/* * 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.ClassesProcessor.ClassNode; import org.jetbrains.java.decompiler.main.collectors.BytecodeMappingTracer; import org.jetbrains.java.decompiler.main.extern.IFernflowerLogger; import org.jetbrains.java.decompiler.main.extern.IFernflowerPreferences; import org.jetbrains.java.decompiler.main.rels.ClassWrapper; import org.jetbrains.java.decompiler.main.rels.MethodWrapper; import org.jetbrains.java.decompiler.modules.decompiler.ExprProcessor; import org.jetbrains.java.decompiler.modules.decompiler.exps.AnnotationExprent; import org.jetbrains.java.decompiler.modules.decompiler.exps.ConstExprent; import org.jetbrains.java.decompiler.modules.decompiler.exps.Exprent; import org.jetbrains.java.decompiler.modules.decompiler.exps.NewExprent; import org.jetbrains.java.decompiler.modules.decompiler.stats.RootStatement; import org.jetbrains.java.decompiler.modules.decompiler.vars.VarTypeProcessor; import org.jetbrains.java.decompiler.modules.decompiler.vars.VarVersionPaar; import org.jetbrains.java.decompiler.modules.renamer.PoolInterceptor; import org.jetbrains.java.decompiler.struct.StructClass; import org.jetbrains.java.decompiler.struct.StructField; import org.jetbrains.java.decompiler.struct.StructMember; import org.jetbrains.java.decompiler.struct.StructMethod; import org.jetbrains.java.decompiler.struct.attr.*; import org.jetbrains.java.decompiler.struct.consts.PrimitiveConstant; import org.jetbrains.java.decompiler.struct.gen.FieldDescriptor; import org.jetbrains.java.decompiler.struct.gen.MethodDescriptor; import org.jetbrains.java.decompiler.struct.gen.VarType; import org.jetbrains.java.decompiler.struct.gen.generics.*; import org.jetbrains.java.decompiler.util.InterpreterUtil; import java.util.*; public class ClassWriter { private ClassReference14Processor ref14processor; private PoolInterceptor interceptor; public ClassWriter() { ref14processor = new ClassReference14Processor(); interceptor = DecompilerContext.getPoolInterceptor(); } private void invokeProcessors(ClassNode node) { ClassWrapper wrapper = node.wrapper; StructClass cl = wrapper.getClassStruct(); InitializerProcessor.extractInitializers(wrapper); if (node.type == ClassNode.CLASS_ROOT && DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_CLASS_1_4)) { ref14processor.processClassReferences(node); } if (cl.hasModifier(CodeConstants.ACC_ENUM) && DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_ENUM)) { EnumProcessor.clearEnum(wrapper); } if (DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_ASSERTIONS)) { AssertProcessor.buildAssertions(node); } } public void classLambdaToJava(ClassNode node, TextBuffer buffer, Exprent method_object, int indent) { // get the class node with the content method ClassNode classNode = node; while (classNode != null && classNode.type == ClassNode.CLASS_LAMBDA) { classNode = classNode.parent; } if (classNode == null) { return; } boolean lambdaToAnonymous = DecompilerContext.getOption(IFernflowerPreferences.LAMBDA_TO_ANONYMOUS_CLASS); ClassNode outerNode = (ClassNode)DecompilerContext.getProperty(DecompilerContext.CURRENT_CLASS_NODE); DecompilerContext.setProperty(DecompilerContext.CURRENT_CLASS_NODE, node); BytecodeMappingTracer tracer = new BytecodeMappingTracer(); try { ClassWrapper wrapper = classNode.wrapper; StructClass cl = wrapper.getClassStruct(); DecompilerContext.getLogger().startWriteClass(node.simpleName); if (node.lambdaInformation.is_method_reference) { if (!node.lambdaInformation.is_content_method_static && method_object != null) { // reference to a virtual method buffer.append(method_object.toJava(indent, tracer)); } else { // reference to a static method buffer.append(ExprProcessor.getCastTypeName(new VarType(node.lambdaInformation.content_class_name, false))); } buffer.append("::"); buffer.append(node.lambdaInformation.content_method_name); } else { // lambda method StructMethod mt = cl.getMethod(node.lambdaInformation.content_method_key); MethodWrapper methodWrapper = wrapper.getMethodWrapper(mt.getName(), mt.getDescriptor()); MethodDescriptor md_content = MethodDescriptor.parseDescriptor(node.lambdaInformation.content_method_descriptor); MethodDescriptor md_lambda = MethodDescriptor.parseDescriptor(node.lambdaInformation.method_descriptor); if (!lambdaToAnonymous) { buffer.append('('); boolean firstParameter = true; int index = node.lambdaInformation.is_content_method_static ? 0 : 1; int start_index = md_content.params.length - md_lambda.params.length; for (int i = 0; i < md_content.params.length; i++) { if (i >= start_index) { if (!firstParameter) { buffer.append(", "); } String parameterName = methodWrapper.varproc.getVarName(new VarVersionPaar(index, 0)); buffer.append(parameterName == null ? "param" + index : parameterName); // null iff decompiled with errors firstParameter = false; } index += md_content.params[i].stackSize; } buffer.append(") ->"); } buffer.append(" {").appendLineSeparator(); methodLambdaToJava(node, classNode, mt, buffer, indent + 1, !lambdaToAnonymous, tracer); buffer.appendIndent(indent).append("}"); } } finally { DecompilerContext.setProperty(DecompilerContext.CURRENT_CLASS_NODE, outerNode); } DecompilerContext.getLogger().endWriteClass(); } public void classToJava(ClassNode node, TextBuffer buffer, int indent, BytecodeMappingTracer tracer) { ClassNode outerNode = (ClassNode)DecompilerContext.getProperty(DecompilerContext.CURRENT_CLASS_NODE); DecompilerContext.setProperty(DecompilerContext.CURRENT_CLASS_NODE, node); int startLine = tracer != null ? tracer.getCurrentSourceLine() : 0; BytecodeMappingTracer dummy_tracer = new BytecodeMappingTracer(); try { // last minute processing invokeProcessors(node); ClassWrapper wrapper = node.wrapper; StructClass cl = wrapper.getClassStruct(); DecompilerContext.getLogger().startWriteClass(cl.qualifiedName); // write class definition int start_class_def = buffer.length(); writeClassDefinition(node, buffer, indent); // // count lines in class definition the easiest way // startLine = buffer.substring(start_class_def).toString().split(lineSeparator, -1).length - 1; boolean hasContent = false; // fields boolean enumFields = false; for (StructField fd : cl.getFields()) { boolean hide = fd.isSynthetic() && DecompilerContext.getOption(IFernflowerPreferences.REMOVE_SYNTHETIC) || wrapper.getHiddenMembers().contains(InterpreterUtil.makeUniqueKey(fd.getName(), fd.getDescriptor())); if (hide) continue; boolean isEnum = fd.hasModifier(CodeConstants.ACC_ENUM) && DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_ENUM); if (isEnum) { if (enumFields) { buffer.append(',').appendLineSeparator(); } enumFields = true; } else if (enumFields) { buffer.append(';'); buffer.appendLineSeparator(); buffer.appendLineSeparator(); enumFields = false; } fieldToJava(wrapper, cl, fd, buffer, indent + 1, dummy_tracer); // FIXME: insert real tracer hasContent = true; } if (enumFields) { buffer.append(';').appendLineSeparator(); } // FIXME: fields don't matter at the moment startLine += buffer.countLines(start_class_def); // methods for (StructMethod mt : cl.getMethods()) { boolean hide = mt.isSynthetic() && DecompilerContext.getOption(IFernflowerPreferences.REMOVE_SYNTHETIC) || mt.hasModifier(CodeConstants.ACC_BRIDGE) && DecompilerContext.getOption(IFernflowerPreferences.REMOVE_BRIDGE) || wrapper.getHiddenMembers().contains(InterpreterUtil.makeUniqueKey(mt.getName(), mt.getDescriptor())); if (hide) continue; int position = buffer.length(); int storedLine = startLine; if (hasContent) { buffer.appendLineSeparator(); startLine++; } BytecodeMappingTracer method_tracer = new BytecodeMappingTracer(startLine); boolean methodSkipped = !methodToJava(node, mt, buffer, indent + 1, method_tracer); if (!methodSkipped) { hasContent = true; DecompilerContext.getBytecodeSourceMapper().addTracer(cl.qualifiedName, InterpreterUtil.makeUniqueKey(mt.getName(), mt.getDescriptor()), method_tracer); startLine = method_tracer.getCurrentSourceLine(); } else { buffer.setLength(position); startLine = storedLine; } } // member classes for (ClassNode inner : node.nested) { if (inner.type == ClassNode.CLASS_MEMBER) { StructClass innerCl = inner.classStruct; boolean isSynthetic = (inner.access & CodeConstants.ACC_SYNTHETIC) != 0 || innerCl.isSynthetic() || inner.namelessConstructorStub; boolean hide = isSynthetic && DecompilerContext.getOption(IFernflowerPreferences.REMOVE_SYNTHETIC) || wrapper.getHiddenMembers().contains(innerCl.qualifiedName); if (hide) continue; if (hasContent) { buffer.appendLineSeparator(); startLine++; } BytecodeMappingTracer class_tracer = new BytecodeMappingTracer(startLine); classToJava(inner, buffer, indent + 1, class_tracer); startLine = buffer.countLines(); hasContent = true; } } buffer.appendIndent(indent).append('}'); if (node.type != ClassNode.CLASS_ANONYMOUS) { buffer.appendLineSeparator(); } } finally { DecompilerContext.setProperty(DecompilerContext.CURRENT_CLASS_NODE, outerNode); } DecompilerContext.getLogger().endWriteClass(); } private void writeClassDefinition(ClassNode node, TextBuffer buffer, int indent) { if (node.type == ClassNode.CLASS_ANONYMOUS) { buffer.append(" {").appendLineSeparator(); return; } ClassWrapper wrapper = node.wrapper; StructClass cl = wrapper.getClassStruct(); int flags = node.type == ClassNode.CLASS_ROOT ? cl.getAccessFlags() : node.access; boolean isDeprecated = cl.getAttributes().containsKey("Deprecated"); boolean isSynthetic = (flags & CodeConstants.ACC_SYNTHETIC) != 0 || cl.getAttributes().containsKey("Synthetic"); boolean isEnum = DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_ENUM) && (flags & CodeConstants.ACC_ENUM) != 0; boolean isInterface = (flags & CodeConstants.ACC_INTERFACE) != 0; boolean isAnnotation = (flags & CodeConstants.ACC_ANNOTATION) != 0; if (isDeprecated) { appendDeprecation(buffer, indent); } if (interceptor != null) { String oldName = interceptor.getOldName(cl.qualifiedName); appendRenameComment(buffer, oldName, MType.CLASS, indent); } if (isSynthetic) { appendComment(buffer, "synthetic class", indent); } appendAnnotations(buffer, cl, indent); buffer.appendIndent(indent); if (isEnum) { // remove abstract and final flags (JLS 8.9 Enums) flags &= ~CodeConstants.ACC_ABSTRACT; flags &= ~CodeConstants.ACC_FINAL; } appendModifiers(buffer, flags, CLASS_ALLOWED, isInterface, CLASS_EXCLUDED); if (isEnum) { buffer.append("enum "); } else if (isInterface) { if (isAnnotation) { buffer.append('@'); } buffer.append("interface "); } else { buffer.append("class "); } GenericClassDescriptor descriptor = null; if (DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_GENERIC_SIGNATURES)) { StructGenericSignatureAttribute attr = (StructGenericSignatureAttribute)cl.getAttributes().getWithKey("Signature"); if (attr != null) { descriptor = GenericMain.parseClassSignature(attr.getSignature()); } } buffer.append(node.simpleName); if (descriptor != null && !descriptor.fparameters.isEmpty()) { appendTypeParameters(buffer, descriptor.fparameters, descriptor.fbounds); } buffer.append(' '); if (!isEnum && !isInterface && cl.superClass != null) { VarType supertype = new VarType(cl.superClass.getString(), true); if (!VarType.VARTYPE_OBJECT.equals(supertype)) { buffer.append("extends "); if (descriptor != null) { buffer.append(GenericMain.getGenericCastTypeName(descriptor.superclass)); } else { buffer.append(ExprProcessor.getCastTypeName(supertype)); } buffer.append(' '); } } if (!isAnnotation) { int[] interfaces = cl.getInterfaces(); if (interfaces.length > 0) { buffer.append(isInterface ? "extends " : "implements "); for (int i = 0; i < interfaces.length; i++) { if (i > 0) { buffer.append(", "); } if (descriptor != null) { buffer.append(GenericMain.getGenericCastTypeName(descriptor.superinterfaces.get(i))); } else { buffer.append(ExprProcessor.getCastTypeName(new VarType(cl.getInterface(i), true))); } } buffer.append(' '); } } buffer.append('{').appendLineSeparator(); } private void fieldToJava(ClassWrapper wrapper, StructClass cl, StructField fd, TextBuffer buffer, int indent, BytecodeMappingTracer tracer) { boolean isInterface = cl.hasModifier(CodeConstants.ACC_INTERFACE); boolean isDeprecated = fd.getAttributes().containsKey("Deprecated"); boolean isEnum = fd.hasModifier(CodeConstants.ACC_ENUM) && DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_ENUM); if (isDeprecated) { appendDeprecation(buffer, indent); } if (interceptor != null) { String oldName = interceptor.getOldName(cl.qualifiedName + " " + fd.getName() + " " + fd.getDescriptor()); appendRenameComment(buffer, oldName, MType.FIELD, indent); } if (fd.isSynthetic()) { appendComment(buffer, "synthetic field", indent); } appendAnnotations(buffer, fd, indent); buffer.appendIndent(indent); if (!isEnum) { appendModifiers(buffer, fd.getAccessFlags(), FIELD_ALLOWED, isInterface, FIELD_EXCLUDED); } VarType fieldType = new VarType(fd.getDescriptor(), false); GenericFieldDescriptor descriptor = null; if (DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_GENERIC_SIGNATURES)) { StructGenericSignatureAttribute attr = (StructGenericSignatureAttribute)fd.getAttributes().getWithKey("Signature"); if (attr != null) { descriptor = GenericMain.parseFieldSignature(attr.getSignature()); } } if (!isEnum) { if (descriptor != null) { buffer.append(GenericMain.getGenericCastTypeName(descriptor.type)); } else { buffer.append(ExprProcessor.getCastTypeName(fieldType)); } buffer.append(' '); } buffer.append(fd.getName()); Exprent initializer; if (fd.hasModifier(CodeConstants.ACC_STATIC)) { initializer = wrapper.getStaticFieldInitializers().getWithKey(InterpreterUtil.makeUniqueKey(fd.getName(), fd.getDescriptor())); } else { initializer = wrapper.getDynamicFieldInitializers().getWithKey(InterpreterUtil.makeUniqueKey(fd.getName(), fd.getDescriptor())); } if (initializer != null) { if (isEnum && initializer.type == Exprent.EXPRENT_NEW) { NewExprent nexpr = (NewExprent)initializer; nexpr.setEnumConst(true); buffer.append(nexpr.toJava(indent, tracer)); } else { buffer.append(" = "); // FIXME: special case field initializer. Can map to more than one method (constructor) and bytecode intruction. buffer.append(initializer.toJava(indent, tracer)); } } else if (fd.hasModifier(CodeConstants.ACC_FINAL) && fd.hasModifier(CodeConstants.ACC_STATIC)) { StructConstantValueAttribute attr = (StructConstantValueAttribute)fd.getAttributes().getWithKey(StructGeneralAttribute.ATTRIBUTE_CONSTANT_VALUE); if (attr != null) { PrimitiveConstant constant = cl.getPool().getPrimitiveConstant(attr.getIndex()); buffer.append(" = "); buffer.append(new ConstExprent(fieldType, constant.value, null).toJava(indent, tracer)); } } if (!isEnum) { buffer.append(";").appendLineSeparator(); } } private static void methodLambdaToJava(ClassNode lambdaNode, ClassNode classNode, StructMethod mt, TextBuffer buffer, int indent, boolean codeOnly, BytecodeMappingTracer tracer) { ClassWrapper classWrapper = classNode.wrapper; MethodWrapper methodWrapper = classWrapper.getMethodWrapper(mt.getName(), mt.getDescriptor()); MethodWrapper outerWrapper = (MethodWrapper)DecompilerContext.getProperty(DecompilerContext.CURRENT_METHOD_WRAPPER); DecompilerContext.setProperty(DecompilerContext.CURRENT_METHOD_WRAPPER, methodWrapper); try { String method_name = lambdaNode.lambdaInformation.method_name; MethodDescriptor md_content = MethodDescriptor.parseDescriptor(lambdaNode.lambdaInformation.content_method_descriptor); MethodDescriptor md_lambda = MethodDescriptor.parseDescriptor(lambdaNode.lambdaInformation.method_descriptor); if (!codeOnly) { buffer.appendIndent(indent); buffer.append("public "); buffer.append(method_name); buffer.append("("); boolean firstParameter = true; int index = lambdaNode.lambdaInformation.is_content_method_static ? 0 : 1; int start_index = md_content.params.length - md_lambda.params.length; for (int i = 0; i < md_content.params.length; i++) { if (i >= start_index) { if (!firstParameter) { buffer.append(", "); } String typeName = ExprProcessor.getCastTypeName(md_content.params[i].copy()); if (ExprProcessor.UNDEFINED_TYPE_STRING.equals(typeName) && DecompilerContext.getOption(IFernflowerPreferences.UNDEFINED_PARAM_TYPE_OBJECT)) { typeName = ExprProcessor.getCastTypeName(VarType.VARTYPE_OBJECT); } buffer.append(typeName); buffer.append(" "); String parameterName = methodWrapper.varproc.getVarName(new VarVersionPaar(index, 0)); buffer.append(parameterName == null ? "param" + index : parameterName); // null iff decompiled with errors firstParameter = false; } index += md_content.params[i].stackSize; } buffer.append(") {").appendLineSeparator(); indent += 1; } if (!methodWrapper.decompiledWithErrors) { RootStatement root = classWrapper.getMethodWrapper(mt.getName(), mt.getDescriptor()).root; if (root != null) { // check for existence try { buffer.append(root.toJava(indent, tracer)); } catch (Throwable ex) { DecompilerContext.getLogger().writeMessage("Method " + mt.getName() + " " + mt.getDescriptor() + " couldn't be written.", ex); methodWrapper.decompiledWithErrors = true; } } } if (methodWrapper.decompiledWithErrors) { buffer.appendIndent(indent); buffer.append("// $FF: Couldn't be decompiled"); buffer.appendLineSeparator(); } if (!codeOnly) { indent -= 1; buffer.appendIndent(indent); buffer.append('}'); buffer.appendLineSeparator(); } } finally { DecompilerContext.setProperty(DecompilerContext.CURRENT_METHOD_WRAPPER, outerWrapper); } } private boolean methodToJava(ClassNode node, StructMethod mt, TextBuffer buffer, int indent, BytecodeMappingTracer tracer) { ClassWrapper wrapper = node.wrapper; StructClass cl = wrapper.getClassStruct(); MethodWrapper methodWrapper = wrapper.getMethodWrapper(mt.getName(), mt.getDescriptor()); boolean hideMethod = false; int start_index_method = buffer.length(); MethodWrapper outerWrapper = (MethodWrapper)DecompilerContext.getProperty(DecompilerContext.CURRENT_METHOD_WRAPPER); DecompilerContext.setProperty(DecompilerContext.CURRENT_METHOD_WRAPPER, methodWrapper); try { boolean isInterface = cl.hasModifier(CodeConstants.ACC_INTERFACE); boolean isAnnotation = cl.hasModifier(CodeConstants.ACC_ANNOTATION); boolean isEnum = cl.hasModifier(CodeConstants.ACC_ENUM) && DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_ENUM); boolean isDeprecated = mt.getAttributes().containsKey("Deprecated"); boolean clinit = false, init = false, dinit = false; StructLineNumberTableAttribute lineNumberTable = (StructLineNumberTableAttribute)mt.getAttributes().getWithKey(StructGeneralAttribute.ATTRIBUTE_LINE_NUMBER_TABLE); tracer.setLineNumberTable(lineNumberTable); MethodDescriptor md = MethodDescriptor.parseDescriptor(mt.getDescriptor()); int flags = mt.getAccessFlags(); if ((flags & CodeConstants.ACC_NATIVE) != 0) { flags &= ~CodeConstants.ACC_STRICT; // compiler bug: a strictfp class sets all methods to strictfp } if ("".equals(mt.getName())) { flags &= CodeConstants.ACC_STATIC; // ignore all modifiers except 'static' in a static initializer } if (isDeprecated) { appendDeprecation(buffer, indent); } if (interceptor != null) { String oldName = interceptor.getOldName(cl.qualifiedName + " " + mt.getName() + " " + mt.getDescriptor()); appendRenameComment(buffer, oldName, MType.METHOD, indent); } boolean isSynthetic = (flags & CodeConstants.ACC_SYNTHETIC) != 0 || mt.getAttributes().containsKey("Synthetic"); boolean isBridge = (flags & CodeConstants.ACC_BRIDGE) != 0; if (isSynthetic) { appendComment(buffer, "synthetic method", indent); } if (isBridge) { appendComment(buffer, "bridge method", indent); } appendAnnotations(buffer, mt, indent); buffer.appendIndent(indent); appendModifiers(buffer, flags, METHOD_ALLOWED, isInterface, METHOD_EXCLUDED); if (isInterface && mt.containsCode()) { // 'default' modifier (Java 8) buffer.append("default "); } String name = mt.getName(); if ("".equals(name)) { if (node.type == ClassNode.CLASS_ANONYMOUS) { name = ""; dinit = true; } else { name = node.simpleName; init = true; } } else if ("".equals(name)) { name = ""; clinit = true; } GenericMethodDescriptor descriptor = null; if (DecompilerContext.getOption(IFernflowerPreferences.DECOMPILE_GENERIC_SIGNATURES)) { StructGenericSignatureAttribute attr = (StructGenericSignatureAttribute)mt.getAttributes().getWithKey("Signature"); if (attr != null) { descriptor = GenericMain.parseMethodSignature(attr.getSignature()); if (descriptor != null) { int actualParams = md.params.length; if (isEnum && init) actualParams -= 2; if (actualParams != descriptor.params.size()) { String message = "Inconsistent generic signature in method " + mt.getName() + " " + mt.getDescriptor(); DecompilerContext.getLogger().writeMessage(message, IFernflowerLogger.Severity.WARN); descriptor = null; } } } } boolean throwsExceptions = false; int paramCount = 0; if (!clinit && !dinit) { boolean thisVar = !mt.hasModifier(CodeConstants.ACC_STATIC); if (descriptor != null && !descriptor.fparameters.isEmpty()) { appendTypeParameters(buffer, descriptor.fparameters, descriptor.fbounds); buffer.append(' '); } if (!init) { if (descriptor != null) { buffer.append(GenericMain.getGenericCastTypeName(descriptor.ret)); } else { buffer.append(ExprProcessor.getCastTypeName(md.ret)); } buffer.append(' '); } buffer.append(name); buffer.append('('); // parameters List signFields = methodWrapper.signatureFields; int lastVisibleParameterIndex = -1; for (int i = 0; i < md.params.length; i++) { if (signFields == null || signFields.get(i) == null) { lastVisibleParameterIndex = i; } } boolean firstParameter = true; int index = isEnum && init ? 3 : thisVar ? 1 : 0; int start = isEnum && init && descriptor == null ? 2 : 0; int params = descriptor == null ? md.params.length : descriptor.params.size(); for (int i = start; i < params; i++) { if (signFields == null || signFields.get(i) == null) { if (!firstParameter) { buffer.append(", "); } appendParameterAnnotations(buffer, mt, paramCount); if (methodWrapper.varproc.getVarFinal(new VarVersionPaar(index, 0)) == VarTypeProcessor.VAR_EXPLICIT_FINAL) { buffer.append("final "); } if (descriptor != null) { GenericType parameterType = descriptor.params.get(i); boolean isVarArg = (i == lastVisibleParameterIndex && mt.hasModifier(CodeConstants.ACC_VARARGS) && parameterType.arrayDim > 0); if (isVarArg) { parameterType = parameterType.decreaseArrayDim(); } String typeName = GenericMain.getGenericCastTypeName(parameterType); if (ExprProcessor.UNDEFINED_TYPE_STRING.equals(typeName) && DecompilerContext.getOption(IFernflowerPreferences.UNDEFINED_PARAM_TYPE_OBJECT)) { typeName = ExprProcessor.getCastTypeName(VarType.VARTYPE_OBJECT); } buffer.append(typeName); if (isVarArg) { buffer.append("..."); } } else { VarType parameterType = md.params[i]; boolean isVarArg = (i == lastVisibleParameterIndex && mt.hasModifier(CodeConstants.ACC_VARARGS) && parameterType.arrayDim > 0); if (isVarArg) { parameterType = parameterType.decreaseArrayDim(); } String typeName = ExprProcessor.getCastTypeName(parameterType); if (ExprProcessor.UNDEFINED_TYPE_STRING.equals(typeName) && DecompilerContext.getOption(IFernflowerPreferences.UNDEFINED_PARAM_TYPE_OBJECT)) { typeName = ExprProcessor.getCastTypeName(VarType.VARTYPE_OBJECT); } buffer.append(typeName); if (isVarArg) { buffer.append("..."); } } buffer.append(' '); String parameterName = methodWrapper.varproc.getVarName(new VarVersionPaar(index, 0)); buffer.append(parameterName == null ? "param" + index : parameterName); // null iff decompiled with errors firstParameter = false; paramCount++; } index += md.params[i].stackSize; } buffer.append(')'); StructExceptionsAttribute attr = (StructExceptionsAttribute)mt.getAttributes().getWithKey("Exceptions"); if ((descriptor != null && !descriptor.exceptions.isEmpty()) || attr != null) { throwsExceptions = true; buffer.append(" throws "); for (int i = 0; i < attr.getThrowsExceptions().size(); i++) { if (i > 0) { buffer.append(", "); } if (descriptor != null && !descriptor.exceptions.isEmpty()) { GenericType type = descriptor.exceptions.get(i); buffer.append(GenericMain.getGenericCastTypeName(type)); } else { VarType type = new VarType(attr.getExcClassname(i, cl.getPool()), true); buffer.append(ExprProcessor.getCastTypeName(type)); } } } } if ((flags & (CodeConstants.ACC_ABSTRACT | CodeConstants.ACC_NATIVE)) != 0) { // native or abstract method (explicit or interface) if (isAnnotation) { StructAnnDefaultAttribute attr = (StructAnnDefaultAttribute)mt.getAttributes().getWithKey("AnnotationDefault"); if (attr != null) { buffer.append(" default "); buffer.append(attr.getDefaultValue().toJava(indent + 1, new BytecodeMappingTracer())); // dummy tracer } } buffer.append(';'); buffer.appendLineSeparator(); } else { if (!clinit && !dinit) { buffer.append(' '); } // We do not have line information for method start, lets have it here for now if (lineNumberTable != null && DecompilerContext.getOption(IFernflowerPreferences.USE_DEBUG_LINE_NUMBERS)) { buffer.setCurrentLine(lineNumberTable.getFirstLine() - 1); } buffer.append('{').appendLineSeparator(); RootStatement root = wrapper.getMethodWrapper(mt.getName(), mt.getDescriptor()).root; if (root != null && !methodWrapper.decompiledWithErrors) { // check for existence try { tracer.incrementCurrentSourceLine(buffer.countLines(start_index_method)); int startLine = tracer.getCurrentSourceLine(); TextBuffer code = root.toJava(indent + 1, tracer); hideMethod = (clinit || dinit || hideConstructor(wrapper, init, throwsExceptions, paramCount)) && code.length() == 0; if (!hideMethod && lineNumberTable != null && DecompilerContext.getOption(IFernflowerPreferences.USE_DEBUG_LINE_NUMBERS)) { mapLines(code, lineNumberTable, tracer, startLine); } buffer.append(code); } catch (Throwable ex) { DecompilerContext.getLogger().writeMessage("Method " + mt.getName() + " " + mt.getDescriptor() + " couldn't be written.", ex); methodWrapper.decompiledWithErrors = true; } } if (methodWrapper.decompiledWithErrors) { buffer.appendIndent(indent + 1); buffer.append("// $FF: Couldn't be decompiled"); buffer.appendLineSeparator(); tracer.incrementCurrentSourceLine(); } buffer.appendIndent(indent).append('}').appendLineSeparator(); tracer.incrementCurrentSourceLine(); } } finally { DecompilerContext.setProperty(DecompilerContext.CURRENT_METHOD_WRAPPER, outerWrapper); } // save total lines // TODO: optimize //tracer.setCurrentSourceLine(buffer.countLines(start_index_method)); return !hideMethod; } private static void mapLines(TextBuffer code, StructLineNumberTableAttribute table, BytecodeMappingTracer tracer, int startLine) { // build line start offsets map HashMap> lineStartOffsets = new HashMap>(); for (Map.Entry entry : tracer.getMapping().entrySet()) { Integer lineNumber = entry.getValue() - startLine; Set curr = lineStartOffsets.get(lineNumber); if (curr == null) { curr = new TreeSet(); // requires natural sorting! } curr.add(entry.getKey()); lineStartOffsets.put(lineNumber, curr); } String lineSeparator = DecompilerContext.getNewLineSeparator(); StringBuilder text = code.getOriginalText(); int pos = text.indexOf(lineSeparator); int lineNumber = 0; while (pos != -1) { Set startOffsets = lineStartOffsets.get(lineNumber); if (startOffsets != null) { for (Integer offset : startOffsets) { int number = table.findLineNumber(offset); if (number >= 0) { code.setLineMapping(number, pos); break; } } } pos = text.indexOf(lineSeparator, pos+1); lineNumber++; } } private static boolean hideConstructor(ClassWrapper wrapper, boolean init, boolean throwsExceptions, int paramCount) { if (!init || throwsExceptions || paramCount > 0 || !DecompilerContext.getOption(IFernflowerPreferences.HIDE_DEFAULT_CONSTRUCTOR)) { return false; } int count = 0; for (StructMethod mt : wrapper.getClassStruct().getMethods()) { if ("".equals(mt.getName())) { if (++count > 1) { return false; } } } return true; } private static void appendDeprecation(TextBuffer buffer, int indent) { buffer.appendIndent(indent).append("/** @deprecated */").appendLineSeparator(); } private enum MType {CLASS, FIELD, METHOD} private static void appendRenameComment(TextBuffer buffer, String oldName, MType type, int indent) { if (oldName == null) return; buffer.appendIndent(indent); buffer.append("// $FF: renamed from: "); switch (type) { case CLASS: buffer.append(ExprProcessor.buildJavaClassName(oldName)); break; case FIELD: String[] fParts = oldName.split(" "); FieldDescriptor fd = FieldDescriptor.parseDescriptor(fParts[2]); buffer.append(fParts[1]); buffer.append(' '); buffer.append(getTypePrintOut(fd.type)); break; default: String[] mParts = oldName.split(" "); MethodDescriptor md = MethodDescriptor.parseDescriptor(mParts[2]); buffer.append(mParts[1]); buffer.append(" ("); boolean first = true; for (VarType paramType : md.params) { if (!first) { buffer.append(", "); } first = false; buffer.append(getTypePrintOut(paramType)); } buffer.append(") "); buffer.append(getTypePrintOut(md.ret)); } buffer.appendLineSeparator(); } private static String getTypePrintOut(VarType type) { String typeText = ExprProcessor.getCastTypeName(type, false); if (ExprProcessor.UNDEFINED_TYPE_STRING.equals(typeText) && DecompilerContext.getOption(IFernflowerPreferences.UNDEFINED_PARAM_TYPE_OBJECT)) { typeText = ExprProcessor.getCastTypeName(VarType.VARTYPE_OBJECT, false); } return typeText; } private static void appendComment(TextBuffer buffer, String comment, int indent) { buffer.appendIndent(indent).append("// $FF: ").append(comment).appendLineSeparator(); } private static final String[] ANNOTATION_ATTRIBUTES = { StructGeneralAttribute.ATTRIBUTE_RUNTIME_VISIBLE_ANNOTATIONS, StructGeneralAttribute.ATTRIBUTE_RUNTIME_INVISIBLE_ANNOTATIONS}; private static void appendAnnotations(TextBuffer buffer, StructMember mb, int indent) { BytecodeMappingTracer tracer_dummy = new BytecodeMappingTracer(); // FIXME: replace with a real one for (String name : ANNOTATION_ATTRIBUTES) { StructAnnotationAttribute attribute = (StructAnnotationAttribute)mb.getAttributes().getWithKey(name); if (attribute != null) { for (AnnotationExprent annotation : attribute.getAnnotations()) { buffer.append(annotation.toJava(indent, tracer_dummy)).appendLineSeparator(); } } } } private static final String[] PARAMETER_ANNOTATION_ATTRIBUTES = { StructGeneralAttribute.ATTRIBUTE_RUNTIME_VISIBLE_PARAMETER_ANNOTATIONS, StructGeneralAttribute.ATTRIBUTE_RUNTIME_INVISIBLE_PARAMETER_ANNOTATIONS}; private static void appendParameterAnnotations(TextBuffer buffer, StructMethod mt, int param) { BytecodeMappingTracer tracer_dummy = new BytecodeMappingTracer(); // FIXME: replace with a real one for (String name : PARAMETER_ANNOTATION_ATTRIBUTES) { StructAnnotationParameterAttribute attribute = (StructAnnotationParameterAttribute)mt.getAttributes().getWithKey(name); if (attribute != null) { List> annotations = attribute.getParamAnnotations(); if (param < annotations.size()) { for (AnnotationExprent annotation : annotations.get(param)) { buffer.append(annotation.toJava(0, tracer_dummy)).append(' '); } } } } } private static final Map MODIFIERS = new LinkedHashMap() {{ put(CodeConstants.ACC_PUBLIC, "public"); put(CodeConstants.ACC_PROTECTED, "protected"); put(CodeConstants.ACC_PRIVATE, "private"); put(CodeConstants.ACC_ABSTRACT, "abstract"); put(CodeConstants.ACC_STATIC, "static"); put(CodeConstants.ACC_FINAL, "final"); put(CodeConstants.ACC_STRICT, "strictfp"); put(CodeConstants.ACC_TRANSIENT, "transient"); put(CodeConstants.ACC_VOLATILE, "volatile"); put(CodeConstants.ACC_SYNCHRONIZED, "synchronized"); put(CodeConstants.ACC_NATIVE, "native"); }}; private static final int CLASS_ALLOWED = CodeConstants.ACC_PUBLIC | CodeConstants.ACC_PROTECTED | CodeConstants.ACC_PRIVATE | CodeConstants.ACC_ABSTRACT | CodeConstants.ACC_STATIC | CodeConstants.ACC_FINAL | CodeConstants.ACC_STRICT; private static final int FIELD_ALLOWED = CodeConstants.ACC_PUBLIC | CodeConstants.ACC_PROTECTED | CodeConstants.ACC_PRIVATE | CodeConstants.ACC_STATIC | CodeConstants.ACC_FINAL | CodeConstants.ACC_TRANSIENT | CodeConstants.ACC_VOLATILE; private static final int METHOD_ALLOWED = CodeConstants.ACC_PUBLIC | CodeConstants.ACC_PROTECTED | CodeConstants.ACC_PRIVATE | CodeConstants.ACC_ABSTRACT | CodeConstants.ACC_STATIC | CodeConstants.ACC_FINAL | CodeConstants.ACC_SYNCHRONIZED | CodeConstants.ACC_NATIVE | CodeConstants.ACC_STRICT; private static final int CLASS_EXCLUDED = CodeConstants.ACC_ABSTRACT | CodeConstants.ACC_STATIC; private static final int FIELD_EXCLUDED = CodeConstants.ACC_PUBLIC | CodeConstants.ACC_STATIC | CodeConstants.ACC_FINAL; private static final int METHOD_EXCLUDED = CodeConstants.ACC_PUBLIC | CodeConstants.ACC_ABSTRACT; private static void appendModifiers(TextBuffer buffer, int flags, int allowed, boolean isInterface, int excluded) { flags &= allowed; if (!isInterface) excluded = 0; for (int modifier : MODIFIERS.keySet()) { if ((flags & modifier) == modifier && (modifier & excluded) == 0) { buffer.append(MODIFIERS.get(modifier)).append(' '); } } } private static void appendTypeParameters(TextBuffer buffer, List parameters, List> bounds) { buffer.append('<'); for (int i = 0; i < parameters.size(); i++) { if (i > 0) { buffer.append(", "); } buffer.append(parameters.get(i)); List parameterBounds = bounds.get(i); if (parameterBounds.size() > 1 || !"java/lang/Object".equals(parameterBounds.get(0).value)) { buffer.append(" extends "); buffer.append(GenericMain.getGenericCastTypeName(parameterBounds.get(0))); for (int j = 1; j < parameterBounds.size(); j++) { buffer.append(" & "); buffer.append(GenericMain.getGenericCastTypeName(parameterBounds.get(j))); } } } buffer.append('>'); } }