/*
* Copyright 2000-2014 JetBrains s.r.o.
*
* 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 org.jetbrains.java.decompiler.main;
import org.jetbrains.java.decompiler.code.CodeConstants;
import org.jetbrains.java.decompiler.main.collectors.BytecodeSourceMapper;
import org.jetbrains.java.decompiler.main.collectors.CounterContainer;
import org.jetbrains.java.decompiler.main.collectors.ImportCollector;
import org.jetbrains.java.decompiler.main.extern.IFernflowerLogger;
import org.jetbrains.java.decompiler.main.extern.IFernflowerPreferences;
import org.jetbrains.java.decompiler.main.extern.IIdentifierRenamer;
import org.jetbrains.java.decompiler.main.rels.ClassWrapper;
import org.jetbrains.java.decompiler.main.rels.LambdaProcessor;
import org.jetbrains.java.decompiler.main.rels.NestedClassProcessor;
import org.jetbrains.java.decompiler.main.rels.NestedMemberAccess;
import org.jetbrains.java.decompiler.modules.decompiler.exps.InvocationExprent;
import org.jetbrains.java.decompiler.modules.decompiler.vars.VarVersionPaar;
import org.jetbrains.java.decompiler.struct.StructClass;
import org.jetbrains.java.decompiler.struct.StructContext;
import org.jetbrains.java.decompiler.struct.StructMethod;
import org.jetbrains.java.decompiler.struct.attr.StructInnerClassesAttribute;
import org.jetbrains.java.decompiler.struct.gen.VarType;
import org.jetbrains.java.decompiler.util.InterpreterUtil;
import java.io.IOException;
import java.util.*;
import java.util.Map.Entry;
public class ClassesProcessor {
public static final int AVERAGE_CLASS_SIZE = 16 * 1024;
private Map<String, ClassNode> mapRootClasses = new HashMap<String, ClassNode>();
public ClassesProcessor(StructContext context) {
HashMap<String, Object[]> mapInnerClasses = new HashMap<String, Object[]>();
HashMap<String, HashSet<String>> mapNestedClassReferences = new HashMap<String, HashSet<String>>();
HashMap<String, HashSet<String>> mapEnclosingClassReferences = new HashMap<String, HashSet<String>>();
HashMap<String, String> mapNewSimpleNames = new HashMap<String, String>();
boolean bDecompileInner = DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_INNER);
// create class nodes
for (StructClass cl : context.getClasses().values()) {
if (cl.isOwn() && !mapRootClasses.containsKey(cl.qualifiedName)) {
if (bDecompileInner) {
StructInnerClassesAttribute inner = (StructInnerClassesAttribute)cl.getAttributes().getWithKey("InnerClasses");
if (inner != null) {
for (int i = 0; i < inner.getClassEntries().size(); i++) {
int[] entry = inner.getClassEntries().get(i);
String[] strentry = inner.getStringEntries().get(i);
Object[] arr = new Object[4]; // arr[0] not used
String innername = strentry[0];
// nested class type
arr[2] = entry[1] == 0 ? (entry[2] == 0 ? ClassNode.CLASS_ANONYMOUS : ClassNode.CLASS_LOCAL) : ClassNode.CLASS_MEMBER;
// original simple name
String simpleName = strentry[2];
String savedName = mapNewSimpleNames.get(innername);
if (savedName != null) {
simpleName = savedName;
}
else if (simpleName != null && DecompilerContext.getOption(IFernflowerPreferences.RENAME_ENTITIES)) {
IIdentifierRenamer renamer = DecompilerContext.getPoolInterceptor().getHelper();
if (renamer.toBeRenamed(IIdentifierRenamer.ELEMENT_CLASS, simpleName, null, null)) {
simpleName = renamer.getNextClassname(innername, simpleName);
mapNewSimpleNames.put(innername, simpleName);
}
}
arr[1] = simpleName;
// original access flags
arr[3] = entry[3];
// enclosing class
String enclClassName;
if (entry[1] != 0) {
enclClassName = strentry[1];
}
else {
enclClassName = cl.qualifiedName;
}
if (!innername.equals(enclClassName)) { // self reference
StructClass enclosing_class = context.getClasses().get(enclClassName);
if (enclosing_class != null && enclosing_class.isOwn()) { // own classes only
Object[] arrold = mapInnerClasses.get(innername);
if (arrold == null) {
mapInnerClasses.put(innername, arr);
}
else if (!InterpreterUtil.equalObjectArrays(arrold, arr)) {
String message = "Inconsistent inner class entries for " + innername + "!";
DecompilerContext.getLogger().writeMessage(message, IFernflowerLogger.Severity.WARN);
}
// reference to the nested class
HashSet<String> set = mapNestedClassReferences.get(enclClassName);
if (set == null) {
mapNestedClassReferences.put(enclClassName, set = new HashSet<String>());
}
set.add(innername);
// reference to the enclosing class
set = mapEnclosingClassReferences.get(innername);
if (set == null) {
mapEnclosingClassReferences.put(innername, set = new HashSet<String>());
}
set.add(enclClassName);
}
}
}
}
}
ClassNode node = new ClassNode(ClassNode.CLASS_ROOT, cl);
node.access = cl.getAccessFlags();
mapRootClasses.put(cl.qualifiedName, node);
}
}
if (bDecompileInner) {
// connect nested classes
for (Entry<String, ClassNode> ent : mapRootClasses.entrySet()) {
// root class?
if (!mapInnerClasses.containsKey(ent.getKey())) {
HashSet<String> setVisited = new HashSet<String>();
LinkedList<String> stack = new LinkedList<String>();
stack.add(ent.getKey());
setVisited.add(ent.getKey());
while (!stack.isEmpty()) {
String superClass = stack.removeFirst();
ClassNode supernode = mapRootClasses.get(superClass);
HashSet<String> setNestedClasses = mapNestedClassReferences.get(superClass);
if (setNestedClasses != null) {
StructClass scl = supernode.classStruct;
StructInnerClassesAttribute inner = (StructInnerClassesAttribute)scl.getAttributes().getWithKey("InnerClasses");
for (int i = 0; i < inner.getStringEntries().size(); i++) {
String nestedClass = inner.getStringEntries().get(i)[0];
if (!setNestedClasses.contains(nestedClass)) {
continue;
}
if (!setVisited.add(nestedClass)) {
continue;
}
ClassNode nestednode = mapRootClasses.get(nestedClass);
if (nestednode == null) {
DecompilerContext.getLogger().writeMessage("Nested class " + nestedClass + " missing!", IFernflowerLogger.Severity.WARN);
continue;
}
Object[] arr = mapInnerClasses.get(nestedClass);
//if ((Integer)arr[2] == ClassNode.CLASS_MEMBER) {
// FIXME: check for consistent naming
//}
nestednode.type = (Integer)arr[2];
nestednode.simpleName = (String)arr[1];
nestednode.access = (Integer)arr[3];
if (nestednode.type == ClassNode.CLASS_ANONYMOUS) {
StructClass cl = nestednode.classStruct;
// remove static if anonymous class
// a common compiler bug
nestednode.access &= ~CodeConstants.ACC_STATIC;
int[] interfaces = cl.getInterfaces();
if (interfaces.length > 0) {
if (interfaces.length > 1) {
String message = "Inconsistent anonymous class definition: " + cl.qualifiedName;
DecompilerContext.getLogger().writeMessage(message, IFernflowerLogger.Severity.WARN);
}
nestednode.anonymousClassType = new VarType(cl.getInterface(0), true);
}
else {
nestednode.anonymousClassType = new VarType(cl.superClass.getString(), true);
}
}
else if (nestednode.type == ClassNode.CLASS_LOCAL) {
// only abstract and final are permitted
// a common compiler bug
nestednode.access &= (CodeConstants.ACC_ABSTRACT | CodeConstants.ACC_FINAL);
}
supernode.nested.add(nestednode);
nestednode.parent = supernode;
nestednode.enclosingClasses.addAll(mapEnclosingClassReferences.get(nestedClass));
stack.add(nestedClass);
}
}
}
}
}
}
}
public void writeClass(StructClass cl, TextBuffer buffer) throws IOException {
ClassNode root = mapRootClasses.get(cl.qualifiedName);
if (root.type != ClassNode.CLASS_ROOT) {
return;
}
DecompilerContext.getLogger().startReadingClass(cl.qualifiedName);
try {
ImportCollector importCollector = new ImportCollector(root);
DecompilerContext.setImportCollector(importCollector);
DecompilerContext.setCounterContainer(new CounterContainer());
DecompilerContext.setBytecodeSourceMapper(new BytecodeSourceMapper());
new LambdaProcessor().processClass(root);
// add simple class names to implicit import
addClassnameToImport(root, importCollector);
// build wrappers for all nested classes (that's where actual processing takes place)
initWrappers(root);
new NestedClassProcessor().processClass(root, root);
new NestedMemberAccess().propagateMemberAccess(root);
TextBuffer classBuffer = new TextBuffer(AVERAGE_CLASS_SIZE);
new ClassWriter().classToJava(root, classBuffer, 0, null);
int total_offset_lines = 0;
int index = cl.qualifiedName.lastIndexOf("/");
if (index >= 0) {
total_offset_lines+=2;
String packageName = cl.qualifiedName.substring(0, index).replace('/', '.');
buffer.append("package ");
buffer.append(packageName);
buffer.append(";");
buffer.appendLineSeparator();
buffer.appendLineSeparator();
}
int import_lines_written = importCollector.writeImports(buffer);
if (import_lines_written > 0) {
buffer.appendLineSeparator();
total_offset_lines += import_lines_written + 1;
}
//buffer.append(lineSeparator);
total_offset_lines = buffer.countLines();
buffer.append(classBuffer);
if (DecompilerContext.getOption(IFernflowerPreferences.BYTECODE_SOURCE_MAPPING)) {
BytecodeSourceMapper mapper = DecompilerContext.getBytecodeSourceMapper();
mapper.addTotalOffset(total_offset_lines);
if (DecompilerContext.getOption(IFernflowerPreferences.DUMP_ORIGINAL_LINES)) {
buffer.dumpOriginalLineNumbers(mapper.getOriginalLinesMapping());
}
if (DecompilerContext.getOption(IFernflowerPreferences.UNIT_TEST_MODE)) {
buffer.appendLineSeparator();
mapper.dumpMapping(buffer, true);
}
}
}
finally {
destroyWrappers(root);
DecompilerContext.getLogger().endReadingClass();
}
}
private static void initWrappers(ClassNode node) throws IOException {
if (node.type == ClassNode.CLASS_LAMBDA) {
return;
}
ClassWrapper wrapper = new ClassWrapper(node.classStruct);
wrapper.init();
node.wrapper = wrapper;
for (ClassNode nd : node.nested) {
initWrappers(nd);
}
}
private static void addClassnameToImport(ClassNode node, ImportCollector imp) {
if (node.simpleName != null && node.simpleName.length() > 0) {
imp.getShortName(node.type == ClassNode.CLASS_ROOT ? node.classStruct.qualifiedName : node.simpleName, false);
}
for (ClassNode nd : node.nested) {
addClassnameToImport(nd, imp);
}
}
private static void destroyWrappers(ClassNode node) {
node.wrapper = null;
node.classStruct.releaseResources();
for (ClassNode nd : node.nested) {
destroyWrappers(nd);
}
}
public Map<String, ClassNode> getMapRootClasses() {
return mapRootClasses;
}
public static class ClassNode {
public static final int CLASS_ROOT = 0;
public static final int CLASS_MEMBER = 1;
public static final int CLASS_ANONYMOUS = 2;
public static final int CLASS_LOCAL = 4;
public static final int CLASS_LAMBDA = 8;
public int type;
public int access;
public String simpleName;
public StructClass classStruct;
public ClassWrapper wrapper;
public String enclosingMethod;
public InvocationExprent superInvocation;
public Map<String, VarVersionPaar> mapFieldsToVars = new HashMap<String, VarVersionPaar>();
public VarType anonymousClassType;
public List<ClassNode> nested = new ArrayList<ClassNode>();
public Set<String> enclosingClasses = new HashSet<String>();
public ClassNode parent;
public LambdaInformation lambdaInformation;
public boolean namelessConstructorStub = false;
public ClassNode(String content_class_name,
String content_method_name,
String content_method_descriptor,
int content_method_invocation_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
lambdaInformation = new LambdaInformation();
lambdaInformation.class_name = lambda_class_name;
lambdaInformation.method_name = lambda_method_name;
lambdaInformation.method_descriptor = lambda_method_descriptor;
lambdaInformation.content_class_name = content_class_name;
lambdaInformation.content_method_name = content_method_name;
lambdaInformation.content_method_descriptor = content_method_descriptor;
lambdaInformation.content_method_invocation_type = content_method_invocation_type;
lambdaInformation.content_method_key =
InterpreterUtil.makeUniqueKey(lambdaInformation.content_method_name, lambdaInformation.content_method_descriptor);
anonymousClassType = new VarType(lambda_class_name, true);
boolean is_method_reference = (content_class_name != classStruct.qualifiedName);
if (!is_method_reference) { // content method in the same class, check synthetic flag
StructMethod mt = classStruct.getMethod(content_method_name, content_method_descriptor);
is_method_reference = !mt.isSynthetic(); // if not synthetic -> method reference
}
lambdaInformation.is_method_reference = is_method_reference;
lambdaInformation.is_content_method_static =
(lambdaInformation.content_method_invocation_type == CodeConstants.CONSTANT_MethodHandle_REF_invokeStatic); // FIXME: redundant?
}
public ClassNode(int type, StructClass classStruct) {
this.type = type;
this.classStruct = classStruct;
simpleName = classStruct.qualifiedName.substring(classStruct.qualifiedName.lastIndexOf('/') + 1);
}
public ClassNode getClassNode(String qualifiedName) {
for (ClassNode node : nested) {
if (qualifiedName.equals(node.classStruct.qualifiedName)) {
return node;
}
}
return null;
}
public static class LambdaInformation {
public String class_name;
public String method_name;
public String method_descriptor;
public String content_class_name;
public String content_method_name;
public String content_method_descriptor;
public int content_method_invocation_type; // values from CONSTANT_MethodHandle_REF_*
public String content_method_key;
public boolean is_method_reference;
public boolean is_content_method_static;
}
}
}