInitializationPlugin classInitializationPlugin = graphBuilderConfig.getPlugins().getClassInitializationPlugin();
if (classInitializationPlugin != null && classInitializationPlugin.shouldApply(this, resolvedType)) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
classInitializationPlugin.apply(this, resolvedType, stateBefore);
}
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleNewInstance(this, resolvedType)) {
return;
}
}
frameState.push(JavaKind.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(JavaKind.Int);
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleNewArray(this, elementType, length)) {
return;
}
}
frameState.push(JavaKind.Object, append(createNewArray(elementType, length, true)));
}
private void genNewObjectArray(int cpi) {
JavaType type = lookupType(cpi, ANEWARRAY);
if (!(type instanceof ResolvedJavaType)) {
ValueNode length = frameState.pop(JavaKind.Int);
handleUnresolvedNewObjectArray(type, length);
return;
}
ResolvedJavaType resolvedType = (ResolvedJavaType) type;
ClassInitializationPlugin classInitializationPlugin = this.graphBuilderConfig.getPlugins().getClassInitializationPlugin();
if (classInitializationPlugin != null && classInitializationPlugin.shouldApply(this, resolvedType.getArrayClass())) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
classInitializationPlugin.apply(this, resolvedType.getArrayClass(), stateBefore);
}
ValueNode length = frameState.pop(JavaKind.Int);
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleNewArray(this, resolvedType, length)) {
return;
}
}
frameState.push(JavaKind.Object, append(createNewArray(resolvedType, length, true)));
}
private void genNewMultiArray(int cpi) {
JavaType type = lookupType(cpi, MULTIANEWARRAY);
int rank = getStream().readUByte(bci() + 3);
ValueNode[] dims = new ValueNode[rank];
if (!(type instanceof ResolvedJavaType)) {
for (int i = rank - 1; i >= 0; i--) {
dims[i] = frameState.pop(JavaKind.Int);
}
handleUnresolvedNewMultiArray(type, dims);
return;
}
ResolvedJavaType resolvedType = (ResolvedJavaType) type;
ClassInitializationPlugin classInitializationPlugin = this.graphBuilderConfig.getPlugins().getClassInitializationPlugin();
if (classInitializationPlugin != null && classInitializationPlugin.shouldApply(this, resolvedType)) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
classInitializationPlugin.apply(this, resolvedType, stateBefore);
}
for (int i = rank - 1; i >= 0; i--) {
dims[i] = frameState.pop(JavaKind.Int);
}
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleNewMultiArray(this, resolvedType, dims)) {
return;
}
}
frameState.push(JavaKind.Object, append(createNewMultiArray(resolvedType, dims)));
}
protected void genGetField(int cpi, int opcode) {
genGetField(cpi, opcode, frameState.pop(JavaKind.Object));
}
protected void genGetField(int cpi, int opcode, ValueNode receiverInput) {
JavaField field = lookupField(cpi, opcode);
genGetField(field, receiverInput);
}
private void genGetField(JavaField field, ValueNode receiverInput) {
ValueNode receiver = emitExplicitExceptions(receiverInput);
if (field instanceof ResolvedJavaField) {
ResolvedJavaField resolvedField = (ResolvedJavaField) field;
genGetField(resolvedField, receiver);
} else {
handleUnresolvedLoadField(field, receiver);
}
}
private void genGetField(ResolvedJavaField resolvedField, ValueNode receiver) {
if (!parsingIntrinsic() && GeneratePIC.getValue(getOptions())) {
graph.recordField(resolvedField);
}
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleLoadField(this, receiver, resolvedField)) {
return;
}
}
ValueNode fieldRead = append(genLoadField(receiver, resolvedField));
if (resolvedField.getDeclaringClass().getName().equals("Ljava/lang/ref/Reference;") && resolvedField.getName().equals("referent")) {
LocationIdentity referentIdentity = new FieldLocationIdentity(resolvedField);
append(new MembarNode(0, referentIdentity));
}
JavaKind fieldKind = resolvedField.getJavaKind();
if (resolvedField.isVolatile() && fieldRead instanceof LoadFieldNode) {
StateSplitProxyNode readProxy = append(genVolatileFieldReadProxy(fieldRead));
frameState.push(fieldKind, readProxy);
readProxy.setStateAfter(frameState.create(stream.nextBCI(), readProxy));
} else {
frameState.push(fieldKind, fieldRead);
}
}
/**
* @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 non-null stamp
*/
protected ValueNode emitExplicitExceptions(ValueNode receiver, ValueNode index) {
if (needsExplicitException()) {
ValueNode nonNullReceiver = emitExplicitNullCheck(receiver);
ValueNode length = append(genArrayLength(nonNullReceiver));
emitExplicitBoundsCheck(index, length);
return nonNullReceiver;
}
return receiver;
}
protected ValueNode emitExplicitExceptions(ValueNode receiver) {
if (StampTool.isPointerNonNull(receiver) || !needsExplicitException()) {
return receiver;
} else {
return emitExplicitNullCheck(receiver);
}
}
private boolean needsExplicitException() {
BytecodeExceptionMode exceptionMode = graphBuilderConfig.getBytecodeExceptionMode();
if (exceptionMode == BytecodeExceptionMode.CheckAll || StressExplicitExceptionCode.getValue(options)) {
return true;
} else if (exceptionMode == BytecodeExceptionMode.Profile && profilingInfo != null) {
return profilingInfo.getExceptionSeen(bci()) == TriState.TRUE;
}
return false;
}
protected void genPutField(int cpi, int opcode) {
JavaField field = lookupField(cpi, opcode);
genPutField(field);
}
protected void genPutField(JavaField field) {
genPutField(field, frameState.pop(field.getJavaKind()));
}
private void genPutField(JavaField field, ValueNode value) {
ValueNode receiver = emitExplicitExceptions(frameState.pop(JavaKind.Object));
if (field instanceof ResolvedJavaField) {
ResolvedJavaField resolvedField = (ResolvedJavaField) field;
if (!parsingIntrinsic() && GeneratePIC.getValue(getOptions())) {
graph.recordField(resolvedField);
}
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleStoreField(this, receiver, resolvedField, value)) {
return;
}
}
if (resolvedField.isFinal() && method.isConstructor()) {
finalBarrierRequired = true;
}
genStoreField(receiver, resolvedField, value);
} else {
handleUnresolvedStoreField(field, value, receiver);
}
}
protected void genGetStatic(int cpi, int opcode) {
JavaField field = lookupField(cpi, opcode);
genGetStatic(field);
}
private void genGetStatic(JavaField field) {
ResolvedJavaField resolvedField = resolveStaticFieldAccess(field, null);
if (resolvedField == null) {
return;
}
if (!parsingIntrinsic() && GeneratePIC.getValue(getOptions())) {
graph.recordField(resolvedField);
}
/*
* 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.getJavaKind(), ConstantNode.forBoolean(true, graph));
return;
}
ClassInitializationPlugin classInitializationPlugin = this.graphBuilderConfig.getPlugins().getClassInitializationPlugin();
if (classInitializationPlugin != null && classInitializationPlugin.shouldApply(this, resolvedField.getDeclaringClass())) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
classInitializationPlugin.apply(this, resolvedField.getDeclaringClass(), stateBefore);
}
for (NodePlugin plugin : graphBuilderConfig.getPlugins().getNodePlugins()) {
if (plugin.handleLoadStaticField(this, resolvedField)) {
return;
}
}
frameState.push(field.getJavaKind(), append(genLoadField(null, resolvedField)));
}
private ResolvedJavaField resolveStaticFieldAccess(JavaField field, ValueNode value) {
if (field instanceof ResolvedJavaField) {
ResolvedJavaField resolvedField = (ResolvedJavaField) field;
if (resolvedField.getDeclaringClass().isInitialized()) {
return resolvedField;
}
/*
* Static fields have initialization semantics but may be safely accessed under certain
* conditions while the class is being initialized. Executing in the clinit or init of
* classes which are subtypes of the field holder are sure to be running in a context
* where the access is safe.
*/
if (resolvedField.getDeclaringClass().isAssignableFrom(method.getDeclaringClass())) {
if (method.isClassInitializer() || method.isConstructor()) {
return resolvedField;
}
}
}
if (value == null) {
handleUnresolvedLoadField(field, null);
} else {
handleUnresolvedStoreField(field, value, null);
}
return null;
}
protected void genPutStatic(int cpi, int opcode) {
JavaField field = lookupField(cpi, opcode);
genPutStatic(field);
}
protected void genPutStatic(JavaField field) {
ValueNode value = frameState.pop(field.getJavaKind());
ResolvedJavaField resolvedField = resolveStaticFieldAccess(field, value);
if (resolvedField == null) {
return;
}
if (!parsingIntrinsic() && GeneratePIC.getValue(getOptions())) {
graph.recordField(resolvedField);
}
ClassInitializationPlugin classInitializationPlugin = this.graphBuilderConfig.getPlugins().getClassInitializationPlugin();
if (classInitializationPlugin != null && classInitializationPlugin.shouldApply(this, resolvedField.getDeclaringClass())) {
FrameState stateBefore = frameState.create(bci(), getNonIntrinsicAncestor(), false, null, null);
classInitializationPlugin.apply(this, resolvedField.getDeclaringClass(), stateBefore);
}
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;
SuccessorInfo(int blockSuccessorIndex) {
this.blockIndex = blockSuccessorIndex;
actualIndex = -1;
}
}
private void genSwitch(BytecodeSwitch bs) {
int bci = bci();
ValueNode value = frameState.pop(JavaKind.Int);
int nofCases = bs.numberOfCases();
int nofCasesPlusDefault = nofCases + 1;
double[] keyProbabilities = switchProbability(nofCasesPlusDefault, bci);
EconomicMap<Integer, SuccessorInfo> bciToBlockSuccessorIndex = EconomicMap.create(Equivalence.DEFAULT);
for (int i = 0; i < currentBlock.getSuccessorCount(); i++) {
assert !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[nofCasesPlusDefault];
int deoptSuccessorIndex = -1;
int nextSuccessorIndex = 0;
boolean constantValue = value.isConstant();
for (int i = 0; i < nofCasesPlusDefault; 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.targetAt(i) : bs.defaultTarget();
SuccessorInfo info = bciToBlockSuccessorIndex.get(targetBci);
if (info.actualIndex < 0) {
info.actualIndex = nextSuccessorIndex++;
actualSuccessors.add(currentBlock.getSuccessor(info.blockIndex));
}
keySuccessors[i] = info.actualIndex;
}
}
/*
* When the profile indicates a case is never taken, the above code will cause the case to
* deopt should it be subsequently encountered. However, the case may share code with
* another case that is taken according to the profile.
*
* For example:
* // @formatter:off
* switch (opcode) {
* case GOTO:
* case GOTO_W: {
* // emit goto code
* break;
* }
* }
* // @formatter:on
*
* The profile may indicate the GOTO_W case is never taken, and thus a deoptimization stub
* will be emitted. There might be optimization opportunity if additional branching based
* on opcode is within the case block. Specially, if there is only single case that
* reaches a target, we have better chance cutting out unused branches. Otherwise,
* it might be beneficial routing to the same code instead of deopting.
*
* The following code rewires deoptimization stub to existing resolved branch target if
* the target is connected by more than 1 cases.
*/
if (deoptSuccessorIndex >= 0) {
int[] connectedCases = new int[nextSuccessorIndex];
for (int i = 0; i < nofCasesPlusDefault; i++) {
connectedCases[keySuccessors[i]]++;
}
for (int i = 0; i < nofCasesPlusDefault; i++) {
if (keySuccessors[i] == deoptSuccessorIndex) {
int targetBci = i < nofCases ? bs.targetAt(i) : bs.defaultTarget();
SuccessorInfo info = bciToBlockSuccessorIndex.get(targetBci);
int rewiredIndex = info.actualIndex;
if (rewiredIndex >= 0 && connectedCases[rewiredIndex] > 1) {
keySuccessors[i] = info.actualIndex;
}
}
}
}
genIntegerSwitch(value, actualSuccessors, keys, keyProbabilities, keySuccessors);
}
protected boolean isNeverExecutedCode(double probability) {
return probability == 0 && optimisticOpts.removeNeverExecutedCode(getOptions());
}
private double rawBranchProbability(LogicNode conditionInput) {
if (conditionInput instanceof IntegerEqualsNode) {
// Propagate injected branch probability if any.
IntegerEqualsNode condition = (IntegerEqualsNode) conditionInput;
BranchProbabilityNode injectedProbability = null;
ValueNode other = null;
if (condition.getX() instanceof BranchProbabilityNode) {
injectedProbability = (BranchProbabilityNode) condition.getX();
other = condition.getY();
} else if (condition.getY() instanceof BranchProbabilityNode) {
injectedProbability = (BranchProbabilityNode) condition.getY();
other = condition.getX();
}
if (injectedProbability != null && injectedProbability.getProbability().isConstant() && other != null && other.isConstant()) {
double probabilityValue = injectedProbability.getProbability().asJavaConstant().asDouble();
return other.asJavaConstant().asInt() == 0 ? 1.0 - probabilityValue : probabilityValue;
}
}
if (profilingInfo == null) {
return 0.5;
}
assert assertAtIfBytecode();
return profilingInfo.getBranchTakenProbability(bci());
}
protected double branchProbability(LogicNode conditionInput) {
double probability = rawBranchProbability(conditionInput);
if (probability < 0) {
assert probability == -1 : "invalid probability";
debug.log("missing probability in %s at bci %d", code, bci());
probability = 0.5;
}
if (!optimisticOpts.removeNeverExecutedCode(getOptions())) {
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(JavaKind.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(JavaKind.Int, appendConstant(JavaConstant.forInt(opcode - ICONST_0))); break;
case LCONST_0 : // fall through
case LCONST_1 : frameState.push(JavaKind.Long, appendConstant(JavaConstant.forLong(opcode - LCONST_0))); break;
case FCONST_0 : // fall through
case FCONST_1 : // fall through
case FCONST_2 : frameState.push(JavaKind.Float, appendConstant(JavaConstant.forFloat(opcode - FCONST_0))); break;
case DCONST_0 : // fall through
case DCONST_1 : frameState.push(JavaKind.Double, appendConstant(JavaConstant.forDouble(opcode - DCONST_0))); break;
case BIPUSH : frameState.push(JavaKind.Int, appendConstant(JavaConstant.forInt(stream.readByte()))); break;
case SIPUSH : frameState.push(JavaKind.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(), JavaKind.Int); break;
case LLOAD : loadLocal(stream.readLocalIndex(), JavaKind.Long); break;
case FLOAD : loadLocal(stream.readLocalIndex(), JavaKind.Float); break;
case DLOAD : loadLocal(stream.readLocalIndex(), JavaKind.Double); break;
case ALOAD : loadLocalObject(stream.readLocalIndex()); break;
case ILOAD_0 : // fall through
case ILOAD_1 : // fall through
case ILOAD_2 : // fall through
case ILOAD_3 : loadLocal(opcode - ILOAD_0, JavaKind.Int); break;
case LLOAD_0 : // fall through
case LLOAD_1 : // fall through
case LLOAD_2 : // fall through
case LLOAD_3 : loadLocal(opcode - LLOAD_0, JavaKind.Long); break;
case FLOAD_0 : // fall through
case FLOAD_1 : // fall through
case FLOAD_2 : // fall through
case FLOAD_3 : loadLocal(opcode - FLOAD_0, JavaKind.Float); break;
case DLOAD_0 : // fall through
case DLOAD_1 : // fall through
case DLOAD_2 : // fall through
case DLOAD_3 : loadLocal(opcode - DLOAD_0, JavaKind.Double); break;
case ALOAD_0 : // fall through
case ALOAD_1 : // fall through
case ALOAD_2 : // fall through
case ALOAD_3 : loadLocalObject(opcode - ALOAD_0); break;
case IALOAD : genLoadIndexed(JavaKind.Int ); break;
case LALOAD : genLoadIndexed(JavaKind.Long ); break;
case FALOAD : genLoadIndexed(JavaKind.Float ); break;
case DALOAD : genLoadIndexed(JavaKind.Double); break;
case AALOAD : genLoadIndexed(JavaKind.Object); break;
case BALOAD : genLoadIndexed(JavaKind.Byte ); break;
case CALOAD : genLoadIndexed(JavaKind.Char ); break;
case SALOAD : genLoadIndexed(JavaKind.Short ); break;
case ISTORE : storeLocal(JavaKind.Int, stream.readLocalIndex()); break;
case LSTORE : storeLocal(JavaKind.Long, stream.readLocalIndex()); break;
case FSTORE : storeLocal(JavaKind.Float, stream.readLocalIndex()); break;
case DSTORE : storeLocal(JavaKind.Double, stream.readLocalIndex()); break;
case ASTORE : storeLocal(JavaKind.Object, stream.readLocalIndex()); break;
case ISTORE_0 : // fall through
case ISTORE_1 : // fall through
case ISTORE_2 : // fall through
case ISTORE_3 : storeLocal(JavaKind.Int, opcode - ISTORE_0); break;
case LSTORE_0 : // fall through
case LSTORE_1 : // fall through
case LSTORE_2 : // fall through
case LSTORE_3 : storeLocal(JavaKind.Long, opcode - LSTORE_0); break;
case FSTORE_0 : // fall through
case FSTORE_1 : // fall through
case FSTORE_2 : // fall through
case FSTORE_3 : storeLocal(JavaKind.Float, opcode - FSTORE_0); break;
case DSTORE_0 : // fall through
case DSTORE_1 : // fall through
case DSTORE_2 : // fall through
case DSTORE_3 : storeLocal(JavaKind.Double, opcode - DSTORE_0); break;
case ASTORE_0 : // fall through
case ASTORE_1 : // fall through
case ASTORE_2 : // fall through
case ASTORE_3 : storeLocal(JavaKind.Object, opcode - ASTORE_0); break;
case IASTORE : genStoreIndexed(JavaKind.Int ); break;
case LASTORE : genStoreIndexed(JavaKind.Long ); break;
case FASTORE : genStoreIndexed(JavaKind.Float ); break;
case DASTORE : genStoreIndexed(JavaKind.Double); break;
case AASTORE : genStoreIndexed(JavaKind.Object); break;
case BASTORE : genStoreIndexed(JavaKind.Byte ); break;
case CASTORE : genStoreIndexed(JavaKind.Char ); break;
case SASTORE : genStoreIndexed(JavaKind.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(JavaKind.Int, opcode); break;
case IDIV : // fall through
case IREM : genIntegerDivOp(JavaKind.Int, opcode); break;
case LADD : // fall through
case LSUB : // fall through
case LMUL : genArithmeticOp(JavaKind.Long, opcode); break;
case LDIV : // fall through
case LREM : genIntegerDivOp(JavaKind.Long, opcode); break;
case FADD : // fall through
case FSUB : // fall through
case FMUL : // fall through
case FDIV : // fall through
case FREM : genArithmeticOp(JavaKind.Float, opcode); break;
case DADD : // fall through
case DSUB : // fall through
case DMUL : // fall through
case DDIV : // fall through
case DREM : genArithmeticOp(JavaKind.Double, opcode); break;
case INEG : genNegateOp(JavaKind.Int); break;
case LNEG : genNegateOp(JavaKind.Long); break;
case FNEG : genNegateOp(JavaKind.Float); break;
case DNEG : genNegateOp(JavaKind.Double); break;
case ISHL : // fall through
case ISHR : // fall through
case IUSHR : genShiftOp(JavaKind.Int, opcode); break;
case IAND : // fall through
case IOR : // fall through
case IXOR : genLogicOp(JavaKind.Int, opcode); break;
case LSHL : // fall through
case LSHR : // fall through
case LUSHR : genShiftOp(JavaKind.Long, opcode); break;
case LAND : // fall through
case LOR : // fall through
case LXOR : genLogicOp(JavaKind.Long, opcode); break;
case IINC : genIncrement(); break;
case I2F : genFloatConvert(FloatConvert.I2F, JavaKind.Int, JavaKind.Float); break;
case I2D : genFloatConvert(FloatConvert.I2D, JavaKind.Int, JavaKind.Double); break;
case L2F : genFloatConvert(FloatConvert.L2F, JavaKind.Long, JavaKind.Float); break;
case L2D : genFloatConvert(FloatConvert.L2D, JavaKind.Long, JavaKind.Double); break;
case F2I : genFloatConvert(FloatConvert.F2I, JavaKind.Float, JavaKind.Int); break;
case F2L : genFloatConvert(FloatConvert.F2L, JavaKind.Float, JavaKind.Long); break;
case F2D : genFloatConvert(FloatConvert.F2D, JavaKind.Float, JavaKind.Double); break;
case D2I : genFloatConvert(FloatConvert.D2I, JavaKind.Double, JavaKind.Int); break;
case D2L : genFloatConvert(FloatConvert.D2L, JavaKind.Double, JavaKind.Long); break;
case D2F : genFloatConvert(FloatConvert.D2F, JavaKind.Double, JavaKind.Float); break;
case L2I : genNarrow(JavaKind.Long, JavaKind.Int); break;
case I2L : genSignExtend(JavaKind.Int, JavaKind.Long); break;
case I2B : genSignExtend(JavaKind.Byte, JavaKind.Int); break;
case I2S : genSignExtend(JavaKind.Short, JavaKind.Int); break;
case I2C : genZeroExtend(JavaKind.Char, JavaKind.Int); break;
case LCMP : genCompareOp(JavaKind.Long, false); break;
case FCMPL : genCompareOp(JavaKind.Float, true); break;
case FCMPG : genCompareOp(JavaKind.Float, false); break;
case DCMPL : genCompareOp(JavaKind.Double, true); break;
case DCMPG : genCompareOp(JavaKind.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(JavaKind.Int, Condition.EQ); break;
case IF_ICMPNE : genIfSame(JavaKind.Int, Condition.NE); break;
case IF_ICMPLT : genIfSame(JavaKind.Int, Condition.LT); break;
case IF_ICMPGE : genIfSame(JavaKind.Int, Condition.GE); break;
case IF_ICMPGT : genIfSame(JavaKind.Int, Condition.GT); break;
case IF_ICMPLE : genIfSame(JavaKind.Int, Condition.LE); break;
case IF_ACMPEQ : genIfSame(JavaKind.Object, Condition.EQ); break;
case IF_ACMPNE : genIfSame(JavaKind.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(JavaKind.Int), JavaKind.Int); break;
case LRETURN : genReturn(frameState.pop(JavaKind.Long), JavaKind.Long); break;
case FRETURN : genReturn(frameState.pop(JavaKind.Float), JavaKind.Float); break;
case DRETURN : genReturn(frameState.pop(JavaKind.Double), JavaKind.Double); break;
case ARETURN : genReturn(frameState.pop(JavaKind.Object), JavaKind.Object); break;
case RETURN : genReturn(null, JavaKind.Void); break;
case GETSTATIC : cpi = stream.readCPI(); genGetStatic(cpi, opcode); break;
case PUTSTATIC : cpi = stream.readCPI(); genPutStatic(cpi, opcode); break;
case GETFIELD : cpi = stream.readCPI(); genGetField(cpi, opcode); break;
case PUTFIELD : cpi = stream.readCPI(); genPutField(cpi, opcode); break;
case INVOKEVIRTUAL : cpi = stream.readCPI(); genInvokeVirtual(cpi, opcode); break;
case INVOKESPECIAL : cpi = stream.readCPI(); genInvokeSpecial(cpi, opcode); break;
case INVOKESTATIC : cpi = stream.readCPI(); genInvokeStatic(cpi, opcode); break;
case INVOKEINTERFACE: cpi = stream.readCPI(); genInvokeInterface(cpi, opcode); break;
case INVOKEDYNAMIC : cpi = stream.readCPI4(); genInvokeDynamic(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(JavaKind.Object), stream.nextBCI()); break;
case MONITOREXIT : genMonitorExit(frameState.pop(JavaKind.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 PermanentBailoutException("concurrent setting of breakpoint");
default : throw new PermanentBailoutException("Unsupported opcode %d (%s) [bci=%d]", opcode, nameOf(opcode), bci);
}
// @formatter:on
// Checkstyle: resume
}
private void genArrayLength() {
ValueNode array = emitExplicitExceptions(frameState.pop(JavaKind.Object));
frameState.push(JavaKind.Int, append(genArrayLength(array)));
}
@Override
public ResolvedJavaMethod getMethod() {
return method;
}
@Override
public Bytecode getCode() {
return code;
}
public FrameStateBuilder getFrameStateBuilder() {
return frameState;
}
protected boolean traceInstruction(int bci, int opcode, boolean blockStart) {
if (debug.isLogEnabled() && TraceBytecodeParserLevel.getValue(options) >= TRACELEVEL_INSTRUCTIONS) {
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);
}
@Override
public boolean parsingIntrinsic() {
return intrinsicContext != null;
}
@Override
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", "");
}
}