Fixed 'IDEA-127301: NPE in decompiler' - a couple of issues with lambda processing

master
Stiver 11 years ago
parent 7f116b6eb5
commit 55beef6b7e
  1. 13
      src/de/fernflower/main/ClassWriter.java
  2. 25
      src/de/fernflower/main/ClassesProcessor.java
  3. 3
      src/de/fernflower/main/rels/LambdaProcessor.java
  4. 2
      src/de/fernflower/main/rels/MethodProcessorThread.java
  5. 4
      src/de/fernflower/main/rels/NestedClassProcessor.java
  6. 54
      src/de/fernflower/modules/decompiler/ExprProcessor.java
  7. 2
      src/de/fernflower/modules/decompiler/FinallyProcessor.java
  8. 3
      src/de/fernflower/modules/decompiler/SimplifyExprentsHelper.java
  9. 11
      src/de/fernflower/modules/decompiler/exps/InvocationExprent.java
  10. 166
      src/de/fernflower/modules/decompiler/exps/NewExprent.java

@ -112,7 +112,7 @@ public class ClassWriter {
}
public void classLambdaToJava(ClassNode node, BufferedWriter writer, int indent) throws IOException {
public void classLambdaToJava(ClassNode node, BufferedWriter writer, Exprent method_object, int indent) throws IOException {
// get the class node with the content method
ClassNode node_content = node;
@ -136,7 +136,12 @@ public class ClassWriter {
if(node.lambda_information.is_method_reference) {
writer.write(ExprProcessor.getCastTypeName(new VarType(node.lambda_information.content_class_name, false)));
if(!node.lambda_information.is_content_method_static && method_object != null) { // reference to a virtual method
writer.write(method_object.toJava(indent));
} else { // reference to a static method
writer.write(ExprProcessor.getCastTypeName(new VarType(node.lambda_information.content_class_name, false)));
}
writer.write("::");
writer.write(node.lambda_information.content_method_name);
@ -156,7 +161,7 @@ public class ClassWriter {
StringBuilder buff = new StringBuilder("(");
boolean firstpar = true;
int index = 1;
int index = node.lambda_information.is_content_method_static ? 0 : 1;;
int start_index = md_content.params.length - md_lambda.params.length;
@ -604,7 +609,7 @@ public class ClassWriter {
bufstrwriter.write("(");
boolean firstpar = true;
int index = 1;
int index = node_lambda.lambda_information.is_content_method_static ? 0 : 1;;
int start_index = md_content.params.length - md_lambda.params.length;

@ -379,8 +379,8 @@ public class ClassesProcessor {
public LambdaInformation lambda_information;
public ClassNode(String content_class_name, String content_method_name, String content_method_descriptor, String lambda_class_name, String lambda_method_name,
String lambda_method_descriptor, StructClass classStruct) { // lambda class constructor
public ClassNode(String content_class_name, String content_method_name, String content_method_descriptor, int content_method_invokation_type,
String lambda_class_name, String lambda_method_name, String lambda_method_descriptor, StructClass classStruct) { // lambda class constructor
this.type = CLASS_LAMBDA;
this.classStruct = classStruct; // 'parent' class containing the static function
@ -393,19 +393,22 @@ public class ClassesProcessor {
lambda_information.content_class_name = content_class_name;
lambda_information.content_method_name = content_method_name;
lambda_information.content_method_descriptor = content_method_descriptor;
lambda_information.content_method_invokation_type = content_method_invokation_type;
lambda_information.content_method_key = InterpreterUtil.makeUniqueKey(lambda_information.content_method_name, lambda_information.content_method_descriptor);
anonimousClassType = new VarType(lambda_class_name, true);
if(content_class_name != classStruct.qualifiedName) { // method reference. FIXME: class name alone doesn't cover it. Synthetic flag seems to be the only 'reliable' difference.
lambda_information.is_method_reference = true;
lambda_information.is_content_method_static = true; // FIXME: consider argument flag
} else {
StructMethod mt = classStruct.getMethod(content_method_name, content_method_descriptor);
boolean is_method_reference = (content_class_name != classStruct.qualifiedName);
StructMethod mt = null;
lambda_information.is_method_reference = false;
lambda_information.is_content_method_static = ((mt.getAccessFlags() & CodeConstants.ACC_STATIC) != 0);
if(!is_method_reference) { // content method in the same class, check synthetic flag
mt = classStruct.getMethod(content_method_name, content_method_descriptor);
is_method_reference = !((mt.getAccessFlags() & CodeConstants.ACC_SYNTHETIC) != 0 || mt.getAttributes().containsKey("Synthetic")); // if not synthetic -> method reference
}
lambda_information.is_method_reference = is_method_reference;
lambda_information.is_content_method_static = (lambda_information.content_method_invokation_type == CodeConstants.CONSTANT_MethodHandle_REF_invokeStatic); // FIXME: redundant?
}
public ClassNode(int type, StructClass classStruct) {
@ -425,6 +428,9 @@ public class ClassesProcessor {
}
public class LambdaInformation {
public String class_name;
public String method_name;
public String method_descriptor;
@ -432,6 +438,7 @@ public class ClassesProcessor {
public String content_class_name;
public String content_method_name;
public String content_method_descriptor;
public int content_method_invokation_type; // values from CONSTANT_MethodHandle_REF_*
public String content_method_key;

@ -98,7 +98,8 @@ public class LambdaProcessor {
LinkConstant content_method_handle = (LinkConstant)bootstrap_arguments.get(1);
ClassNode node_lambda = clprocessor.new ClassNode(content_method_handle.classname, content_method_handle.elementname, content_method_handle.descriptor,
ClassNode node_lambda = clprocessor.new ClassNode(content_method_handle.classname, content_method_handle.elementname,
content_method_handle.descriptor, content_method_handle.index1,
lambda_class_name, lambda_method_name, lambda_method_descriptor, cl);
node_lambda.simpleName = cl.qualifiedName + "##Lambda_" + invoke_dynamic.index1 + "_" + invoke_dynamic.index2;
node_lambda.enclosingMethod = InterpreterUtil.makeUniqueKey(mt.getName(), mt.getDescriptor());

@ -175,7 +175,7 @@ public class MethodProcessorThread implements Runnable {
ClearStructHelper.clearStatements(root);
ExprProcessor proc = new ExprProcessor();
proc.processStatement(root, cl.getPool());
proc.processStatement(root, cl);
// DotExporter.toDotFile(graph, new File("c:\\Temp\\fern3.dot"), true);
// System.out.println(graph.toString());

@ -56,8 +56,8 @@ public class NestedClassProcessor {
public void processClass(ClassNode root, ClassNode node) {
// hide lambda content methods
if(node.type == ClassNode.CLASS_LAMBDA) {
// hide synthetic lambda content methods
if(node.type == ClassNode.CLASS_LAMBDA && !node.lambda_information.is_method_reference) {
ClassNode node_content = DecompilerContext.getClassprocessor().getMapRootClasses().get(node.classStruct.qualifiedName);
if(node_content != null && node_content.wrapper != null) {
node_content.wrapper.getHideMembers().add(node.lambda_information.content_method_key);

@ -14,22 +14,48 @@
package de.fernflower.modules.decompiler;
import java.util.*;
import java.util.Arrays;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import java.util.Set;
import de.fernflower.code.CodeConstants;
import de.fernflower.code.Instruction;
import de.fernflower.code.InstructionSequence;
import de.fernflower.code.cfg.BasicBlock;
import de.fernflower.main.DecompilerContext;
import de.fernflower.modules.decompiler.exps.*;
import de.fernflower.modules.decompiler.exps.ArrayExprent;
import de.fernflower.modules.decompiler.exps.AssignmentExprent;
import de.fernflower.modules.decompiler.exps.ConstExprent;
import de.fernflower.modules.decompiler.exps.ExitExprent;
import de.fernflower.modules.decompiler.exps.Exprent;
import de.fernflower.modules.decompiler.exps.FieldExprent;
import de.fernflower.modules.decompiler.exps.FunctionExprent;
import de.fernflower.modules.decompiler.exps.IfExprent;
import de.fernflower.modules.decompiler.exps.InvocationExprent;
import de.fernflower.modules.decompiler.exps.MonitorExprent;
import de.fernflower.modules.decompiler.exps.NewExprent;
import de.fernflower.modules.decompiler.exps.SwitchExprent;
import de.fernflower.modules.decompiler.exps.VarExprent;
import de.fernflower.modules.decompiler.sforms.DirectGraph;
import de.fernflower.modules.decompiler.sforms.DirectNode;
import de.fernflower.modules.decompiler.sforms.FlattenStatementsHelper;
import de.fernflower.modules.decompiler.sforms.FlattenStatementsHelper.FinallyPathWrapper;
import de.fernflower.modules.decompiler.stats.*;
import de.fernflower.modules.decompiler.stats.BasicBlockStatement;
import de.fernflower.modules.decompiler.stats.CatchAllStatement;
import de.fernflower.modules.decompiler.stats.CatchStatement;
import de.fernflower.modules.decompiler.stats.RootStatement;
import de.fernflower.modules.decompiler.stats.Statement;
import de.fernflower.modules.decompiler.vars.VarProcessor;
import de.fernflower.struct.StructClass;
import de.fernflower.struct.attr.StructBootstrapMethodsAttribute;
import de.fernflower.struct.attr.StructGeneralAttribute;
import de.fernflower.struct.consts.ConstantPool;
import de.fernflower.struct.consts.LinkConstant;
import de.fernflower.struct.consts.PooledConstant;
import de.fernflower.struct.consts.PrimitiveConstant;
import de.fernflower.struct.gen.MethodDescriptor;
import de.fernflower.struct.gen.VarType;
@ -124,7 +150,7 @@ public class ExprProcessor implements CodeConstants {
private VarProcessor varProcessor = (VarProcessor) DecompilerContext.getProperty(DecompilerContext.CURRENT_VAR_PROCESSOR);
public void processStatement(RootStatement root, ConstantPool pool) {
public void processStatement(RootStatement root, StructClass cl) {
FlattenStatementsHelper flatthelper = new FlattenStatementsHelper();
DirectGraph dgraph = flatthelper.buildDirectGraph(root);
@ -179,7 +205,7 @@ public class ExprProcessor implements CodeConstants {
BasicBlockStatement block = node.block;
if (block != null) {
processBlock(block, data, pool);
processBlock(block, data, cl);
block.setExprents(data.getLstExprents());
}
@ -291,7 +317,10 @@ public class ExprProcessor implements CodeConstants {
}
}
public void processBlock(BasicBlockStatement stat, PrimitiveExprsList data, ConstantPool pool) {
public void processBlock(BasicBlockStatement stat, PrimitiveExprsList data, StructClass cl) {
ConstantPool pool = cl.getPool();
StructBootstrapMethodsAttribute bootstrap = (StructBootstrapMethodsAttribute)cl.getAttributes().getWithKey(StructGeneralAttribute.ATTRIBUTE_BOOTSTRAP_METHODS);
BasicBlock block = stat.getBlock();
@ -516,7 +545,18 @@ public class ExprProcessor implements CodeConstants {
case opc_invokeinterface:
case opc_invokedynamic:
if(instr.opcode != opc_invokedynamic || instr.bytecode_version >= CodeConstants.BYTECODE_JAVA_7) {
InvocationExprent exprinv = new InvocationExprent(instr.opcode, pool.getLinkConstant(instr.getOperand(0)), stack);
LinkConstant invoke_constant = pool.getLinkConstant(instr.getOperand(0));
int dynamic_invokation_type = -1;
if(instr.opcode == opc_invokedynamic && bootstrap != null) {
List<PooledConstant> bootstrap_arguments = bootstrap.getMethodArguments(invoke_constant.index1);
LinkConstant content_method_handle = (LinkConstant)bootstrap_arguments.get(1);
dynamic_invokation_type = content_method_handle.index1;
}
InvocationExprent exprinv = new InvocationExprent(instr.opcode, invoke_constant, stack, dynamic_invokation_type);
if (exprinv.getDescriptor().ret.type == CodeConstants.TYPE_VOID) {
exprlist.add(exprinv);
} else {

@ -206,7 +206,7 @@ public class FinallyProcessor {
}
ExprProcessor proc = new ExprProcessor();
proc.processStatement(root, mt.getClassStruct().getPool());
proc.processStatement(root, mt.getClassStruct());
SSAConstructorSparseEx ssa = new SSAConstructorSparseEx();
ssa.splitVariables(root, mt);

@ -721,6 +721,9 @@ public class SimplifyExprentsHelper {
NewExprent newexp = new NewExprent(new VarType(lambda_class_name, true), null, 0);
newexp.setConstructor(in);
// note: we don't set the instance to null with in.setInstance(null) like it is done for a common constructor invokation
// lambda can also be a reference to a virtual method (e.g. String x; ...(x::toString);)
// in this case instance will hold the corresponding object
return newexp;
}

@ -76,7 +76,7 @@ public class InvocationExprent extends Exprent {
public InvocationExprent() {}
public InvocationExprent(int opcode, LinkConstant cn, ListStack<Exprent> stack) {
public InvocationExprent(int opcode, LinkConstant cn, ListStack<Exprent> stack, int dynamic_invokation_type) {
name = cn.elementname;
classname = cn.classname;
@ -99,6 +99,7 @@ public class InvocationExprent extends Exprent {
classname = "java/lang/Class"; // dummy class name
invoke_dynamic_classsuffix = "##Lambda_" + cn.index1 + "_" + cn.index2;
}
if("<init>".equals(name)) {
@ -114,7 +115,13 @@ public class InvocationExprent extends Exprent {
lstParameters.add(0, stack.pop());
}
if(opcode == CodeConstants.opc_invokestatic || opcode == CodeConstants.opc_invokedynamic) {
if(opcode == CodeConstants.opc_invokedynamic) {
if(dynamic_invokation_type == CodeConstants.CONSTANT_MethodHandle_REF_invokeStatic) {
isStatic = true;
} else {
instance = lstParameters.get(0); // FIXME: remove the first parameter completely from the list. It's the object type for a virtual lambda method.
}
} else if(opcode == CodeConstants.opc_invokestatic) {
isStatic = true;
} else {
instance = stack.pop();

@ -133,6 +133,12 @@ public class NewExprent extends Exprent {
List<Exprent> lst = new ArrayList<Exprent>();
if(newtype.arraydim == 0) {
if(constructor != null) {
Exprent constructor_instance = constructor.getInstance();
if(constructor_instance != null) { // should be true only for a lambda expression with a virtual content method
lst.add(constructor_instance);
}
lst.addAll(constructor.getLstParameters());
}
} else {
@ -165,21 +171,21 @@ public class NewExprent extends Exprent {
public String toJava(int indent) {
StringBuilder buf = new StringBuilder();
if(anonymous) {
if (anonymous) {
ClassNode child = DecompilerContext.getClassprocessor().getMapRootClasses().get(newtype.value);
buf.append("(");
if(!lambda && constructor != null) {
if (!lambda && constructor != null) {
InvocationExprent invsuper = child.superInvocation;
ClassNode newnode = DecompilerContext.getClassprocessor().getMapRootClasses().get(invsuper.getClassname());
List<VarVersionPaar> sigFields = null;
if(newnode != null) { // own class
if(newnode.wrapper != null) {
if (newnode != null) { // own class
if (newnode.wrapper != null) {
sigFields = newnode.wrapper.getMethodWrapper("<init>", invsuper.getStringDescriptor()).signatureFields;
} else {
if(newnode.type == ClassNode.CLASS_MEMBER && (newnode.access & CodeConstants.ACC_STATIC) == 0 &&
@ -191,21 +197,22 @@ public class NewExprent extends Exprent {
}
boolean firstpar = true;
int start = 0, end = invsuper.getLstParameters().size();
if(enumconst) {
start += 2; end -= 1;
}
for(int i=start;i<end;i++) {
if(sigFields == null || sigFields.get(i) == null) {
if(!firstpar) {
int start = 0, end = invsuper.getLstParameters().size();
if (enumconst) {
start += 2;
end -= 1;
}
for(int i = start; i < end; i++) {
if (sigFields == null || sigFields.get(i) == null) {
if (!firstpar) {
buf.append(", ");
}
Exprent param = invsuper.getLstParameters().get(i);
if(param.type == Exprent.EXPRENT_VAR) {
int varindex = ((VarExprent)param).getIndex();
if(varindex > 0 && varindex <= constructor.getLstParameters().size()) {
param = constructor.getLstParameters().get(varindex-1);
if (param.type == Exprent.EXPRENT_VAR) {
int varindex = ((VarExprent) param).getIndex();
if (varindex > 0 && varindex <= constructor.getLstParameters().size()) {
param = constructor.getLstParameters().get(varindex - 1);
}
}
@ -219,63 +226,64 @@ public class NewExprent extends Exprent {
}
if(!enumconst) {
if (!enumconst) {
String enclosing = null;
if(!lambda && constructor != null) {
if (!lambda && constructor != null) {
enclosing = getQualifiedNewInstance(child.anonimousClassType.value, constructor.getLstParameters(), indent);
}
String typename = ExprProcessor.getCastTypeName(child.anonimousClassType);
if(enclosing != null) {
if (enclosing != null) {
ClassNode anonimousNode = DecompilerContext.getClassprocessor().getMapRootClasses().get(child.anonimousClassType.value);
if(anonimousNode != null) {
if (anonimousNode != null) {
typename = anonimousNode.simpleName;
} else {
typename = typename.substring(typename.lastIndexOf('.')+1);
typename = typename.substring(typename.lastIndexOf('.') + 1);
}
}
buf.insert(0, "new "+typename);
buf.insert(0, "new " + typename);
if(enclosing != null) {
buf.insert(0, enclosing+".");
if (enclosing != null) {
buf.insert(0, enclosing + ".");
}
}
buf.append(")");
if(enumconst && buf.length() == 2) {
buf.setLength(0);
}
if (enumconst && buf.length() == 2) {
buf.setLength(0);
}
StringWriter strwriter = new StringWriter();
BufferedWriter bufstrwriter = new BufferedWriter(strwriter);
ClassWriter clwriter = new ClassWriter();
try {
if(lambda) {
clwriter.classLambdaToJava(child, bufstrwriter, indent);
if (lambda) {
clwriter.classLambdaToJava(child, bufstrwriter, (constructor == null ? null : constructor.getInstance()), indent);
} else {
clwriter.classToJava(child, bufstrwriter, indent);
}
bufstrwriter.flush();
} catch(IOException ex) {
} catch (IOException ex) {
throw new RuntimeException(ex);
}
if(lambda && !DecompilerContext.getOption(IFernflowerPreferences.LAMBDA_TO_ANONYMOUS_CLASS)) {
buf.setLength(0); // remove the usual 'new <class>()', it will be replaced with lambda style '() ->'
if (lambda && !DecompilerContext.getOption(IFernflowerPreferences.LAMBDA_TO_ANONYMOUS_CLASS)) {
buf.setLength(0); // remove the usual 'new <class>()', it will
// be replaced with lambda style '() ->'
}
buf.append(strwriter.toString());
} else if(directArrayInit) {
} else if (directArrayInit) {
VarType leftType = newtype.copy();
leftType.decArrayDim();
buf.append("{");
for(int i=0;i<lstArrayElements.size();i++) {
if(i>0) {
for(int i = 0; i < lstArrayElements.size(); i++) {
if (i > 0) {
buf.append(", ");
}
StringBuilder buff = new StringBuilder();
@ -285,90 +293,90 @@ public class NewExprent extends Exprent {
}
buf.append("}");
} else {
if(newtype.arraydim == 0) {
if (newtype.arraydim == 0) {
if(constructor != null) {
if (constructor != null) {
List<Exprent> lstParameters = constructor.getLstParameters();
ClassNode newnode = DecompilerContext.getClassprocessor().getMapRootClasses().get(constructor.getClassname());
List<VarVersionPaar> sigFields = null;
if(newnode != null) { // own class
if(newnode.wrapper != null) {
if (newnode != null) { // own class
if (newnode.wrapper != null) {
sigFields = newnode.wrapper.getMethodWrapper("<init>", constructor.getStringDescriptor()).signatureFields;
} else {
if(newnode.type == ClassNode.CLASS_MEMBER && (newnode.access & CodeConstants.ACC_STATIC) == 0 &&
!constructor.getLstParameters().isEmpty()) { // member non-static class invoked with enclosing class instance
sigFields = new ArrayList<VarVersionPaar>(Collections.nCopies(lstParameters.size(), (VarVersionPaar)null));
if (newnode.type == ClassNode.CLASS_MEMBER && (newnode.access & CodeConstants.ACC_STATIC) == 0 &&
!constructor.getLstParameters().isEmpty()) { // member non-static class invoked with enclosing class instance
sigFields = new ArrayList<VarVersionPaar>(Collections.nCopies(lstParameters.size(), (VarVersionPaar) null));
sigFields.set(0, new VarVersionPaar(-1, 0));
}
}
}
int start = enumconst ? 2 : 0;
if(!enumconst || start < lstParameters.size()) {
buf.append("(");
boolean firstpar = true;
for(int i=start;i<lstParameters.size();i++) {
if(sigFields == null || sigFields.get(i) == null) {
if(!firstpar) {
buf.append(", ");
}
StringBuilder buff = new StringBuilder();
ExprProcessor.getCastedExprent(lstParameters.get(i), constructor.getDescriptor().params[i], buff, indent, true);
buf.append(buff);
firstpar = false;
}
}
buf.append(")");
}
}
if(!enumconst) {
int start = enumconst ? 2 : 0;
if (!enumconst || start < lstParameters.size()) {
buf.append("(");
boolean firstpar = true;
for(int i = start; i < lstParameters.size(); i++) {
if (sigFields == null || sigFields.get(i) == null) {
if (!firstpar) {
buf.append(", ");
}
StringBuilder buff = new StringBuilder();
ExprProcessor.getCastedExprent(lstParameters.get(i), constructor.getDescriptor().params[i], buff, indent, true);
buf.append(buff);
firstpar = false;
}
}
buf.append(")");
}
}
if (!enumconst) {
String enclosing = null;
if(constructor != null) {
if (constructor != null) {
enclosing = getQualifiedNewInstance(newtype.value, constructor.getLstParameters(), indent);
}
String typename = ExprProcessor.getTypeName(newtype);
if(enclosing != null) {
if (enclosing != null) {
ClassNode newNode = DecompilerContext.getClassprocessor().getMapRootClasses().get(newtype.value);
if(newNode != null) {
if (newNode != null) {
typename = newNode.simpleName;
} else {
typename = typename.substring(typename.lastIndexOf('.')+1);
typename = typename.substring(typename.lastIndexOf('.') + 1);
}
}
buf.insert(0, "new "+typename);
buf.insert(0, "new " + typename);
if(enclosing != null) {
buf.insert(0, enclosing+".");
if (enclosing != null) {
buf.insert(0, enclosing + ".");
}
}
} else {
buf.append("new ").append(ExprProcessor.getTypeName(newtype));
if(lstArrayElements.isEmpty()) {
for(int i=0;i<newtype.arraydim;i++) {
if (lstArrayElements.isEmpty()) {
for(int i = 0; i < newtype.arraydim; i++) {
buf.append("[").append(i < lstDims.size() ? lstDims.get(i).toJava(indent) : "").append("]");
}
} else {
for(int i=0;i<newtype.arraydim;i++) {
for(int i = 0; i < newtype.arraydim; i++) {
buf.append("[]");
}
VarType leftType = newtype.copy();
leftType.decArrayDim();
VarType leftType = newtype.copy();
leftType.decArrayDim();
buf.append("{");
for(int i=0;i<lstArrayElements.size();i++) {
if(i>0) {
buf.append("{");
for(int i = 0; i < lstArrayElements.size(); i++) {
if (i > 0) {
buf.append(", ");
}
StringBuilder buff = new StringBuilder();

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