Mercurial > hg > Members > kono > jpf-core
view src/main/gov/nasa/jpf/jvm/bytecode/INVOKEDYNAMIC.java @ 1:f6886b2bda4a
first set of post v7 patches
general part of extendTransition optimization, which skips transition breaks (and hence state matching) if vm.extend_transitions is set, and the next CG has only a single choice that does not require a break (e.g. context switch). This is mainly meant to be a state space optimization, and complements the null return on the CG creator side, which is extension/domain specific and also cuts into observability from listeners (no CG - no CG notifications).
Note this is only the first part of the patch and probably too general in most cases. The second part extends this with an interface that can control breaks dynamically (e.g. from listeners).
Added a ChoiceGenerator.setCurrent() (empty by default) that can be used as a CG type specific hook to expand/modify choices once the CG becomes active
Added the first part of the patch that allows SUT context expansion of EventChoiceGenerators, which is required to make the new event system work in situations that need to add additional events based on the current SUT state (e.g. statemachines with timeout events).
Fix for INVOKEDYNAMIC causing a NPE for recycled/restored function objects (Nastaran's patch)
| author | Peter Mehlitz <Peter.C.Mehlitz@nasa.gov> |
|---|---|
| date | Fri, 23 Jan 2015 11:08:46 -0800 |
| parents | 61d41facf527 |
| children | db918c531e6d |
line wrap: on
line source
/* * Copyright (C) 2014, United States Government, as represented by the * Administrator of the National Aeronautics and Space Administration. * All rights reserved. * * The Java Pathfinder core (jpf-core) platform is licensed under the * Apache License, Version 2.0 (the "License"); you may not use this file except * in compliance with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0. * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package gov.nasa.jpf.jvm.bytecode; import gov.nasa.jpf.vm.BootstrapMethodInfo; import gov.nasa.jpf.vm.ClassInfo; import gov.nasa.jpf.vm.ElementInfo; import gov.nasa.jpf.vm.FunctionObjectFactory; import gov.nasa.jpf.vm.Instruction; import gov.nasa.jpf.vm.LoadOnJPFRequired; import gov.nasa.jpf.vm.MJIEnv; import gov.nasa.jpf.vm.StackFrame; import gov.nasa.jpf.vm.ThreadInfo; import gov.nasa.jpf.vm.Types; import gov.nasa.jpf.vm.VM; /** * @author Nastaran Shafiei <nastaran.shafiei@gmail.com> * * Invoke dynamic method. It allows dynamic linkage between a call site and a method implementation. * * ..., [arg1, [arg2 ...]] => ... */ public class INVOKEDYNAMIC extends Instruction { // index of a bootstrap method (index to the array bootstrapMethods[] declared in ClassInfo // containing this bytecode instruction) int bootstrapMethodIndex; // Free variables are those that are not defined within the lamabda body and // are captured from the lexical scope. Note that for instance lambda methods // the first captured variable always represents "this" String[] freeVariableTypeNames; byte[] freeVariableTypes; String functionalInterfaceName; String samMethodName; int funcObjRef = MJIEnv.NULL; ElementInfo lastFuncObj = null; public INVOKEDYNAMIC () {} protected INVOKEDYNAMIC (int bmIndex, String methodName, String descriptor){ bootstrapMethodIndex = bmIndex; samMethodName = methodName; freeVariableTypeNames = Types.getArgumentTypeNames(descriptor); freeVariableTypes = Types.getArgumentTypes(descriptor); functionalInterfaceName = Types.getReturnTypeSignature(descriptor); } @Override public int getByteCode () { return 0xBA; } @Override public String toString() { String args = ""; for(String type: freeVariableTypeNames) { if(args.length()>0) { type += ','+ type; } args += type; } return "invokedynamic " + bootstrapMethodIndex + " " + samMethodName + '(' + args +"):" + functionalInterfaceName; } /** * For now, INVOKEDYNAMIC works only in the context of lambda expressions. * Executing this returns an object that implements the functional interface * and contains a method which captures the behavior of the lambda expression. */ @Override public Instruction execute (ThreadInfo ti) { StackFrame frame = ti.getModifiableTopFrame(); ElementInfo ei = ti.getHeap().get(funcObjRef); if(ei==null || ei!=lastFuncObj) { ClassInfo fiClassInfo; // First, resolve the functional interface try { fiClassInfo = ti.resolveReferencedClass(functionalInterfaceName); } catch(LoadOnJPFRequired lre) { return ti.getPC(); } if (!fiClassInfo.isRegistered()){ fiClassInfo.registerClass(ti); } if (fiClassInfo.initializeClass(ti)) { return ti.getPC(); } ClassInfo enclosingClass = this.getMethodInfo().getClassInfo(); BootstrapMethodInfo bmi = enclosingClass.getBootstrapMethodInfo(bootstrapMethodIndex); VM vm = VM.getVM(); FunctionObjectFactory funcObjFactory = vm.getFunctionObjectFacotry(); String samUniqueName = samMethodName + bmi.getSamDescriptor(); Object[] freeVariableValues = frame.getArgumentsValues(ti, freeVariableTypes); funcObjRef = funcObjFactory.getFunctionObject(ti, fiClassInfo, samUniqueName, bmi, freeVariableTypeNames, freeVariableValues); lastFuncObj = ti.getHeap().get(funcObjRef); } frame.pop(freeVariableTypes.length); frame.pushRef(funcObjRef); return getNext(ti); } }