Mercurial > projects > qtd
view generator/abstractmetabuilder.cpp @ 397:590dcfc85873
Quick const-correctness fix for QModelIndex.
This probably deserves a more in-depth look later.
| author | David Nadlinger <code@klickverbot.at> |
|---|---|
| date | Mon, 03 Jan 2011 08:30:59 +0100 |
| parents | 1049b01aebd2 |
| children |
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/**************************************************************************** ** ** Copyright (C) 1992-2008 Nokia. All rights reserved. ** ** This file is part of Qt Jambi. ** ** * Commercial Usage * Licensees holding valid Qt Commercial licenses may use this file in * accordance with the Qt Commercial License Agreement provided with the * Software or, alternatively, in accordance with the terms contained in * a written agreement between you and Nokia. * * * GNU General Public License Usage * Alternatively, this file may be used under the terms of the GNU * General Public License versions 2.0 or 3.0 as published by the Free * Software Foundation and appearing in the file LICENSE.GPL included in * the packaging of this file. Please review the following information * to ensure GNU General Public Licensing requirements will be met: * http://www.fsf.org/licensing/licenses/info/GPLv2.html and * http://www.gnu.org/copyleft/gpl.html. In addition, as a special * exception, Nokia gives you certain additional rights. These rights * are described in the Nokia Qt GPL Exception version 1.2, included in * the file GPL_EXCEPTION.txt in this package. * * Qt for Windows(R) Licensees * As a special exception, Nokia, as the sole copyright holder for Qt * Designer, grants users of the Qt/Eclipse Integration plug-in the * right for the Qt/Eclipse Integration to link to functionality * provided by Qt Designer and its related libraries. * * * If you are unsure which license is appropriate for your use, please * contact the sales department at qt-sales@nokia.com. ** ** This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE ** WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. ** ****************************************************************************/ #include "abstractmetabuilder.h" #include "reporthandler.h" #include "ast.h" #include "binder.h" #include "control.h" #include "default_visitor.h" #include "dumptree.h" #include "lexer.h" #include "parser.h" #include "tokens.h" #include <QtCore/QDebug> #include <QtCore/QFile> #include <QtCore/QFileInfo> #include <QtCore/QTextCodec> #include <QtCore/QTextStream> #include <QtCore/QVariant> static QString strip_template_args(const QString &name) { int pos = name.indexOf('<'); return pos < 0 ? name : name.left(pos); } static QHash<QString, QString> *operator_names; QString rename_operator(const QString &oper) { QString op = oper.trimmed(); if (!operator_names) { operator_names = new QHash<QString, QString>; operator_names->insert("+", "add"); operator_names->insert("-", "subtract"); operator_names->insert("*", "multiply"); operator_names->insert("/", "divide"); operator_names->insert("%", "modulo"); operator_names->insert("&", "and"); operator_names->insert("|", "or"); operator_names->insert("^", "xor"); operator_names->insert("~", "negate"); operator_names->insert("<<", "shift_left"); operator_names->insert(">>", "shift_right"); // assigments operator_names->insert("=", "assign"); operator_names->insert("+=", "add_assign"); operator_names->insert("-=", "subtract_assign"); operator_names->insert("*=", "multiply_assign"); operator_names->insert("/=", "divide_assign"); operator_names->insert("%=", "modulo_assign"); operator_names->insert("&=", "and_assign"); operator_names->insert("|=", "or_assign"); operator_names->insert("^=", "xor_assign"); operator_names->insert("<<=", "shift_left_assign"); operator_names->insert(">>=", "shift_right_assign"); // Logical operator_names->insert("&&", "logical_and"); operator_names->insert("||", "logical_or"); operator_names->insert("!", "not"); // incr/decr operator_names->insert("++", "increment"); operator_names->insert("--", "decrement"); // compare operator_names->insert("<", "less"); operator_names->insert(">", "greater"); operator_names->insert("<=", "less_or_equal"); operator_names->insert(">=", "greater_or_equal"); operator_names->insert("!=", "not_equal"); operator_names->insert("==", "equal"); // other operator_names->insert("[]", "subscript"); operator_names->insert("->", "pointer"); } if (!operator_names->contains(op)) { TypeDatabase *tb = TypeDatabase::instance(); TypeParser::Info typeInfo = TypeParser::parse(op); QString cast_to_name = typeInfo.qualified_name.join("::"); TypeEntry *te = tb->findType(cast_to_name); if ((te && te->codeGeneration() == TypeEntry::GenerateNothing) || tb->isClassRejected(cast_to_name)) { return QString(); } else if (te) { return "operator_cast_" + typeInfo.qualified_name.join("_"); } else { ReportHandler::warning(QString("unknown operator '%1'").arg(op)); return "operator " + op; } } return "operator_" + operator_names->value(op); } AbstractMetaBuilder::AbstractMetaBuilder() : m_current_class(0) { } void AbstractMetaBuilder::checkFunctionModifications() { TypeDatabase *types = TypeDatabase::instance(); SingleTypeEntryHash entryHash = types->entries(); QList<TypeEntry *> entries = entryHash.values(); foreach (TypeEntry *entry, entries) { if (entry == 0) continue; if (!entry->isComplex() || entry->codeGeneration() == TypeEntry::GenerateNothing) continue; ComplexTypeEntry *centry = static_cast<ComplexTypeEntry *>(entry); FunctionModificationList modifications = centry->functionModifications(); foreach (FunctionModification modification, modifications) { QString signature = modification.signature; QString name = signature.trimmed(); name = name.mid(0, signature.indexOf("(")); AbstractMetaClass *clazz = m_meta_classes.findClass(centry->qualifiedCppName()); if (clazz == 0) continue; AbstractMetaFunctionList functions = clazz->functions(); bool found = false; QStringList possibleSignatures; foreach (AbstractMetaFunction *function, functions) { if (function->minimalSignature() == signature && function->implementingClass() == clazz) { found = true; break; } if (function->originalName() == name) possibleSignatures.append(function->minimalSignature() + " in " + function->implementingClass()->name()); } if (!found) { QString warning = QString("signature '%1' for function modification in '%2' not found. Possible candidates: %3") .arg(signature) .arg(clazz->qualifiedCppName()) .arg(possibleSignatures.join(", ")); ReportHandler::warning(warning); } } } } AbstractMetaClass *AbstractMetaBuilder::argumentToClass(ArgumentModelItem argument) { AbstractMetaClass *returned = 0; bool ok = false; AbstractMetaType *type = translateType(argument->type(), &ok); if (ok && type != 0 && type->typeEntry() != 0 && type->typeEntry()->isComplex()) { const TypeEntry *entry = type->typeEntry(); returned = m_meta_classes.findClass(entry->name()); } delete type; return returned; } /** * Checks the argument of a hash function and flags the type if it is a complex type */ void AbstractMetaBuilder::registerHashFunction(FunctionModelItem function_item) { ArgumentList arguments = function_item->arguments(); if (arguments.size() == 1) { if (AbstractMetaClass *cls = argumentToClass(arguments.at(0))) cls->setHasHashFunction(true); } } /** * Check if a class has a debug stream operator that can be used as toString */ void AbstractMetaBuilder::registerToStringCapability(FunctionModelItem function_item) { ArgumentList arguments = function_item->arguments(); if (arguments.size() == 2) { if (arguments.at(0)->type().toString() == "QDebug"){ ArgumentModelItem arg = arguments.at(1); if (AbstractMetaClass *cls = argumentToClass(arg)) { if (arg->type().indirections() < 2) { cls->setToStringCapability(function_item); } } } } } void AbstractMetaBuilder::traverseCompareOperator(FunctionModelItem item) { ArgumentList arguments = item->arguments(); if (arguments.size() == 2 && item->accessPolicy() == CodeModel::Public) { AbstractMetaClass *comparer_class = argumentToClass(arguments.at(0)); AbstractMetaClass *compared_class = argumentToClass(arguments.at(1)); if (comparer_class != 0 && compared_class != 0) { AbstractMetaClass *old_current_class = m_current_class; m_current_class = comparer_class; AbstractMetaFunction *meta_function = traverseFunction(item); if (meta_function != 0 && !meta_function->isInvalid()) { // Strip away first argument, since that is the containing object AbstractMetaArgumentList arguments = meta_function->arguments(); arguments.pop_front(); meta_function->setArguments(arguments); meta_function->setFunctionType(AbstractMetaFunction::GlobalScopeFunction); meta_function->setOriginalAttributes(meta_function->attributes()); setupFunctionDefaults(meta_function, comparer_class); comparer_class->addFunction(meta_function); } else if (meta_function != 0) { delete meta_function; } m_current_class = old_current_class; } } } void AbstractMetaBuilder::traverseStreamOperator(FunctionModelItem item) { ArgumentList arguments = item->arguments(); if (arguments.size() == 2 && item->accessPolicy() == CodeModel::Public) { AbstractMetaClass *streamClass = argumentToClass(arguments.at(0)); AbstractMetaClass *streamedClass = argumentToClass(arguments.at(1)); if (streamClass != 0 && streamedClass != 0 && (streamClass->name() == "QDataStream" || streamClass->name() == "QTextStream")) { AbstractMetaClass *old_current_class = m_current_class; m_current_class = streamedClass; AbstractMetaFunction *streamFunction = traverseFunction(item); if (streamFunction != 0 && !streamFunction->isInvalid()) { QString name = item->name(); streamFunction->setFunctionType(AbstractMetaFunction::GlobalScopeFunction); if (name.endsWith("<<")) streamFunction->setName("writeTo"); else streamFunction->setName("readFrom"); // Strip away last argument, since that is the containing object AbstractMetaArgumentList arguments = streamFunction->arguments(); arguments.pop_back(); streamFunction->setArguments(arguments); *streamFunction += AbstractMetaAttributes::Final; *streamFunction += AbstractMetaAttributes::Public; streamFunction->setOriginalAttributes(streamFunction->attributes()); streamFunction->setType(0); setupFunctionDefaults(streamFunction, streamedClass); streamedClass->addFunction(streamFunction); streamedClass->typeEntry()->addExtraInclude(streamClass->typeEntry()->include()); m_current_class = old_current_class; } } } } void AbstractMetaBuilder::fixQObjectForScope(TypeDatabase *types, NamespaceModelItem scope) { foreach (ClassModelItem item, scope->classes()) { QString qualified_name = item->qualifiedName().join("::"); TypeEntry *entry = types->findType(qualified_name); if (entry) { if (isQObject(qualified_name) && entry->isComplex()) { ((ComplexTypeEntry *) entry)->setQObject(true); } } } foreach (NamespaceModelItem item, scope->namespaceMap().values()) { if (scope != item) fixQObjectForScope(types, item); } } static bool class_less_than(AbstractMetaClass *a, AbstractMetaClass *b) { return a->name() < b->name(); } void AbstractMetaBuilder::sortLists() { qSort(m_meta_classes.begin(), m_meta_classes.end(), class_less_than); foreach (AbstractMetaClass *cls, m_meta_classes) { cls->sortFunctions(); } } bool AbstractMetaBuilder::build() { Q_ASSERT(!m_file_name.isEmpty()); ReportHandler::setContext("Parser"); QFile file(m_file_name); if (!file.open(QFile::ReadOnly)) return false; QTextStream stream(&file); stream.setCodec(QTextCodec::codecForName("UTF-8")); QByteArray contents = stream.readAll().toUtf8(); file.close(); Control control; Parser p(&control); pool __pool; TranslationUnitAST *ast = p.parse(contents, contents.size(), &__pool); CodeModel model; Binder binder(&model, p.location()); m_dom = binder.run(ast); ReportHandler::setContext("MetaJavaBuilder"); pushScope(model_dynamic_cast<ScopeModelItem>(m_dom)); QHash<QString, ClassModelItem> typeMap = m_dom->classMap(); // fix up QObject's in the type system.. TypeDatabase *types = TypeDatabase::instance(); fixQObjectForScope(types, model_dynamic_cast<NamespaceModelItem>(m_dom)); // Start the generation... foreach (ClassModelItem item, typeMap.values()) { AbstractMetaClass *cls = traverseClass(item); addAbstractMetaClass(cls); } QHash<QString, NamespaceModelItem> namespaceMap = m_dom->namespaceMap(); foreach (NamespaceModelItem item, namespaceMap.values()) { AbstractMetaClass *meta_class = traverseNamespace(item); if (meta_class) m_meta_classes << meta_class; } // Some trickery to support global-namespace enums... QHash<QString, EnumModelItem> enumMap = m_dom->enumMap(); m_current_class = 0; foreach (EnumModelItem item, enumMap) { AbstractMetaEnum *meta_enum = traverseEnum(item, 0, QSet<QString>()); if (meta_enum) { QString package = meta_enum->typeEntry()->javaPackage(); QString globalName = TypeDatabase::globalNamespaceClassName(meta_enum->typeEntry()); AbstractMetaClass *global = m_meta_classes.findClass(package + "." + globalName); if (!global) { ComplexTypeEntry *gte = new ObjectTypeEntry(globalName); gte->setTargetLangPackage(meta_enum->typeEntry()->javaPackage()); gte->setCodeGeneration(meta_enum->typeEntry()->codeGeneration()); global = createMetaClass(); global->setTypeEntry(gte); *global += AbstractMetaAttributes::Final; *global += AbstractMetaAttributes::Public; *global += AbstractMetaAttributes::Fake; m_meta_classes << global; } global->addEnum(meta_enum); meta_enum->setEnclosingClass(global); meta_enum->typeEntry()->setQualifier(globalName); } } // Go through all typedefs to see if we have defined any // specific typedefs to be used as classes. TypeAliasList typeAliases = m_dom->typeAliases(); foreach (TypeAliasModelItem typeAlias, typeAliases) { AbstractMetaClass *cls = traverseTypeAlias(typeAlias); addAbstractMetaClass(cls); } foreach (AbstractMetaClass *cls, m_meta_classes) { if (!cls->isInterface() && !cls->isNamespace()) { setupInheritance(cls); } } foreach (AbstractMetaClass *cls, m_meta_classes) { cls->fixFunctions(); if (cls->typeEntry() == 0) { ReportHandler::warning(QString("class '%1' does not have an entry in the type system") .arg(cls->name())); } else { if (!cls->hasConstructors() && !cls->isFinalInCpp() && !cls->isInterface() && !cls->isNamespace()) cls->addDefaultConstructor(); } if (cls->isAbstract() && !cls->isInterface()) { cls->typeEntry()->setLookupName(cls->typeEntry()->targetLangName() + "_ConcreteWrapper"); } } QList<TypeEntry *> entries = TypeDatabase::instance()->entries().values(); foreach (const TypeEntry *entry, entries) { if (entry->isPrimitive()) continue; if ((entry->isValue() || entry->isObject()) && !entry->isString() && !entry->isChar() && !entry->isContainer() && !entry->isCustom() && !entry->isVariant() && !m_meta_classes.findClass(entry->qualifiedCppName())) { ReportHandler::warning(QString("type '%1' is specified in typesystem, but not defined. This could potentially lead to compilation errors.") .arg(entry->qualifiedCppName())); } if (entry->isEnum()) { QString pkg = entry->javaPackage(); QString name = (pkg.isEmpty() ? QString() : pkg + ".") + ((EnumTypeEntry *) entry)->javaQualifier(); AbstractMetaClass *cls = m_meta_classes.findClass(name); if (!cls) { ReportHandler::warning(QString("namespace '%1' for enum '%2' is not declared") .arg(name).arg(entry->targetLangName())); } else { AbstractMetaEnum *e = cls->findEnum(entry->targetLangName()); if (!e) ReportHandler::warning(QString("enum '%1' is specified in typesystem, " "but not declared") .arg(entry->qualifiedCppName())); } } } { FunctionList hash_functions = m_dom->findFunctions("qHash"); foreach (FunctionModelItem item, hash_functions) { registerHashFunction(item); } } { FunctionList hash_functions = m_dom->findFunctions("operator<<"); foreach (FunctionModelItem item, hash_functions) { registerToStringCapability(item); } } { FunctionList compare_operators = m_dom->findFunctions("operator==") + m_dom->findFunctions("operator<=") + m_dom->findFunctions("operator>=") + m_dom->findFunctions("operator<") + m_dom->findFunctions("operator>"); foreach (FunctionModelItem item, compare_operators) { traverseCompareOperator(item); } } { FunctionList stream_operators = m_dom->findFunctions("operator<<") + m_dom->findFunctions("operator>>"); foreach (FunctionModelItem item, stream_operators) { traverseStreamOperator(item); } } figureOutEnumValues(); figureOutDefaultEnumArguments(); checkFunctionModifications(); foreach (AbstractMetaClass *cls, m_meta_classes) { setupEquals(cls); setupComparable(cls); setupClonable(cls); } dumpLog(); sortLists(); return true; } void AbstractMetaBuilder::addAbstractMetaClass(AbstractMetaClass *cls) { if (!cls) return; cls->setOriginalAttributes(cls->attributes()); if (cls->typeEntry()->isContainer()) { m_templates << cls; } else { m_meta_classes << cls; if (cls->typeEntry()->designatedInterface()) { AbstractMetaClass *interface = cls->extractInterface(); m_meta_classes << interface; ReportHandler::debugSparse(QString(" -> interface '%1'").arg(interface->name())); } } } AbstractMetaClass *AbstractMetaBuilder::traverseNamespace(NamespaceModelItem namespace_item) { QString namespace_name = (!m_namespace_prefix.isEmpty() ? m_namespace_prefix + "::" : QString()) + namespace_item->name(); NamespaceTypeEntry *type = TypeDatabase::instance()->findNamespaceType(namespace_name); if (TypeDatabase::instance()->isClassRejected(namespace_name)) { m_rejected_classes.insert(namespace_name, GenerationDisabled); return 0; } if (!type) { ReportHandler::warning(QString("namespace '%1' does not have a type entry") .arg(namespace_name)); return 0; } AbstractMetaClass *meta_class = createMetaClass(); meta_class->setTypeEntry(type); *meta_class += AbstractMetaAttributes::Public; m_current_class = meta_class; ReportHandler::debugSparse(QString("namespace '%1.%2'") .arg(meta_class->package()) .arg(namespace_item->name())); traverseEnums(model_dynamic_cast<ScopeModelItem>(namespace_item), meta_class, namespace_item->enumsDeclarations()); traverseFunctions(model_dynamic_cast<ScopeModelItem>(namespace_item), meta_class); // traverseClasses(model_dynamic_cast<ScopeModelItem>(namespace_item)); pushScope(model_dynamic_cast<ScopeModelItem>(namespace_item)); m_namespace_prefix = currentScope()->qualifiedName().join("::"); ClassList classes = namespace_item->classes(); foreach (ClassModelItem cls, classes) { AbstractMetaClass *mjc = traverseClass(cls); addAbstractMetaClass(mjc); } // Go through all typedefs to see if we have defined any // specific typedefs to be used as classes. TypeAliasList typeAliases = namespace_item->typeAliases(); foreach (TypeAliasModelItem typeAlias, typeAliases) { AbstractMetaClass *cls = traverseTypeAlias(typeAlias); addAbstractMetaClass(cls); } // Traverse namespaces recursively QList<NamespaceModelItem> inner_namespaces = namespace_item->namespaceMap().values(); foreach (const NamespaceModelItem &ni, inner_namespaces) { AbstractMetaClass *mjc = traverseNamespace(ni); addAbstractMetaClass(mjc); } m_current_class = 0; popScope(); m_namespace_prefix = currentScope()->qualifiedName().join("::"); if (!type->include().isValid()) { QFileInfo info(namespace_item->fileName()); type->setInclude(Include(Include::IncludePath, info.fileName())); } return meta_class; } struct Operator { enum Type { Plus, ShiftLeft, None }; Operator() : type(None) { } int calculate(int x) { switch (type) { case Plus: return x + value; case ShiftLeft: return x << value; case None: return x; } return x; } Type type; int value; }; Operator findOperator(QString *s) { const char *names[] = { "+", "<<" }; for (int i=0; i<Operator::None; ++i) { QString name = QLatin1String(names[i]); QString str = *s; int splitPoint = str.indexOf(name); if (splitPoint > 0) { bool ok; QString right = str.mid(splitPoint + name.length()); Operator op; op.value = right.toInt(&ok); if (ok) { op.type = Operator::Type(i); *s = str.left(splitPoint).trimmed(); return op; } } } return Operator(); } int AbstractMetaBuilder::figureOutEnumValue(const QString &stringValue, int oldValuevalue, AbstractMetaEnum *meta_enum, AbstractMetaFunction *meta_function) { if (stringValue.isEmpty()) return oldValuevalue; QStringList stringValues = stringValue.split("|"); int returnValue = 0; bool matched = false; for (int i=0; i<stringValues.size(); ++i) { QString s = stringValues.at(i).trimmed(); bool ok; int v; Operator op = findOperator(&s); if (s.length() > 0 && s.at(0) == QLatin1Char('0')) v = s.toUInt(&ok, 0); else v = s.toInt(&ok); if (ok) { matched = true; } else if (m_enum_values.contains(s)) { v = m_enum_values[s]->value(); matched = true; } else { AbstractMetaEnumValue *ev = 0; if (meta_enum && (ev = meta_enum->values().find(s))) { v = ev->value(); matched = true; } else if (meta_enum && (ev = meta_enum->enclosingClass()->findEnumValue(s, meta_enum))) { v = ev->value(); matched = true; } else { if (meta_enum) ReportHandler::warning("unhandled enum value: " + s + " in " + meta_enum->enclosingClass()->name() + "::" + meta_enum->name()); else ReportHandler::warning("unhandled enum value: Unknown enum"); } } if (matched) returnValue |= op.calculate(v); } if (!matched) { QString warn = QString("unmatched enum %1").arg(stringValue); if (meta_function != 0) { warn += QString(" when parsing default value of '%1' in class '%2'") .arg(meta_function->name()) .arg(meta_function->implementingClass()->name()); } ReportHandler::warning(warn); returnValue = oldValuevalue; } return returnValue; } void AbstractMetaBuilder::figureOutEnumValuesForClass(AbstractMetaClass *meta_class, QSet<AbstractMetaClass *> *classes) { AbstractMetaClass *base = meta_class->baseClass(); if (base != 0 && !classes->contains(base)) figureOutEnumValuesForClass(base, classes); if (classes->contains(meta_class)) return; AbstractMetaEnumList enums = meta_class->enums(); foreach (AbstractMetaEnum *e, enums) { if (!e) ReportHandler::warning("bad enum in class " + meta_class->name()); AbstractMetaEnumValueList lst = e->values(); int value = 0; for (int i=0; i<lst.size(); ++i) { value = figureOutEnumValue(lst.at(i)->stringValue(), value, e); lst.at(i)->setValue(value); value++; } // Check for duplicate values... EnumTypeEntry *ete = e->typeEntry(); if (!ete->forceInteger()) { QHash<int, AbstractMetaEnumValue *> entries; foreach (AbstractMetaEnumValue *v, lst) { bool vRejected = ete->isEnumValueRejected(v->name()); AbstractMetaEnumValue *current = entries.value(v->value()); if (current) { bool currentRejected = ete->isEnumValueRejected(current->name()); if (!currentRejected && !vRejected) { ReportHandler::warning( QString("duplicate enum values: %1::%2, %3 and %4 are %5, already rejected: (%6)") .arg(meta_class->name()) .arg(e->name()) .arg(v->name()) .arg(entries[v->value()]->name()) .arg(v->value()) .arg(ete->enumValueRejections().join(", "))); continue; } } if (!vRejected) entries[v->value()] = v; } // Entries now contain all the original entries, no // rejected ones... Use this to generate the enumValueRedirection table. foreach (AbstractMetaEnumValue *reject, lst) { if (!ete->isEnumValueRejected(reject->name())) continue; AbstractMetaEnumValue *used = entries.value(reject->value()); if (!used) { ReportHandler::warning( QString::fromLatin1("Rejected enum has no alternative...: %1::%2\n") .arg(meta_class->name()) .arg(reject->name())); continue; } ete->addEnumValueRedirection(reject->name(), used->name()); } } } *classes += meta_class; } void AbstractMetaBuilder::figureOutEnumValues() { // Keep a set of classes that we already traversed. We use this to // enforce that we traverse base classes prior to subclasses. QSet<AbstractMetaClass *> classes; foreach (AbstractMetaClass *c, m_meta_classes) { figureOutEnumValuesForClass(c, &classes); } } void AbstractMetaBuilder::figureOutDefaultEnumArguments() { foreach (AbstractMetaClass *meta_class, m_meta_classes) { foreach (AbstractMetaFunction *meta_function, meta_class->functions()) { foreach (AbstractMetaArgument *arg, meta_function->arguments()) { QString expr = arg->defaultValueExpression(); if (expr.isEmpty()) continue; if (!meta_function->replacedDefaultExpression(meta_function->implementingClass(), arg->argumentIndex()+1).isEmpty()) { continue; } QString new_expr = expr; if (arg->type()->isEnum()) { QStringList lst = expr.split(QLatin1String("::")); if (lst.size() == 1) { QVector<AbstractMetaClass *> classes(1, meta_class); AbstractMetaEnum *e = 0; while (!classes.isEmpty() && e == 0) { if (classes.front() != 0) { classes << classes.front()->baseClass(); AbstractMetaClassList interfaces = classes.front()->interfaces(); foreach (AbstractMetaClass *interface, interfaces) classes << interface->primaryInterfaceImplementor(); e = classes.front()->findEnumForValue(expr); } classes.pop_front(); } if (e != 0) { /* qtd new_expr = QString("%1.%2") .arg(e->typeEntry()->qualifiedTargetLangName()) .arg(expr); */ // new_expr = arg->type()->typeEntry()->targetLangName() + "." + expr; new_expr = arg->type()->typeEntry()->qualifiedTargetLangName() + "." + expr; } else { ReportHandler::warning("Cannot find enum constant for value '" + expr + "' in '" + meta_class->name() + "' or any of its super classes"); } } else if (lst.size() == 2) { AbstractMetaClass *cl = m_meta_classes.findClass(lst.at(0)); if (!cl) { ReportHandler::warning("missing required class for enums: " + lst.at(0)); continue; } /* qtd new_expr = QString("%1.%2.%3") .arg(cl->typeEntry()->qualifiedTargetLangName()) .arg(arg->type()->name()) .arg(lst.at(1)); */ // new_expr = arg->type()->typeEntry()->targetLangName() + "." + lst.at(1); new_expr = arg->type()->typeEntry()->qualifiedTargetLangName() + "." + lst.at(1); } else { ReportHandler::warning("bad default value passed to enum " + expr); } } else if(arg->type()->isFlags()) { const FlagsTypeEntry *flagsEntry = static_cast<const FlagsTypeEntry *>(arg->type()->typeEntry()); EnumTypeEntry *enumEntry = flagsEntry->originator(); AbstractMetaEnum *meta_enum = m_meta_classes.findEnum(enumEntry); if (!meta_enum) { ReportHandler::warning("unknown required enum " + enumEntry->qualifiedCppName()); continue; } int value = figureOutEnumValue(expr, 0, meta_enum, meta_function); new_expr = QString::number(value); } else if (arg->type()->isPrimitive()) { AbstractMetaEnumValue *value = 0; if (expr.contains("::")) value = m_meta_classes.findEnumValue(expr); if (!value) value = meta_class->findEnumValue(expr, 0); if (value) { new_expr = QString::number(value->value()); } else if (expr.contains(QLatin1Char('+'))) { new_expr = QString::number(figureOutEnumValue(expr, 0, 0)); } } arg->setDefaultValueExpression(new_expr); } } } } AbstractMetaEnum *AbstractMetaBuilder::traverseEnum(EnumModelItem enum_item, AbstractMetaClass *enclosing, const QSet<QString> &enumsDeclarations) { // Skipping private enums. if (enum_item->accessPolicy() == CodeModel::Private) { return 0; } QString qualified_name = enum_item->qualifiedName().join("::"); TypeEntry *type_entry = TypeDatabase::instance()->findType(qualified_name); QString enum_name = enum_item->name(); QString class_name; if (m_current_class) class_name = m_current_class->typeEntry()->qualifiedCppName(); if (TypeDatabase::instance()->isEnumRejected(class_name, enum_name)) { m_rejected_enums.insert(qualified_name, GenerationDisabled); return 0; } if (!type_entry || !type_entry->isEnum()) { QString context = m_current_class ? m_current_class->name() : QLatin1String(""); ReportHandler::warning(QString("enum '%1' does not have a type entry or is not an enum") .arg(qualified_name)); m_rejected_enums.insert(qualified_name, NotInTypeSystem); return 0; } AbstractMetaEnum *meta_enum = createMetaEnum(); if ( enumsDeclarations.contains(qualified_name) || enumsDeclarations.contains(enum_name)) { meta_enum->setHasQEnumsDeclaration(true); } meta_enum->setTypeEntry((EnumTypeEntry *) type_entry); switch (enum_item->accessPolicy()) { case CodeModel::Public: *meta_enum += AbstractMetaAttributes::Public; break; case CodeModel::Protected: *meta_enum += AbstractMetaAttributes::Protected; break; // case CodeModel::Private: *meta_enum += AbstractMetaAttributes::Private; break; default: break; } ReportHandler::debugMedium(QString(" - traversing enum %1").arg(meta_enum->fullName())); foreach (EnumeratorModelItem value, enum_item->enumerators()) { AbstractMetaEnumValue *meta_enum_value = createMetaEnumValue(); meta_enum_value->setName(value->name()); // Deciding the enum value... meta_enum_value->setStringValue(value->value()); meta_enum->addEnumValue(meta_enum_value); ReportHandler::debugFull(" - " + meta_enum_value->name() + " = " + meta_enum_value->value()); // Add into global register... if (enclosing) m_enum_values[enclosing->name() + "::" + meta_enum_value->name()] = meta_enum_value; else m_enum_values[meta_enum_value->name()] = meta_enum_value; } m_enums << meta_enum; return meta_enum; } AbstractMetaClass *AbstractMetaBuilder::traverseTypeAlias(TypeAliasModelItem typeAlias) { QString class_name = strip_template_args(typeAlias->name()); QString full_class_name = class_name; // we have an inner class if (m_current_class) { full_class_name = strip_template_args(m_current_class->typeEntry()->qualifiedCppName()) + "::" + full_class_name; } // If we haven't specified anything for the typedef, then we don't care ComplexTypeEntry *type = TypeDatabase::instance()->findComplexType(full_class_name); if (type == 0) return 0; if (type->isObject()) static_cast<ObjectTypeEntry *>(type)->setQObject(isQObject(strip_template_args(typeAlias->type().qualifiedName().join("::")))); AbstractMetaClass *meta_class = createMetaClass(); meta_class->setTypeAlias(true); meta_class->setTypeEntry(type); meta_class->setBaseClassNames(QStringList() << typeAlias->type().qualifiedName().join("::")); *meta_class += AbstractMetaAttributes::Public; // Set the default include file name if (!type->include().isValid()) { QFileInfo info(typeAlias->fileName()); type->setInclude(Include(Include::IncludePath, info.fileName())); } return meta_class; } AbstractMetaClass *AbstractMetaBuilder::traverseClass(ClassModelItem class_item) { QString class_name = strip_template_args(class_item->name()); QString full_class_name = class_name; // we have inner an class if (m_current_class) { full_class_name = strip_template_args(m_current_class->typeEntry()->qualifiedCppName()) + "::" + full_class_name; } ComplexTypeEntry *type = TypeDatabase::instance()->findComplexType(full_class_name); RejectReason reason = NoReason; if (TypeDatabase::instance()->isClassRejected(full_class_name)) { reason = GenerationDisabled; } else if (!type) { TypeEntry *te = TypeDatabase::instance()->findType(full_class_name); if (te && !te->isComplex()) reason = RedefinedToNotClass; else reason = NotInTypeSystem; } else if (type->codeGeneration() == TypeEntry::GenerateNothing) { reason = GenerationDisabled; } if (reason != NoReason) { m_rejected_classes.insert(full_class_name, reason); return 0; } if (type->isObject()) { ((ObjectTypeEntry *)type)->setQObject(isQObject(full_class_name)); } AbstractMetaClass *meta_class = createMetaClass(); meta_class->setTypeEntry(type); meta_class->setBaseClassNames(class_item->baseClasses()); *meta_class += AbstractMetaAttributes::Public; AbstractMetaClass *old_current_class = m_current_class; m_current_class = meta_class; if (type->isContainer()) { ReportHandler::debugSparse(QString("container: '%1'").arg(full_class_name)); } else { ReportHandler::debugSparse(QString("class: '%1'").arg(meta_class->fullName())); } TemplateParameterList template_parameters = class_item->templateParameters(); QList<TypeEntry *> template_args; template_args.clear(); for (int i=0; i<template_parameters.size(); ++i) { const TemplateParameterModelItem ¶m = template_parameters.at(i); TemplateArgumentEntry *param_type = new TemplateArgumentEntry(param->name()); param_type->setOrdinal(i); template_args.append(param_type); } meta_class->setTemplateArguments(template_args); parseQ_Property(meta_class, class_item->propertyDeclarations()); traverseFunctions(model_dynamic_cast<ScopeModelItem>(class_item), meta_class); traverseEnums(model_dynamic_cast<ScopeModelItem>(class_item), meta_class, class_item->enumsDeclarations()); traverseFields(model_dynamic_cast<ScopeModelItem>(class_item), meta_class); // Inner classes { QList<ClassModelItem> inner_classes = class_item->classMap().values(); foreach (const ClassModelItem &ci, inner_classes) { AbstractMetaClass *cl = traverseClass(ci); if (cl) { cl->setEnclosingClass(meta_class); m_meta_classes << cl; } } } // Go through all typedefs to see if we have defined any // specific typedefs to be used as classes. TypeAliasList typeAliases = class_item->typeAliases(); foreach (TypeAliasModelItem typeAlias, typeAliases) { AbstractMetaClass *cls = traverseTypeAlias(typeAlias); if (cls != 0) { cls->setEnclosingClass(meta_class); addAbstractMetaClass(cls); } } m_current_class = old_current_class; // Set the default include file name if (!type->include().isValid()) { QFileInfo info(class_item->fileName()); type->setInclude(Include(Include::IncludePath, info.fileName())); } return meta_class; } AbstractMetaField *AbstractMetaBuilder::traverseField(VariableModelItem field, const AbstractMetaClass *cls) { QString field_name = field->name(); QString class_name = m_current_class->typeEntry()->qualifiedCppName(); // Ignore friend decl. if (field->isFriend()) return 0; if (field->accessPolicy() == CodeModel::Private) return 0; if (TypeDatabase::instance()->isFieldRejected(class_name, field_name)) { m_rejected_fields.insert(class_name + "::" + field_name, GenerationDisabled); return 0; } AbstractMetaField *meta_field = createMetaField(); meta_field->setName(field_name); meta_field->setEnclosingClass(cls); bool ok; TypeInfo field_type = field->type(); AbstractMetaType *meta_type = translateType(field_type, &ok); if (!meta_type || !ok) { ReportHandler::warning(QString("skipping field '%1::%2' with unmatched type '%3'") .arg(m_current_class->name()) .arg(field_name) .arg(TypeInfo::resolveType(field_type, currentScope()->toItem()).qualifiedName().join("::"))); delete meta_field; return 0; } meta_field->setType(meta_type); uint attr = 0; if (field->isStatic()) attr |= AbstractMetaAttributes::Static; CodeModel::AccessPolicy policy = field->accessPolicy(); if (policy == CodeModel::Public) attr |= AbstractMetaAttributes::Public; else if (policy == CodeModel::Protected) attr |= AbstractMetaAttributes::Protected; else attr |= AbstractMetaAttributes::Private; meta_field->setAttributes(attr); return meta_field; } void AbstractMetaBuilder::traverseFields(ScopeModelItem scope_item, AbstractMetaClass *meta_class) { foreach (VariableModelItem field, scope_item->variables()) { AbstractMetaField *meta_field = traverseField(field, meta_class); if (meta_field) { meta_field->setOriginalAttributes(meta_field->attributes()); meta_class->addField(meta_field); } } } void AbstractMetaBuilder::setupFunctionDefaults(AbstractMetaFunction *meta_function, AbstractMetaClass *meta_class) { // Set the default value of the declaring class. This may be changed // in fixFunctions later on meta_function->setDeclaringClass(meta_class); // Some of the queries below depend on the implementing class being set // to function properly. Such as function modifications meta_function->setImplementingClass(meta_class); if (meta_function->name() == "operator_equal") meta_class->setHasEqualsOperator(true); if (!meta_function->isFinalInTargetLang() && meta_function->isRemovedFrom(meta_class, TypeSystem::TargetLangCode)) { *meta_function += AbstractMetaAttributes::FinalInCpp; } } void AbstractMetaBuilder::traverseFunctions(ScopeModelItem scope_item, AbstractMetaClass *meta_class) { foreach (FunctionModelItem function, scope_item->functions()) { AbstractMetaFunction *meta_function = traverseFunction(function); if (meta_function) { QList<FunctionModification> mods = meta_function->modifications(meta_class); for (int i=0; i<mods.size(); ++i) { if (mods.at(i).isPrivateSignal()) { meta_function->setFunctionType(AbstractMetaFunction::SignalFunction); } } meta_function->setOriginalAttributes(meta_function->attributes()); if (meta_class->isNamespace()) *meta_function += AbstractMetaAttributes::Static; if (!meta_function->isInvalid()) { if (QPropertySpec *read = meta_class->propertySpecForRead(meta_function->name())) { if (read->type() == meta_function->type()->typeEntry()) { *meta_function += AbstractMetaAttributes::PropertyReader; meta_function->setPropertySpec(read); // printf("%s is reader for %s\n", // qPrintable(meta_function->name()), // qPrintable(read->name())); } } else if (QPropertySpec *write = meta_class->propertySpecForWrite(meta_function->name())) { if (write->type() == meta_function->arguments().at(0)->type()->typeEntry()) { *meta_function += AbstractMetaAttributes::PropertyWriter; meta_function->setPropertySpec(write); /* // qtd D properties syntax, rename setter from setPropertyName to just propertyName AbstractMetaFunction *f_copy = new AbstractMetaFunction(); *f_copy = *meta_function; QString f_name = meta_function->name(); QString new_name = f_name.midRef(3, 1).toString().toLower() + f_name.right(f_name.length() - 4); meta_function->setName(new_name); // f_copy->setOwnerClass(meta_function->ownerClass()); ((AbstractMetaClass*)(meta_function->ownerClass()))->addFunction(f_copy); // hack qtd2 // */ // printf("%s is writer for %s\n", // qPrintable(meta_function->name()), // qPrintable(write->name())); } } else if (QPropertySpec *reset = meta_class->propertySpecForReset(meta_function->name())) { *meta_function += AbstractMetaAttributes::PropertyResetter; meta_function->setPropertySpec(reset); // printf("%s is resetter for %s\n", // qPrintable(meta_function->name()), // qPrintable(reset->name())); } } bool isInvalidDestructor = meta_function->isDestructor() && meta_function->isPrivate(); bool isInvalidConstructor = meta_function->isConstructor() && (meta_function->isPrivate() || meta_function->isInvalid()); if ((isInvalidDestructor || isInvalidConstructor) && !meta_class->hasNonPrivateConstructor()) { *meta_class += AbstractMetaAttributes::Final; } else if (meta_function->isConstructor() && !meta_function->isPrivate()) { *meta_class -= AbstractMetaAttributes::Final; meta_class->setHasNonPrivateConstructor(true); } if (meta_function->isDestructor() && !meta_function->isFinal()) meta_class->setHasVirtualDestructor(true); if (!meta_function->isDestructor() && !meta_function->isInvalid() && (!meta_function->isConstructor() || !meta_function->isPrivate())) { if (meta_class->typeEntry()->designatedInterface() && !meta_function->isPublic() && !meta_function->isPrivate()) { QString warn = QString("non-public function '%1' in interface '%2'") .arg(meta_function->name()).arg(meta_class->name()); ReportHandler::warning(warn); meta_function->setVisibility(AbstractMetaClass::Public); } setupFunctionDefaults(meta_function, meta_class); if (meta_function->isSignal() && meta_class->hasSignal(meta_function)) { QString warn = QString("signal '%1' in class '%2' is overloaded.") .arg(meta_function->name()).arg(meta_class->name()); ReportHandler::warning(warn); } if (meta_function->isSignal() && !meta_class->isQObject()) { QString warn = QString("signal '%1' in non-QObject class '%2'") .arg(meta_function->name()).arg(meta_class->name()); ReportHandler::warning(warn); } meta_class->addFunction(meta_function); } else if (meta_function->isDestructor() && !meta_function->isPublic()) { meta_class->setHasPublicDestructor(false); } } } } bool AbstractMetaBuilder::setupInheritance(AbstractMetaClass *meta_class) { Q_ASSERT(!meta_class->isInterface()); if (m_setup_inheritance_done.contains(meta_class)) return true; m_setup_inheritance_done.insert(meta_class); QStringList base_classes = meta_class->baseClassNames(); TypeDatabase *types = TypeDatabase::instance(); // we only support our own containers and ONLY if there is only one baseclass if (base_classes.size() == 1 && base_classes.first().count('<') == 1) { QStringList scope = meta_class->typeEntry()->qualifiedCppName().split("::"); scope.removeLast(); for (int i=scope.size(); i>=0; --i) { QString prefix = i > 0 ? QStringList(scope.mid(0, i)).join("::") + "::" : QString(); QString complete_name = prefix + base_classes.first(); TypeParser::Info info = TypeParser::parse(complete_name); QString base_name = info.qualified_name.join("::"); AbstractMetaClass *templ = 0; foreach (AbstractMetaClass *c, m_templates) { if (c->typeEntry()->name() == base_name) { templ = c; break; } } if (templ == 0) templ = m_meta_classes.findClass(base_name); if (templ) { setupInheritance(templ); inheritTemplate(meta_class, templ, info); return true; } } ReportHandler::warning(QString("template baseclass '%1' of '%2' is not known") .arg(base_classes.first()) .arg(meta_class->name())); return false; } int primary = -1; int primaries = 0; for (int i=0; i<base_classes.size(); ++i) { if (types->isClassRejected(base_classes.at(i))) continue; TypeEntry *base_class_entry = types->findType(base_classes.at(i)); if (!base_class_entry) { ReportHandler::warning(QString("class '%1' inherits from unknown base class '%2'") .arg(meta_class->name()).arg(base_classes.at(i))); } // true for primary base class else if (!base_class_entry->designatedInterface()) { if (primaries > 0) { ReportHandler::warning(QString("class '%1' has multiple primary base classes" " '%2' and '%3'") .arg(meta_class->name()) .arg(base_classes.at(primary)) .arg(base_class_entry->name())); return false; } primaries++; primary = i; } } if (primary >= 0) { AbstractMetaClass *base_class = m_meta_classes.findClass(base_classes.at(primary)); if (!base_class) { ReportHandler::warning(QString("unknown baseclass for '%1': '%2'") .arg(meta_class->name()) .arg(base_classes.at(primary))); return false; } meta_class->setBaseClass(base_class); if (meta_class->typeEntry()->designatedInterface() != 0 && meta_class->isQObject()) { ReportHandler::warning(QString("QObject extended by interface type '%1'. This is not supported and the generated Java code will not compile.") .arg(meta_class->name())); } else if (meta_class->typeEntry()->designatedInterface() != 0 && base_class != 0 && !base_class->isInterface()) { ReportHandler::warning(QString("object type '%1' extended by interface type '%2'. The resulting API will be less expressive than the original.") .arg(base_class->name()) .arg(meta_class->name())); } } for (int i=0; i<base_classes.size(); ++i) { if (types->isClassRejected(base_classes.at(i))) continue; if (i != primary) { AbstractMetaClass *base_class = m_meta_classes.findClass(base_classes.at(i)); if (base_class == 0) { ReportHandler::warning(QString("class not found for setup inheritance '%1'").arg(base_classes.at(i))); return false; } setupInheritance(base_class); QString interface_name = InterfaceTypeEntry::interfaceName(base_class->name()); AbstractMetaClass *iface = m_meta_classes.findClass(interface_name); if (!iface) { ReportHandler::warning(QString("unknown interface for '%1': '%2'") .arg(meta_class->name()) .arg(interface_name)); return false; } meta_class->addInterface(iface); AbstractMetaClassList interfaces = iface->interfaces(); foreach (AbstractMetaClass *iface, interfaces) meta_class->addInterface(iface); } } return true; } void AbstractMetaBuilder::traverseEnums(ScopeModelItem scope_item, AbstractMetaClass *meta_class, const QStringList &enumsDeclarations) { EnumList enums = scope_item->enums(); foreach (EnumModelItem enum_item, enums) { AbstractMetaEnum *meta_enum = traverseEnum(enum_item, meta_class, QSet<QString>::fromList(enumsDeclarations)); if (meta_enum) { meta_enum->setOriginalAttributes(meta_enum->attributes()); meta_class->addEnum(meta_enum); meta_enum->setEnclosingClass(meta_class); } } } AbstractMetaFunction *AbstractMetaBuilder::traverseFunction(FunctionModelItem function_item) { QString function_name = function_item->name(); QString class_name = m_current_class->typeEntry()->qualifiedCppName(); if (TypeDatabase::instance()->isFunctionRejected(class_name, function_name)) { m_rejected_functions.insert(class_name + "::" + function_name, GenerationDisabled); return 0; } Q_ASSERT(function_item->functionType() == CodeModel::Normal || function_item->functionType() == CodeModel::Signal || function_item->functionType() == CodeModel::Slot); if (function_item->isFriend()) return 0; QString cast_type; if (function_name.startsWith("operator")) { function_name = rename_operator(function_name.mid(8)); if (function_name.isEmpty()) { m_rejected_functions.insert(class_name + "::" + function_name, GenerationDisabled); return 0; } if (function_name.contains("_cast_")) cast_type = function_name.mid(14).trimmed(); } AbstractMetaFunction *meta_function = createMetaFunction(); meta_function->setConstant(function_item->isConstant()); ReportHandler::debugMedium(QString(" - %2()").arg(function_name)); meta_function->setName(function_name); meta_function->setOriginalName(function_item->name()); if (function_item->isAbstract()) *meta_function += AbstractMetaAttributes::Abstract; if (!meta_function->isAbstract()) *meta_function += AbstractMetaAttributes::Native; if (!function_item->isVirtual()) *meta_function += AbstractMetaAttributes::Final; if (function_item->isInvokable()) *meta_function += AbstractMetaAttributes::Invokable; if (function_item->isStatic()) { *meta_function += AbstractMetaAttributes::Static; *meta_function += AbstractMetaAttributes::Final; } // Access rights if (function_item->accessPolicy() == CodeModel::Public) *meta_function += AbstractMetaAttributes::Public; else if (function_item->accessPolicy() == CodeModel::Private) *meta_function += AbstractMetaAttributes::Private; else *meta_function += AbstractMetaAttributes::Protected; QString stripped_class_name = class_name; int cc_pos = stripped_class_name.lastIndexOf("::"); if (cc_pos > 0) stripped_class_name = stripped_class_name.mid(cc_pos + 2); TypeInfo function_type = function_item->type(); if (function_name.startsWith('~')) { meta_function->setFunctionType(AbstractMetaFunction::DestructorFunction); meta_function->setInvalid(true); } else if (strip_template_args(function_name) == stripped_class_name) { meta_function->setFunctionType(AbstractMetaFunction::ConstructorFunction); meta_function->setName(m_current_class->name()); } else { bool ok; AbstractMetaType *type = 0; if (!cast_type.isEmpty()) { TypeInfo info; info.setQualifiedName(QStringList(cast_type)); type = translateType(info, &ok); } else { type = translateType(function_type, &ok); } if (!ok) { ReportHandler::warning(QString("skipping function '%1::%2', unmatched return type '%3'") .arg(class_name) .arg(function_item->name()) .arg(function_item->type().toString())); m_rejected_functions[class_name + "::" + function_name] = UnmatchedReturnType; meta_function->setInvalid(true); return meta_function; } meta_function->setType(type); if (function_item->functionType() == CodeModel::Signal) meta_function->setFunctionType(AbstractMetaFunction::SignalFunction); else if (function_item->functionType() == CodeModel::Slot) meta_function->setFunctionType(AbstractMetaFunction::SlotFunction); } ArgumentList arguments = function_item->arguments(); AbstractMetaArgumentList meta_arguments; int first_default_argument = 0; for (int i=0; i<arguments.size(); ++i) { ArgumentModelItem arg = arguments.at(i); bool ok; AbstractMetaType *meta_type = translateType(arg->type(), &ok); if (!meta_type || !ok) { ReportHandler::warning(QString("skipping function '%1::%2', " "unmatched parameter type '%3'") .arg(class_name) .arg(function_item->name()) .arg(arg->type().toString())); m_rejected_functions[class_name + "::" + function_name] = UnmatchedArgumentType; meta_function->setInvalid(true); return meta_function; } AbstractMetaArgument *meta_argument = createMetaArgument(); meta_argument->setType(meta_type); meta_argument->setName(arg->name()); meta_argument->setArgumentIndex(i); meta_arguments << meta_argument; } meta_function->setArguments(meta_arguments); // Find the correct default values for (int i=0; i<arguments.size(); ++i) { ArgumentModelItem arg = arguments.at(i); AbstractMetaArgument *meta_arg = meta_arguments.at(i); if (arg->defaultValue()) { QString expr = arg->defaultValueExpression(); if (!expr.isEmpty()) meta_arg->setOriginalDefaultValueExpression(expr); expr = translateDefaultValue(arg, meta_arg->type(), meta_function, m_current_class, i); if (expr.isEmpty()) { first_default_argument = i; } else { meta_arg->setDefaultValueExpression(expr); } if (meta_arg->type()->isEnum() || meta_arg->type()->isFlags()) { m_enum_default_arguments << QPair<AbstractMetaArgument *, AbstractMetaFunction *>(meta_arg, meta_function); } } } // If we where not able to translate the default argument make it // reset all default arguments before this one too. for (int i=0; i<first_default_argument; ++i) meta_arguments[i]->setDefaultValueExpression(QString()); if (ReportHandler::debugLevel() == ReportHandler::FullDebug) foreach(AbstractMetaArgument *arg, meta_arguments) ReportHandler::debugFull(" - " + arg->toString()); return meta_function; } AbstractMetaType *AbstractMetaBuilder::translateType(const TypeInfo &_typei, bool *ok, bool resolveType, bool resolveScope) { Q_ASSERT(ok); *ok = true; // 1. Test the type info without resolving typedefs in case this is present in the // type system TypeInfo typei; if (resolveType) { bool ok; AbstractMetaType *t = translateType(_typei, &ok, false, resolveScope); if (t != 0 && ok) return t; } if (!resolveType) typei = _typei; else { // Go through all parts of the current scope (including global namespace) // to resolve typedefs. The parser does not properly resolve typedefs in // the global scope when they are referenced from inside a namespace. // This is a work around to fix this bug since fixing it in resolveType // seemed non-trivial int i = m_scopes.size() - 1; while (i >= 0) { typei = TypeInfo::resolveType(_typei, m_scopes.at(i--)->toItem()); if (typei.qualifiedName().join("::") != _typei.qualifiedName().join("::")) break; } } if (typei.isFunctionPointer()) { *ok = false; return 0; } TypeParser::Info typeInfo = TypeParser::parse(typei.toString()); if (typeInfo.is_busted) { *ok = false; return 0; } // 2. Handle pointers specified as arrays with unspecified size bool array_of_unspecified_size = false; if (typeInfo.arrays.size() > 0) { array_of_unspecified_size = true; for (int i=0; i<typeInfo.arrays.size(); ++i) array_of_unspecified_size = array_of_unspecified_size && typeInfo.arrays.at(i).isEmpty(); if (!array_of_unspecified_size) { TypeInfo newInfo; //newInfo.setArguments(typei.arguments()); newInfo.setIndirections(typei.indirections()); newInfo.setConstant(typei.isConstant()); newInfo.setFunctionPointer(typei.isFunctionPointer()); newInfo.setQualifiedName(typei.qualifiedName()); newInfo.setReference(typei.isReference()); newInfo.setVolatile(typei.isVolatile()); AbstractMetaType *elementType = translateType(newInfo, ok); if (!(*ok)) return 0; for (int i=typeInfo.arrays.size()-1; i>=0; --i) { QString s = typeInfo.arrays.at(i); bool ok; int elems = s.toInt(&ok); if (!ok) return 0; AbstractMetaType *arrayType = createMetaType(); arrayType->setArrayElementCount(elems); arrayType->setArrayElementType(elementType); arrayType->setTypeEntry(new ArrayTypeEntry(elementType->typeEntry())); decideUsagePattern(arrayType); elementType = arrayType; } return elementType; } else { typeInfo.indirections += typeInfo.arrays.size(); } } QStringList qualifier_list = typeInfo.qualified_name; if (qualifier_list.isEmpty()) { ReportHandler::warning(QString("horribly broken type '%1'").arg(_typei.toString())); *ok = false; return 0; } QString qualified_name = qualifier_list.join("::"); QString name = qualifier_list.takeLast(); // 3. Special case 'void' type if (name == "void" && typeInfo.indirections == 0) { return 0; } // 4. Special case QFlags (include instantiation in name) if (qualified_name == "QFlags") qualified_name = typeInfo.toString(); // 5. Try to find the type const TypeEntry *type = TypeDatabase::instance()->findType(qualified_name); // 6. No? Try looking it up as a flags type if (!type) type = TypeDatabase::instance()->findFlagsType(qualified_name); // 7. No? Try looking it up as a container type if (!type) type = TypeDatabase::instance()->findContainerType(name); // 8. No? Check if the current class is a template and this type is one // of the parameters. if (type == 0 && m_current_class != 0) { QList<TypeEntry *> template_args = m_current_class->templateArguments(); foreach (TypeEntry *te, template_args) { if (te->name() == qualified_name) type = te; } } // 9. Try finding the type by prefixing it with the current // context and all baseclasses of the current context if (!type && !TypeDatabase::instance()->isClassRejected(qualified_name) && m_current_class != 0 && resolveScope) { QStringList contexts; contexts.append(m_current_class->qualifiedCppName()); contexts.append(currentScope()->qualifiedName().join("::")); TypeInfo info = typei; bool subclasses_done = false; while (!contexts.isEmpty() && type == 0) { //type = TypeDatabase::instance()->findType(contexts.at(0) + "::" + qualified_name); bool ok; info.setQualifiedName(QStringList() << contexts.at(0) << qualified_name); AbstractMetaType *t = translateType(info, &ok, true, false); if (t != 0 && ok) return t; ClassModelItem item = m_dom->findClass(contexts.at(0)); if (item != 0) contexts += item->baseClasses(); contexts.pop_front(); // 10. Last resort: Special cased prefix of Qt namespace since the meta object implicitly inherits this, so // enum types from there may be addressed without any scope resolution in properties. if (contexts.size() == 0 && !subclasses_done) { contexts << "Qt"; subclasses_done = true; } } } if (!type) { *ok = false; return 0; } // Used to for diagnostics later... m_used_types << type; // These are only implicit and should not appear in code... Q_ASSERT(!type->isInterface()); AbstractMetaType *meta_type = createMetaType(); meta_type->setTypeEntry(type); meta_type->setIndirections(typeInfo.indirections); meta_type->setReference(typeInfo.is_reference); meta_type->setConstant(typeInfo.is_constant); meta_type->setOriginalTypeDescription(_typei.toString()); decideUsagePattern(meta_type); if (meta_type->typeEntry()->isContainer()) { ContainerTypeEntry::Type container_type = static_cast<const ContainerTypeEntry *>(type)->type(); if (container_type == ContainerTypeEntry::StringListContainer) { TypeInfo info; info.setQualifiedName(QStringList() << "QString"); AbstractMetaType *targ_type = translateType(info, ok); Q_ASSERT(*ok); Q_ASSERT(targ_type); meta_type->addInstantiation(targ_type); meta_type->setInstantiationInCpp(false); } else { foreach (const TypeParser::Info &ta, typeInfo.template_instantiations) { TypeInfo info; info.setConstant(ta.is_constant); info.setReference(ta.is_reference); info.setIndirections(ta.indirections); info.setFunctionPointer(false); info.setQualifiedName(ta.instantiationName().split("::")); AbstractMetaType *targ_type = translateType(info, ok); if (!(*ok)) { delete meta_type; return 0; } meta_type->addInstantiation(targ_type); } } if (container_type == ContainerTypeEntry::ListContainer || container_type == ContainerTypeEntry::VectorContainer || container_type == ContainerTypeEntry::StringListContainer) { Q_ASSERT(meta_type->instantiations().size() == 1); } } return meta_type; } void AbstractMetaBuilder::decideUsagePattern(AbstractMetaType *meta_type) { const TypeEntry *type = meta_type->typeEntry(); if (type->isPrimitive() && (meta_type->actualIndirections() == 0 || (meta_type->isConstant() && meta_type->isReference() && meta_type->indirections() == 0))) { meta_type->setTypeUsagePattern(AbstractMetaType::PrimitivePattern); } else if (type->isVoid()) { meta_type->setTypeUsagePattern(AbstractMetaType::NativePointerPattern); } else if (type->isString() && meta_type->indirections() == 0 && (meta_type->isConstant() == meta_type->isReference() || meta_type->isConstant())) { meta_type->setTypeUsagePattern(AbstractMetaType::StringPattern); } else if (type->isChar() && meta_type->indirections() == 0 && meta_type->isConstant() == meta_type->isReference()) { meta_type->setTypeUsagePattern(AbstractMetaType::CharPattern); } else if (type->isJObjectWrapper() && meta_type->indirections() == 0 && meta_type->isConstant() == meta_type->isReference()) { meta_type->setTypeUsagePattern(AbstractMetaType::JObjectWrapperPattern); } else if (type->isVariant() && meta_type->indirections() == 0 && meta_type->isConstant() == meta_type->isReference()) { meta_type->setTypeUsagePattern(AbstractMetaType::VariantPattern); } else if (type->isEnum() && meta_type->actualIndirections() == 0) { meta_type->setTypeUsagePattern(AbstractMetaType::EnumPattern); } else if (type->isObject() && meta_type->indirections() == 0 && meta_type->isReference()) { if (((ComplexTypeEntry *) type)->isQObject()) meta_type->setTypeUsagePattern(AbstractMetaType::QObjectPattern); else meta_type->setTypeUsagePattern(AbstractMetaType::ObjectPattern); } else if (type->isObject() && meta_type->indirections() == 1) { if (((ComplexTypeEntry *) type)->isQObject()) meta_type->setTypeUsagePattern(AbstractMetaType::QObjectPattern); else meta_type->setTypeUsagePattern(AbstractMetaType::ObjectPattern); // const-references to pointers can be passed as pointers if (meta_type->isReference() && meta_type->isConstant()) { meta_type->setReference(false); meta_type->setConstant(false); } } else if (type->isContainer() && meta_type->indirections() == 0) { meta_type->setTypeUsagePattern(AbstractMetaType::ContainerPattern); } else if (type->isTemplateArgument()) { } else if (type->isFlags() && meta_type->indirections() == 0 && (meta_type->isConstant() == meta_type->isReference())) { meta_type->setTypeUsagePattern(AbstractMetaType::FlagsPattern); } else if (type->isArray()) { meta_type->setTypeUsagePattern(AbstractMetaType::ArrayPattern); } else if (type->isThread()) { Q_ASSERT(meta_type->indirections() == 1); meta_type->setTypeUsagePattern(AbstractMetaType::ThreadPattern); } else if (type->isValue() && meta_type->indirections() == 0 && (meta_type->isConstant() == meta_type->isReference() || !meta_type->isReference())) { meta_type->setTypeUsagePattern(AbstractMetaType::ValuePattern); } else if (type->isObject() && meta_type->actualIndirections() == 0) { ReportHandler::warning(QString("Object type '%1' passed as value. Resulting code will not compile.") .arg(meta_type->cppSignature())); meta_type->setTypeUsagePattern(AbstractMetaType::NativePointerPattern); } else { meta_type->setTypeUsagePattern(AbstractMetaType::NativePointerPattern); ReportHandler::debugFull(QString("native pointer pattern for '%1'") .arg(meta_type->cppSignature())); } } QString AbstractMetaBuilder::translateDefaultValue(ArgumentModelItem item, AbstractMetaType *type, AbstractMetaFunction *fnc, AbstractMetaClass *implementing_class, int argument_index) { QString function_name = fnc->name(); QString class_name = implementing_class->name(); QString replaced_expression = fnc->replacedDefaultExpression(implementing_class, argument_index + 1); if (fnc->removedDefaultExpression(implementing_class, argument_index +1)) return ""; if (!replaced_expression.isEmpty()) return replaced_expression; QString expr = item->defaultValueExpression(); if (type->isPrimitive()) { if (type->name() == "boolean") { if (expr == "false" || expr=="true") { return expr; } else { bool ok = false; int number = expr.toInt(&ok); if (ok && number) return "true"; else return "false"; } } else if (expr == "ULONG_MAX") { return "Long.MAX_VALUE"; } else if (expr == "QVariant::Invalid") { return QString::number(QVariant::Invalid); } else { // This can be an enum or flag so I need to delay the // translation untill all namespaces are completly // processed. This is done in figureOutEnumValues() return expr; } } else if (type != 0 && (type->isFlags() || type->isEnum())) { // Same as with enum explanation above... return expr; } else { // constructor or functioncall can be a bit tricky... if (expr == "QVariant()" /* qtd || expr == "QModelIndex()"*/) { return "null"; } else if (expr == "QString()") { return "\"\""; } else if (expr.endsWith(")") && expr.contains("::")) { TypeEntry *typeEntry = TypeDatabase::instance()->findType(expr.left(expr.indexOf("::"))); if (typeEntry) return typeEntry->qualifiedTargetLangName() + "." + expr.right(expr.length() - expr.indexOf("::") - 2); } else if (expr.endsWith(")") && type->isValue()) { int pos = expr.indexOf("("); TypeEntry *typeEntry = TypeDatabase::instance()->findType(expr.left(pos)); if (typeEntry) { // qtd if(typeEntry->isStructInD()) return typeEntry->qualifiedCppName() + expr.right(expr.length() - pos); else return "new " + typeEntry->qualifiedCppName() + expr.right(expr.length() - pos); } else return expr; } else if (expr == "0" || expr == "NULL") { return "null"; } else if (type->isObject() || type->isValue() || expr.contains("::")) { // like Qt::black passed to a QColor TypeEntry *typeEntry = TypeDatabase::instance()->findType(expr.left(expr.indexOf("::"))); expr = expr.right(expr.length() - expr.indexOf("::") - 2); if (typeEntry) { return "new " + type->typeEntry()->qualifiedCppName() + "(" + typeEntry->qualifiedCppName() + "." + expr + ")"; } } } QString warn = QString("unsupported default value '%3' of argument in function '%1', class '%2'") .arg(function_name).arg(class_name).arg(item->defaultValueExpression()); ReportHandler::warning(warn); return QString(); } bool AbstractMetaBuilder::isQObject(const QString &qualified_name) { if (qualified_name == "QObject") return true; ClassModelItem class_item = m_dom->findClass(qualified_name); if (!class_item) { QStringList names = qualified_name.split(QLatin1String("::")); NamespaceModelItem ns = model_dynamic_cast<NamespaceModelItem>(m_dom); for (int i=0; i<names.size() - 1 && ns; ++i) ns = ns->namespaceMap().value(names.at(i)); if (ns && names.size() >= 2) class_item = ns->findClass(names.at(names.size() - 1)); } bool isqobject = class_item && class_item->extendsClass("QObject"); if (class_item && !isqobject) { QStringList baseClasses = class_item->baseClasses(); for (int i=0; i<baseClasses.count(); ++i) { isqobject = isQObject(baseClasses.at(i)); if (isqobject) break; } } return isqobject; } bool AbstractMetaBuilder::isEnum(const QStringList &qualified_name) { CodeModelItem item = m_dom->model()->findItem(qualified_name, m_dom->toItem()); return item && item->kind() == _EnumModelItem::__node_kind; } AbstractMetaType *AbstractMetaBuilder::inheritTemplateType(const QList<AbstractMetaType *> &template_types, AbstractMetaType *meta_type, bool *ok) { if (ok != 0) *ok = true; if (!meta_type || (!meta_type->typeEntry()->isTemplateArgument() && !meta_type->hasInstantiations())) return meta_type ? meta_type->copy() : 0; AbstractMetaType *returned = meta_type->copy(); returned->setOriginalTemplateType(meta_type->copy()); if (returned->typeEntry()->isTemplateArgument()) { const TemplateArgumentEntry *tae = static_cast<const TemplateArgumentEntry *>(returned->typeEntry()); // If the template is intantiated with void we special case this as rejecting the functions that use this // parameter from the instantiation. if (template_types.size() <= tae->ordinal() || template_types.at(tae->ordinal())->typeEntry()->name() == "void") { if (ok != 0) *ok = false; return 0; } AbstractMetaType *t = returned->copy(); t->setTypeEntry(template_types.at(tae->ordinal())->typeEntry()); t->setIndirections(template_types.at(tae->ordinal())->indirections() + t->indirections() ? 1 : 0); decideUsagePattern(t); delete returned; returned = inheritTemplateType(template_types, t, ok); if (ok != 0 && !(*ok)) return 0; } if (returned->hasInstantiations()) { QList<AbstractMetaType *> instantiations = returned->instantiations(); for (int i=0; i<instantiations.count(); ++i) { instantiations[i] = inheritTemplateType(template_types, instantiations.at(i), ok); if (ok != 0 && !(*ok)) return 0; } returned->setInstantiations(instantiations); } return returned; } bool AbstractMetaBuilder::inheritTemplate(AbstractMetaClass *subclass, const AbstractMetaClass *template_class, const TypeParser::Info &info) { QList<TypeParser::Info> targs = info.template_instantiations; QList<AbstractMetaType *> template_types; foreach (const TypeParser::Info &i, targs) { TypeEntry *t = TypeDatabase::instance()->findType(i.qualified_name.join("::")); if (t != 0) { AbstractMetaType *temporary_type = createMetaType(); temporary_type->setTypeEntry(t); temporary_type->setConstant(i.is_constant); temporary_type->setReference(i.is_reference); temporary_type->setIndirections(i.indirections); template_types << temporary_type; } } AbstractMetaFunctionList funcs = subclass->functions(); foreach (const AbstractMetaFunction *function, template_class->functions()) { if (function->isModifiedRemoved(TypeSystem::All)) continue; AbstractMetaFunction *f = function->copy(); f->setArguments(AbstractMetaArgumentList()); bool ok = true; AbstractMetaType *ftype = function->type(); f->setType(inheritTemplateType(template_types, ftype, &ok)); if (!ok) { delete f; continue; } foreach (AbstractMetaArgument *argument, function->arguments()) { AbstractMetaType *atype = argument->type(); AbstractMetaArgument *arg = argument->copy(); arg->setType(inheritTemplateType(template_types, atype, &ok)); if (!ok) break; f->addArgument(arg); } if (!ok) { delete f; continue ; } // There is no base class in java to inherit from here, so the // template instantiation is the class that implements the function.. f->setImplementingClass(subclass); // We also set it as the declaring class, since the superclass is // supposed to disappear. This allows us to make certain function modifications // on the inherited functions. f->setDeclaringClass(subclass); if (f->isConstructor() && subclass->isTypeAlias()) { f->setName(subclass->name()); } else if (f->isConstructor()) { delete f; continue; } // if the instantiation has a function named the same as an existing // function we have shadowing so we need to skip it. bool found = false; for (int i=0; i<funcs.size(); ++i) { if (funcs.at(i)->name() == f->name()) { found = true; continue; } } if (found) { delete f; continue; } ComplexTypeEntry *te = subclass->typeEntry(); FunctionModificationList mods = function->modifications(template_class); for (int i=0; i<mods.size(); ++i) { FunctionModification mod = mods.at(i); mod.signature = f->minimalSignature(); // If we ever need it... Below is the code to do // substitution of the template instantation type inside // injected code.. #if 0 if (mod.modifiers & Modification::CodeInjection) { for (int j=0; j<template_types.size(); ++j) { CodeSnip &snip = mod.snips.last(); QString code = snip.code(); code.replace(QString::fromLatin1("$$QT_TEMPLATE_%1$$").arg(j), template_types.at(j)->typeEntry()->qualifiedCppName()); snip.codeList.clear(); snip.addCode(code); } } #endif te->addFunctionModification(mod); } subclass->addFunction(f); } // Clean up foreach (AbstractMetaType *type, template_types) { delete type; } { subclass->setTemplateBaseClass(template_class); subclass->setInterfaces(template_class->interfaces()); subclass->setBaseClass(template_class->baseClass()); } return true; } void AbstractMetaBuilder::parseQ_Property(AbstractMetaClass *meta_class, const QStringList &declarations) { for (int i=0; i<declarations.size(); ++i) { QString p = declarations.at(i); QStringList l = p.split(QLatin1String(" ")); QStringList qualifiedScopeName = currentScope()->qualifiedName(); bool ok = false; AbstractMetaType *type = 0; QString scope; for (int j=qualifiedScopeName.size(); j>=0; --j) { scope = j > 0 ? QStringList(qualifiedScopeName.mid(0, j)).join("::") + "::" : QString(); TypeInfo info; info.setQualifiedName((scope + l.at(0)).split("::")); type = translateType(info, &ok); if (type != 0 && ok) { break; } } if (type == 0 || !ok) { ReportHandler::warning(QString("Unable to decide type of property: '%1' in class '%2'") .arg(l.at(0)).arg(meta_class->name())); continue; } QString typeName = scope + l.at(0); QPropertySpec *spec = new QPropertySpec(type->typeEntry()); spec->setName(l.at(1)); spec->setIndex(i); for (int pos=2; pos+1<l.size(); pos+=2) { if (l.at(pos) == QLatin1String("READ")) spec->setRead(l.at(pos+1)); else if (l.at(pos) == QLatin1String("WRITE")) spec->setWrite(l.at(pos+1)); else if (l.at(pos) == QLatin1String("DESIGNABLE")) spec->setDesignable(l.at(pos+1)); else if (l.at(pos) == QLatin1String("RESET")) spec->setReset(l.at(pos+1)); } meta_class->addPropertySpec(spec); delete type; } } static void hide_functions(const AbstractMetaFunctionList &l) { foreach (AbstractMetaFunction *f, l) { FunctionModification mod; mod.signature = f->minimalSignature(); mod.modifiers = FunctionModification::Private; ((ComplexTypeEntry *) f->implementingClass()->typeEntry())->addFunctionModification(mod); } } static void remove_function(AbstractMetaFunction *f) { FunctionModification mod; mod.removal = TypeSystem::All; mod.signature = f->minimalSignature(); ((ComplexTypeEntry *) f->implementingClass()->typeEntry())->addFunctionModification(mod); } static AbstractMetaFunctionList filter_functions(const AbstractMetaFunctionList &lst, QSet<QString> *signatures) { AbstractMetaFunctionList functions; foreach (AbstractMetaFunction *f, lst) { QString signature = f->minimalSignature(); int start = signature.indexOf(QLatin1Char('(')) + 1; int end = signature.lastIndexOf(QLatin1Char(')')); signature = signature.mid(start, end - start); if (signatures->contains(signature)) { remove_function(f); continue; } (*signatures) << signature; functions << f; } return functions; } void AbstractMetaBuilder::setupEquals(AbstractMetaClass *cls) { AbstractMetaFunctionList equals; AbstractMetaFunctionList nequals; QString op_equals = QLatin1String("operator_equal"); QString op_nequals = QLatin1String("operator_not_equal"); AbstractMetaFunctionList functions = cls->queryFunctions(AbstractMetaClass::ClassImplements | AbstractMetaClass::NotRemovedFromTargetLang); foreach (AbstractMetaFunction *f, functions) { if (f->name() == op_equals) equals << f; else if (f->name() == op_nequals) nequals << f; } if (equals.size() || nequals.size()) { if (!cls->hasHashFunction()) { ReportHandler::warning(QString::fromLatin1("Class '%1' has equals operators but no qHash() function") .arg(cls->name())); } hide_functions(equals); hide_functions(nequals); // We only need == if we have both == and !=, and one == for // each signature type, like QDateTime::==(QDate) and (QTime) // if such a thing exists... QSet<QString> func_signatures; cls->setEqualsFunctions(filter_functions(equals, &func_signatures)); cls->setNotEqualsFunctions(filter_functions(nequals, &func_signatures)); } } void AbstractMetaBuilder::setupComparable(AbstractMetaClass *cls) { AbstractMetaFunctionList greater; AbstractMetaFunctionList greaterEquals; AbstractMetaFunctionList less; AbstractMetaFunctionList lessEquals; QString op_greater = QLatin1String("operator_greater"); QString op_greater_eq = QLatin1String("operator_greater_or_equal"); QString op_less = QLatin1String("operator_less"); QString op_less_eq = QLatin1String("operator_less_or_equal"); AbstractMetaFunctionList functions = cls->queryFunctions(AbstractMetaClass::ClassImplements | AbstractMetaClass::NotRemovedFromTargetLang); foreach (AbstractMetaFunction *f, functions) { if (f->name() == op_greater) greater << f; else if (f->name() == op_greater_eq) greaterEquals << f; else if (f->name() == op_less) less << f; else if (f->name() == op_less_eq) lessEquals << f; } bool hasEquals = cls->equalsFunctions().size() || cls->notEqualsFunctions().size(); // Conditions for comparable is: // >, ==, < - The basic case // >, == - Less than becomes else case // <, == - Greater than becomes else case // >=, <= - if (<= && >=) -> equal bool mightBeComparable = greater.size() || greaterEquals.size() || less.size() || lessEquals.size() || greaterEquals.size() == 1 || lessEquals.size() == 1; if (mightBeComparable) { QSet<QString> signatures; // We only hide the original functions if we are able to make a compareTo() method bool wasComparable = false; // The three upper cases, prefer the <, == approach if (hasEquals && (greater.size() || less.size())) { cls->setLessThanFunctions(filter_functions(less, &signatures)); cls->setGreaterThanFunctions(filter_functions(greater, &signatures)); filter_functions(greaterEquals, &signatures); filter_functions(lessEquals, &signatures); wasComparable = true; } else if (hasEquals && (greaterEquals.size() || lessEquals.size())) { cls->setLessThanEqFunctions(filter_functions(lessEquals, &signatures)); cls->setGreaterThanEqFunctions(filter_functions(greaterEquals, &signatures)); wasComparable = true; } else if (greaterEquals.size() == 1 || lessEquals.size() == 1) { cls->setGreaterThanEqFunctions(greaterEquals); cls->setLessThanEqFunctions(lessEquals); filter_functions(less, &signatures); filter_functions(greater, &signatures); wasComparable = true; } if (wasComparable) { hide_functions(greater); hide_functions(greaterEquals); hide_functions(less); hide_functions(lessEquals); } } } void AbstractMetaBuilder::setupClonable(AbstractMetaClass *cls) { // All value types are required to have a copy constructor, // or they will not work as value types (it won't even compile, // because of calls to qRegisterMetaType(). Thus all value types // should be cloneable. if (cls->typeEntry()->isValue()) { cls->setHasCloneOperator(true); return; } else { QString op_assign = QLatin1String("operator_assign"); AbstractMetaFunctionList functions = cls->queryFunctions(AbstractMetaClass::ClassImplements); foreach (AbstractMetaFunction *f, functions) { if ((f->name() == op_assign || f->isConstructor()) && f->isPublic()) { AbstractMetaArgumentList arguments = f->arguments(); if (f->actualMinimumArgumentCount() == 1) { if (cls->typeEntry()->qualifiedCppName() == arguments.at(0)->type()->typeEntry()->qualifiedCppName()) { if (cls->typeEntry()->isValue()) { cls->setHasCloneOperator(true); return; } } } } } } } static void write_reject_log_file(const QString &name, const QMap<QString, AbstractMetaBuilder::RejectReason> &rejects) { QFile f(name); if (!f.open(QIODevice::WriteOnly | QIODevice::Text)) { ReportHandler::warning(QString("failed to write log file: '%1'") .arg(f.fileName())); return; } QTextStream s(&f); for (int reason=0; reason<AbstractMetaBuilder::NoReason; ++reason) { s << QString(72, '*') << endl; switch (reason) { case AbstractMetaBuilder::NotInTypeSystem: s << "Not in type system"; break; case AbstractMetaBuilder::GenerationDisabled: s << "Generation disabled by type system"; break; case AbstractMetaBuilder::RedefinedToNotClass: s << "Type redefined to not be a class"; break; case AbstractMetaBuilder::UnmatchedReturnType: s << "Unmatched return type"; break; case AbstractMetaBuilder::UnmatchedArgumentType: s << "Unmatched argument type"; break; default: s << "unknown reason"; break; } s << endl; for (QMap<QString, AbstractMetaBuilder::RejectReason>::const_iterator it = rejects.constBegin(); it != rejects.constEnd(); ++it) { if (it.value() != reason) continue; s << " - " << it.key() << endl; } s << QString(72, '*') << endl << endl; } } void AbstractMetaBuilder::dumpLog() { write_reject_log_file("mjb_rejected_classes.log", m_rejected_classes); write_reject_log_file("mjb_rejected_enums.log", m_rejected_enums); write_reject_log_file("mjb_rejected_functions.log", m_rejected_functions); write_reject_log_file("mjb_rejected_fields.log", m_rejected_fields); } AbstractMetaClassList AbstractMetaBuilder::classesTopologicalSorted() const { AbstractMetaClassList res; AbstractMetaClassList classes = m_meta_classes; qSort(classes); QSet<AbstractMetaClass*> noDependency; QHash<AbstractMetaClass*, QSet<AbstractMetaClass* >* > hash; foreach (AbstractMetaClass *cls, classes) { QSet<AbstractMetaClass* > *depends = new QSet<AbstractMetaClass* >(); if (cls->baseClass()) depends->insert(cls->baseClass()); foreach (AbstractMetaClass *interface, cls->interfaces()) { depends->insert(interface); } if (depends->empty()) { noDependency.insert(cls); } else { hash.insert(cls, depends); } } while (!noDependency.empty()) { foreach (AbstractMetaClass *cls, noDependency.values()) { if(!cls->isInterface()) res.append(cls); noDependency.remove(cls); QHashIterator<AbstractMetaClass*, QSet<AbstractMetaClass* >* > i(hash); while (i.hasNext()) { i.next(); i.value()->remove(cls); if (i.value()->empty()) { AbstractMetaClass *key = i.key(); noDependency.insert(key); hash.remove(key); delete(i.value()); } } } } if (!noDependency.empty() || !hash.empty()) { qWarning("dependency graph was cyclic."); } return res; }