/**************************************************************************** ** ** Copyright (C) 2012 Nokia Corporation and/or its subsidiary(-ies). ** Contact: http://www.qt-project.org/ ** ** This file is part of the tools applications of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and Digia. For licensing terms and ** conditions see http://qt.digia.com/licensing. For further information ** use the contact form at http://qt.digia.com/contact-us. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Digia gives you certain additional ** rights. These rights are described in the Digia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 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 the GNU General Public License version 3.0 requirements will be ** met: http://www.gnu.org/copyleft/gpl.html. ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "generator.h" #include "outputrevision.h" #include "utils.h" #include #include #include #include #include #include #include #include //for the flags. QT_BEGIN_NAMESPACE uint nameToBuiltinType(const QByteArray &name) { if (name.isEmpty()) return 0; uint tp = QMetaType::type(name.constData()); return tp < uint(QMetaType::User) ? tp : uint(QMetaType::UnknownType); } /* Returns true if the type is a built-in type. */ bool isBuiltinType(const QByteArray &type) { int id = QMetaType::type(type.constData()); if (id == QMetaType::UnknownType) return false; return (id < QMetaType::User); } static const char *metaTypeEnumValueString(int type) { #define RETURN_METATYPENAME_STRING(MetaTypeName, MetaTypeId, RealType) \ case QMetaType::MetaTypeName: return #MetaTypeName; switch (type) { QT_FOR_EACH_STATIC_TYPE(RETURN_METATYPENAME_STRING) } #undef RETURN_METATYPENAME_STRING return 0; } Generator::Generator(ClassDef *classDef, const QList &metaTypes, const QSet &knownQObjectClasses, FILE *outfile) : out(outfile), cdef(classDef), metaTypes(metaTypes), knownQObjectClasses(knownQObjectClasses) { if (cdef->superclassList.size()) purestSuperClass = cdef->superclassList.first().first; } static inline int lengthOfEscapeSequence(const QByteArray &s, int i) { if (s.at(i) != '\\' || i >= s.length() - 1) return 1; const int startPos = i; ++i; char ch = s.at(i); if (ch == 'x') { ++i; while (i < s.length() && is_hex_char(s.at(i))) ++i; } else if (is_octal_char(ch)) { while (i < startPos + 4 && i < s.length() && is_octal_char(s.at(i))) { ++i; } } else { // single character escape sequence i = qMin(i + 1, s.length()); } return i - startPos; } void Generator::strreg(const QByteArray &s) { if (!strings.contains(s)) strings.append(s); } int Generator::stridx(const QByteArray &s) { int i = strings.indexOf(s); Q_ASSERT_X(i != -1, Q_FUNC_INFO, "We forgot to register some strings"); return i; } // Returns the sum of all parameters (including return type) for the given // \a list of methods. This is needed for calculating the size of the methods' // parameter type/name meta-data. static int aggregateParameterCount(const QList &list) { int sum = 0; for (int i = 0; i < list.count(); ++i) sum += list.at(i).arguments.count() + 1; // +1 for return type return sum; } bool Generator::registerableMetaType(const QByteArray &propertyType) { if (metaTypes.contains(propertyType)) return true; if (propertyType.endsWith('*')) { QByteArray objectPointerType = propertyType; // The objects container stores class names, such as 'QState', 'QLabel' etc, // not 'QState*', 'QLabel*'. The propertyType does contain the '*', so we need // to chop it to find the class type in the known QObjects list. objectPointerType.chop(1); if (knownQObjectClasses.contains(objectPointerType)) return true; } static const QVector smartPointers = QVector() #define STREAM_SMART_POINTER(SMART_POINTER) << #SMART_POINTER QT_FOR_EACH_AUTOMATIC_TEMPLATE_SMART_POINTER(STREAM_SMART_POINTER) #undef STREAM_SMART_POINTER ; foreach (const QByteArray &smartPointer, smartPointers) if (propertyType.startsWith(smartPointer + "<") && !propertyType.endsWith("&")) return knownQObjectClasses.contains(propertyType.mid(smartPointer.size() + 1, propertyType.size() - smartPointer.size() - 1 - 1)); static const QVector oneArgTemplates = QVector() #define STREAM_1ARG_TEMPLATE(TEMPLATENAME) << #TEMPLATENAME QT_FOR_EACH_AUTOMATIC_TEMPLATE_1ARG(STREAM_1ARG_TEMPLATE) #undef STREAM_1ARG_TEMPLATE ; foreach (const QByteArray &oneArgTemplateType, oneArgTemplates) if (propertyType.startsWith(oneArgTemplateType + "<") && !propertyType.endsWith("&")) { const int argumentSize = propertyType.size() - oneArgTemplateType.size() - 1 // The closing '>' - 1 // templates inside templates have an extra whitespace char to strip. - (propertyType.at(propertyType.size() - 2) == '>' ? 1 : 0 ); const QByteArray templateArg = propertyType.mid(oneArgTemplateType.size() + 1, argumentSize); return isBuiltinType(templateArg) || registerableMetaType(templateArg); } return false; } void Generator::generateCode() { bool isQt = (cdef->classname == "Qt"); bool isQObject = (cdef->classname == "QObject"); bool isConstructible = !cdef->constructorList.isEmpty(); // filter out undeclared enumerators and sets { QList enumList; for (int i = 0; i < cdef->enumList.count(); ++i) { EnumDef def = cdef->enumList.at(i); if (cdef->enumDeclarations.contains(def.name)) { enumList += def; } QByteArray alias = cdef->flagAliases.value(def.name); if (cdef->enumDeclarations.contains(alias)) { def.name = alias; enumList += def; } } cdef->enumList = enumList; } // // Register all strings used in data section // strreg(cdef->qualified); registerClassInfoStrings(); registerFunctionStrings(cdef->signalList); registerFunctionStrings(cdef->slotList); registerFunctionStrings(cdef->methodList); registerFunctionStrings(cdef->constructorList); registerPropertyStrings(); registerEnumStrings(); QByteArray qualifiedClassNameIdentifier = cdef->qualified; qualifiedClassNameIdentifier.replace(':', '_'); // // Build stringdata struct // fprintf(out, "struct qt_meta_stringdata_%s_t {\n", qualifiedClassNameIdentifier.constData()); fprintf(out, " QByteArrayData data[%d];\n", strings.size()); { int len = 0; for (int i = 0; i < strings.size(); ++i) len += strings.at(i).length() + 1; fprintf(out, " char stringdata[%d];\n", len + 1); } fprintf(out, "};\n"); // Macro that expands into a QByteArrayData. The offset member is // calculated from 1) the offset of the actual characters in the // stringdata.stringdata member, and 2) the stringdata.data index of the // QByteArrayData being defined. This calculation relies on the // QByteArrayData::data() implementation returning simply "this + offset". fprintf(out, "#define QT_MOC_LITERAL(idx, ofs, len) \\\n" " Q_STATIC_BYTE_ARRAY_DATA_HEADER_INITIALIZER_WITH_OFFSET(len, \\\n" " offsetof(qt_meta_stringdata_%s_t, stringdata) + ofs \\\n" " - idx * sizeof(QByteArrayData) \\\n" " )\n", qualifiedClassNameIdentifier.constData()); fprintf(out, "static const qt_meta_stringdata_%s_t qt_meta_stringdata_%s = {\n", qualifiedClassNameIdentifier.constData(), qualifiedClassNameIdentifier.constData()); fprintf(out, " {\n"); { int idx = 0; for (int i = 0; i < strings.size(); ++i) { if (i) fprintf(out, ",\n"); const QByteArray &str = strings.at(i); fprintf(out, "QT_MOC_LITERAL(%d, %d, %d)", i, idx, str.length()); idx += str.length() + 1; for (int j = 0; j < str.length(); ++j) { if (str.at(j) == '\\') { int cnt = lengthOfEscapeSequence(str, j) - 1; idx -= cnt; j += cnt; } } } fprintf(out, "\n },\n"); } // // Build stringdata array // fprintf(out, " \""); int col = 0; int len = 0; for (int i = 0; i < strings.size(); ++i) { QByteArray s = strings.at(i); len = s.length(); if (col && col + len >= 72) { fprintf(out, "\"\n \""); col = 0; } else if (len && s.at(0) >= '0' && s.at(0) <= '9') { fprintf(out, "\"\""); len += 2; } int idx = 0; while (idx < s.length()) { if (idx > 0) { col = 0; fprintf(out, "\"\n \""); } int spanLen = qMin(70, s.length() - idx); // don't cut escape sequences at the end of a line int backSlashPos = s.lastIndexOf('\\', idx + spanLen - 1); if (backSlashPos >= idx) { int escapeLen = lengthOfEscapeSequence(s, backSlashPos); spanLen = qBound(spanLen, backSlashPos + escapeLen - idx, s.length() - idx); } fwrite(s.constData() + idx, 1, spanLen, out); idx += spanLen; col += spanLen; } fputs("\\0", out); col += len + 2; } // Terminate stringdata struct fprintf(out, "\"\n};\n"); fprintf(out, "#undef QT_MOC_LITERAL\n\n"); // // build the data array // int index = MetaObjectPrivateFieldCount; fprintf(out, "static const uint qt_meta_data_%s[] = {\n", qualifiedClassNameIdentifier.constData()); fprintf(out, "\n // content:\n"); fprintf(out, " %4d, // revision\n", int(QMetaObjectPrivate::OutputRevision)); fprintf(out, " %4d, // classname\n", stridx(cdef->qualified)); fprintf(out, " %4d, %4d, // classinfo\n", cdef->classInfoList.count(), cdef->classInfoList.count() ? index : 0); index += cdef->classInfoList.count() * 2; int methodCount = cdef->signalList.count() + cdef->slotList.count() + cdef->methodList.count(); fprintf(out, " %4d, %4d, // methods\n", methodCount, methodCount ? index : 0); index += methodCount * 5; if (cdef->revisionedMethods) index += methodCount; int paramsIndex = index; int totalParameterCount = aggregateParameterCount(cdef->signalList) + aggregateParameterCount(cdef->slotList) + aggregateParameterCount(cdef->methodList) + aggregateParameterCount(cdef->constructorList); index += totalParameterCount * 2 // types and parameter names - methodCount // return "parameters" don't have names - cdef->constructorList.count(); // "this" parameters don't have names fprintf(out, " %4d, %4d, // properties\n", cdef->propertyList.count(), cdef->propertyList.count() ? index : 0); index += cdef->propertyList.count() * 3; if(cdef->notifyableProperties) index += cdef->propertyList.count(); if (cdef->revisionedProperties) index += cdef->propertyList.count(); fprintf(out, " %4d, %4d, // enums/sets\n", cdef->enumList.count(), cdef->enumList.count() ? index : 0); int enumsIndex = index; for (int i = 0; i < cdef->enumList.count(); ++i) index += 4 + (cdef->enumList.at(i).values.count() * 2); fprintf(out, " %4d, %4d, // constructors\n", isConstructible ? cdef->constructorList.count() : 0, isConstructible ? index : 0); fprintf(out, " %4d, // flags\n", 0); fprintf(out, " %4d, // signalCount\n", cdef->signalList.count()); // // Build classinfo array // generateClassInfos(); // // Build signals array first, otherwise the signal indices would be wrong // generateFunctions(cdef->signalList, "signal", MethodSignal, paramsIndex); // // Build slots array // generateFunctions(cdef->slotList, "slot", MethodSlot, paramsIndex); // // Build method array // generateFunctions(cdef->methodList, "method", MethodMethod, paramsIndex); // // Build method version arrays // if (cdef->revisionedMethods) { generateFunctionRevisions(cdef->signalList, "signal"); generateFunctionRevisions(cdef->slotList, "slot"); generateFunctionRevisions(cdef->methodList, "method"); } // // Build method parameters array // generateFunctionParameters(cdef->signalList, "signal"); generateFunctionParameters(cdef->slotList, "slot"); generateFunctionParameters(cdef->methodList, "method"); if (isConstructible) generateFunctionParameters(cdef->constructorList, "constructor"); // // Build property array // generateProperties(); // // Build enums array // generateEnums(enumsIndex); // // Build constructors array // if (isConstructible) generateFunctions(cdef->constructorList, "constructor", MethodConstructor, paramsIndex); // // Terminate data array // fprintf(out, "\n 0 // eod\n};\n\n"); // // Generate internal qt_static_metacall() function // if (cdef->hasQObject && !isQt) generateStaticMetacall(); // // Build extra array // QList extraList; for (int i = 0; i < cdef->propertyList.count(); ++i) { const PropertyDef &p = cdef->propertyList.at(i); if (!isBuiltinType(p.type) && !metaTypes.contains(p.type) && !p.type.contains('*') && !p.type.contains('<') && !p.type.contains('>')) { int s = p.type.lastIndexOf("::"); if (s > 0) { QByteArray scope = p.type.left(s); if (scope != "Qt" && scope != cdef->classname && !extraList.contains(scope)) extraList += scope; } } } // QTBUG-20639 - Accept non-local enums for QML signal/slot parameters. // Look for any scoped enum declarations, and add those to the list // of extra/related metaobjects for this object. QList enumKeys = cdef->enumDeclarations.keys(); for (int i = 0; i < enumKeys.count(); ++i) { const QByteArray &enumKey = enumKeys[i]; int s = enumKey.lastIndexOf("::"); if (s > 0) { QByteArray scope = enumKey.left(s); if (scope != "Qt" && scope != cdef->classname && !extraList.contains(scope)) extraList += scope; } } if (!extraList.isEmpty()) { fprintf(out, "static const QMetaObject *qt_meta_extradata_%s[] = {\n ", qualifiedClassNameIdentifier.constData()); for (int i = 0; i < extraList.count(); ++i) { fprintf(out, " &%s::staticMetaObject,\n", extraList.at(i).constData()); } fprintf(out, " 0\n};\n\n"); } // // Finally create and initialize the static meta object // if (isQt) fprintf(out, "const QMetaObject QObject::staticQtMetaObject = {\n"); else fprintf(out, "const QMetaObject %s::staticMetaObject = {\n", cdef->qualified.constData()); if (isQObject) fprintf(out, " { 0, "); else if (cdef->superclassList.size()) fprintf(out, " { &%s::staticMetaObject, ", purestSuperClass.constData()); else fprintf(out, " { 0, "); fprintf(out, "qt_meta_stringdata_%s.data,\n" " qt_meta_data_%s, ", qualifiedClassNameIdentifier.constData(), qualifiedClassNameIdentifier.constData()); if (cdef->hasQObject && !isQt) fprintf(out, " qt_static_metacall, "); else fprintf(out, " 0, "); if (extraList.isEmpty()) fprintf(out, "0, "); else fprintf(out, "qt_meta_extradata_%s, ", qualifiedClassNameIdentifier.constData()); fprintf(out, "0}\n};\n\n"); if(isQt) return; if (!cdef->hasQObject) return; fprintf(out, "\nconst QMetaObject *%s::metaObject() const\n{\n return QObject::d_ptr->metaObject ? QObject::d_ptr->dynamicMetaObject() : &staticMetaObject;\n}\n", cdef->qualified.constData()); // // Generate smart cast function // fprintf(out, "\nvoid *%s::qt_metacast(const char *_clname)\n{\n", cdef->qualified.constData()); fprintf(out, " if (!_clname) return 0;\n"); fprintf(out, " if (!strcmp(_clname, qt_meta_stringdata_%s.stringdata))\n" " return static_cast(const_cast< %s*>(this));\n", qualifiedClassNameIdentifier.constData(), cdef->classname.constData()); for (int i = 1; i < cdef->superclassList.size(); ++i) { // for all superclasses but the first one if (cdef->superclassList.at(i).second == FunctionDef::Private) continue; const char *cname = cdef->superclassList.at(i).first.constData(); fprintf(out, " if (!strcmp(_clname, \"%s\"))\n return static_cast< %s*>(const_cast< %s*>(this));\n", cname, cname, cdef->classname.constData()); } for (int i = 0; i < cdef->interfaceList.size(); ++i) { const QList &iface = cdef->interfaceList.at(i); for (int j = 0; j < iface.size(); ++j) { fprintf(out, " if (!strcmp(_clname, %s))\n return ", iface.at(j).interfaceId.constData()); for (int k = j; k >= 0; --k) fprintf(out, "static_cast< %s*>(", iface.at(k).className.constData()); fprintf(out, "const_cast< %s*>(this)%s;\n", cdef->classname.constData(), QByteArray(j+1, ')').constData()); } } if (!purestSuperClass.isEmpty() && !isQObject) { QByteArray superClass = purestSuperClass; // workaround for VC6 if (superClass.contains("::")) { fprintf(out, " typedef %s QMocSuperClass;\n", superClass.constData()); superClass = "QMocSuperClass"; } fprintf(out, " return %s::qt_metacast(_clname);\n", superClass.constData()); } else { fprintf(out, " return 0;\n"); } fprintf(out, "}\n"); // // Generate internal qt_metacall() function // generateMetacall(); // // Generate internal signal functions // for (int signalindex = 0; signalindex < cdef->signalList.size(); ++signalindex) generateSignal(&cdef->signalList[signalindex], signalindex); // // Generate plugin meta data // generatePluginMetaData(); } void Generator::registerClassInfoStrings() { for (int i = 0; i < cdef->classInfoList.size(); ++i) { const ClassInfoDef &c = cdef->classInfoList.at(i); strreg(c.name); strreg(c.value); } } void Generator::generateClassInfos() { if (cdef->classInfoList.isEmpty()) return; fprintf(out, "\n // classinfo: key, value\n"); for (int i = 0; i < cdef->classInfoList.size(); ++i) { const ClassInfoDef &c = cdef->classInfoList.at(i); fprintf(out, " %4d, %4d,\n", stridx(c.name), stridx(c.value)); } } void Generator::registerFunctionStrings(const QList& list) { for (int i = 0; i < list.count(); ++i) { const FunctionDef &f = list.at(i); strreg(f.name); if (!isBuiltinType(f.normalizedType)) strreg(f.normalizedType); strreg(f.tag); int argsCount = f.arguments.count(); for (int j = 0; j < argsCount; ++j) { const ArgumentDef &a = f.arguments.at(j); if (!isBuiltinType(a.normalizedType)) strreg(a.normalizedType); strreg(a.name); } } } void Generator::generateFunctions(const QList& list, const char *functype, int type, int ¶msIndex) { if (list.isEmpty()) return; fprintf(out, "\n // %ss: name, argc, parameters, tag, flags\n", functype); for (int i = 0; i < list.count(); ++i) { const FunctionDef &f = list.at(i); unsigned char flags = type; if (f.access == FunctionDef::Private) flags |= AccessPrivate; else if (f.access == FunctionDef::Public) flags |= AccessPublic; else if (f.access == FunctionDef::Protected) flags |= AccessProtected; if (f.access == FunctionDef::Private) flags |= AccessPrivate; else if (f.access == FunctionDef::Public) flags |= AccessPublic; else if (f.access == FunctionDef::Protected) flags |= AccessProtected; if (f.isCompat) flags |= MethodCompatibility; if (f.wasCloned) flags |= MethodCloned; if (f.isScriptable) flags |= MethodScriptable; if (f.revision > 0) flags |= MethodRevisioned; int argc = f.arguments.count(); fprintf(out, " %4d, %4d, %4d, %4d, 0x%02x,\n", stridx(f.name), argc, paramsIndex, stridx(f.tag), flags); paramsIndex += 1 + argc * 2; } } void Generator::generateFunctionRevisions(const QList& list, const char *functype) { if (list.count()) fprintf(out, "\n // %ss: revision\n", functype); for (int i = 0; i < list.count(); ++i) { const FunctionDef &f = list.at(i); fprintf(out, " %4d,\n", f.revision); } } void Generator::generateFunctionParameters(const QList& list, const char *functype) { if (list.isEmpty()) return; fprintf(out, "\n // %ss: parameters\n", functype); for (int i = 0; i < list.count(); ++i) { const FunctionDef &f = list.at(i); fprintf(out, " "); // Types int argsCount = f.arguments.count(); for (int j = -1; j < argsCount; ++j) { if (j > -1) fputc(' ', out); const QByteArray &typeName = (j < 0) ? f.normalizedType : f.arguments.at(j).normalizedType; generateTypeInfo(typeName, /*allowEmptyName=*/f.isConstructor); fputc(',', out); } // Parameter names for (int j = 0; j < argsCount; ++j) { const ArgumentDef &arg = f.arguments.at(j); fprintf(out, " %4d,", stridx(arg.name)); } fprintf(out, "\n"); } } void Generator::generateTypeInfo(const QByteArray &typeName, bool allowEmptyName) { Q_UNUSED(allowEmptyName); if (isBuiltinType(typeName)) { int type; const char *valueString; if (typeName == "qreal") { type = QMetaType::UnknownType; valueString = "QReal"; } else { type = nameToBuiltinType(typeName); valueString = metaTypeEnumValueString(type); } if (valueString) { fprintf(out, "QMetaType::%s", valueString); } else { Q_ASSERT(type != QMetaType::UnknownType); fprintf(out, "%4d", type); } } else { Q_ASSERT(!typeName.isEmpty() || allowEmptyName); fprintf(out, "0x%.8x | %d", IsUnresolvedType, stridx(typeName)); } } void Generator::registerPropertyStrings() { for (int i = 0; i < cdef->propertyList.count(); ++i) { const PropertyDef &p = cdef->propertyList.at(i); strreg(p.name); if (!isBuiltinType(p.type)) strreg(p.type); } } void Generator::generateProperties() { // // Create meta data // if (cdef->propertyList.count()) fprintf(out, "\n // properties: name, type, flags\n"); for (int i = 0; i < cdef->propertyList.count(); ++i) { const PropertyDef &p = cdef->propertyList.at(i); uint flags = Invalid; if (!isBuiltinType(p.type)) flags |= EnumOrFlag; if (!p.read.isEmpty()) flags |= Readable; if (!p.write.isEmpty()) { flags |= Writable; if (p.stdCppSet()) flags |= StdCppSet; } if (!p.reset.isEmpty()) flags |= Resettable; // if (p.override) // flags |= Override; if (p.designable.isEmpty()) flags |= ResolveDesignable; else if (p.designable != "false") flags |= Designable; if (p.scriptable.isEmpty()) flags |= ResolveScriptable; else if (p.scriptable != "false") flags |= Scriptable; if (p.stored.isEmpty()) flags |= ResolveStored; else if (p.stored != "false") flags |= Stored; if (p.editable.isEmpty()) flags |= ResolveEditable; else if (p.editable != "false") flags |= Editable; if (p.user.isEmpty()) flags |= ResolveUser; else if (p.user != "false") flags |= User; if (p.notifyId != -1) flags |= Notify; if (p.revision > 0) flags |= Revisioned; if (p.constant) flags |= Constant; if (p.final) flags |= Final; fprintf(out, " %4d, ", stridx(p.name)); generateTypeInfo(p.type); fprintf(out, ", 0x%.8x,\n", flags); } if(cdef->notifyableProperties) { fprintf(out, "\n // properties: notify_signal_id\n"); for (int i = 0; i < cdef->propertyList.count(); ++i) { const PropertyDef &p = cdef->propertyList.at(i); if(p.notifyId == -1) fprintf(out, " %4d,\n", 0); else fprintf(out, " %4d,\n", p.notifyId); } } if (cdef->revisionedProperties) { fprintf(out, "\n // properties: revision\n"); for (int i = 0; i < cdef->propertyList.count(); ++i) { const PropertyDef &p = cdef->propertyList.at(i); fprintf(out, " %4d,\n", p.revision); } } } void Generator::registerEnumStrings() { for (int i = 0; i < cdef->enumList.count(); ++i) { const EnumDef &e = cdef->enumList.at(i); strreg(e.name); for (int j = 0; j < e.values.count(); ++j) strreg(e.values.at(j)); } } void Generator::generateEnums(int index) { if (cdef->enumDeclarations.isEmpty()) return; fprintf(out, "\n // enums: name, flags, count, data\n"); index += 4 * cdef->enumList.count(); int i; for (i = 0; i < cdef->enumList.count(); ++i) { const EnumDef &e = cdef->enumList.at(i); fprintf(out, " %4d, 0x%.1x, %4d, %4d,\n", stridx(e.name), cdef->enumDeclarations.value(e.name) ? 1 : 0, e.values.count(), index); index += e.values.count() * 2; } fprintf(out, "\n // enum data: key, value\n"); for (i = 0; i < cdef->enumList.count(); ++i) { const EnumDef &e = cdef->enumList.at(i); for (int j = 0; j < e.values.count(); ++j) { const QByteArray &val = e.values.at(j); QByteArray code = cdef->qualified.constData(); if (e.isEnumClass) code += "::" + e.name; code += "::" + val; fprintf(out, " %4d, uint(%s),\n", stridx(val), code.constData()); } } } void Generator::generateMetacall() { bool isQObject = (cdef->classname == "QObject"); fprintf(out, "\nint %s::qt_metacall(QMetaObject::Call _c, int _id, void **_a)\n{\n", cdef->qualified.constData()); if (!purestSuperClass.isEmpty() && !isQObject) { QByteArray superClass = purestSuperClass; // workaround for VC6 if (superClass.contains("::")) { fprintf(out, " typedef %s QMocSuperClass;\n", superClass.constData()); superClass = "QMocSuperClass"; } fprintf(out, " _id = %s::qt_metacall(_c, _id, _a);\n", superClass.constData()); } fprintf(out, " if (_id < 0)\n return _id;\n"); fprintf(out, " "); bool needElse = false; QList methodList; methodList += cdef->signalList; methodList += cdef->slotList; methodList += cdef->methodList; if (methodList.size()) { needElse = true; fprintf(out, "if (_c == QMetaObject::InvokeMetaMethod) {\n"); fprintf(out, " if (_id < %d)\n", methodList.size()); fprintf(out, " qt_static_metacall(this, _c, _id, _a);\n"); fprintf(out, " _id -= %d;\n }", methodList.size()); fprintf(out, " else if (_c == QMetaObject::RegisterMethodArgumentMetaType) {\n"); fprintf(out, " if (_id < %d)\n", methodList.size()); if (methodsWithAutomaticTypesHelper(methodList).isEmpty()) fprintf(out, " *reinterpret_cast(_a[0]) = -1;\n"); else fprintf(out, " qt_static_metacall(this, _c, _id, _a);\n"); fprintf(out, " _id -= %d;\n }", methodList.size()); } if (cdef->propertyList.size()) { bool needGet = false; bool needTempVarForGet = false; bool needSet = false; bool needReset = false; bool needDesignable = false; bool needScriptable = false; bool needStored = false; bool needEditable = false; bool needUser = false; for (int i = 0; i < cdef->propertyList.size(); ++i) { const PropertyDef &p = cdef->propertyList.at(i); needGet |= !p.read.isEmpty(); if (!p.read.isEmpty()) needTempVarForGet |= (p.gspec != PropertyDef::PointerSpec && p.gspec != PropertyDef::ReferenceSpec); needSet |= !p.write.isEmpty(); needReset |= !p.reset.isEmpty(); needDesignable |= p.designable.endsWith(')'); needScriptable |= p.scriptable.endsWith(')'); needStored |= p.stored.endsWith(')'); needEditable |= p.editable.endsWith(')'); needUser |= p.user.endsWith(')'); } fprintf(out, "\n#ifndef QT_NO_PROPERTIES\n "); if (needElse) fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::ReadProperty) {\n"); if (needGet) { if (needTempVarForGet) fprintf(out, " void *_v = _a[0];\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (p.read.isEmpty()) continue; QByteArray prefix; if (p.inPrivateClass.size()) { prefix = p.inPrivateClass; prefix.append("->"); } if (p.gspec == PropertyDef::PointerSpec) fprintf(out, " case %d: _a[0] = const_cast(reinterpret_cast(%s%s())); break;\n", propindex, prefix.constData(), p.read.constData()); else if (p.gspec == PropertyDef::ReferenceSpec) fprintf(out, " case %d: _a[0] = const_cast(reinterpret_cast(&%s%s())); break;\n", propindex, prefix.constData(), p.read.constData()); else if (cdef->enumDeclarations.value(p.type, false)) fprintf(out, " case %d: *reinterpret_cast(_v) = QFlag(%s%s()); break;\n", propindex, prefix.constData(), p.read.constData()); else fprintf(out, " case %d: *reinterpret_cast< %s*>(_v) = %s%s(); break;\n", propindex, p.type.constData(), prefix.constData(), p.read.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::WriteProperty) {\n"); if (needSet) { fprintf(out, " void *_v = _a[0];\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (p.write.isEmpty()) continue; QByteArray prefix; if (p.inPrivateClass.size()) { prefix = p.inPrivateClass; prefix.append("->"); } if (cdef->enumDeclarations.value(p.type, false)) { fprintf(out, " case %d: %s%s(QFlag(*reinterpret_cast(_v))); break;\n", propindex, prefix.constData(), p.write.constData()); } else { fprintf(out, " case %d: %s%s(*reinterpret_cast< %s*>(_v)); break;\n", propindex, prefix.constData(), p.write.constData(), p.type.constData()); } } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::ResetProperty) {\n"); if (needReset) { fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (!p.reset.endsWith(')')) continue; QByteArray prefix; if (p.inPrivateClass.size()) { prefix = p.inPrivateClass; prefix.append("->"); } fprintf(out, " case %d: %s%s; break;\n", propindex, prefix.constData(), p.reset.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::QueryPropertyDesignable) {\n"); if (needDesignable) { fprintf(out, " bool *_b = reinterpret_cast(_a[0]);\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (!p.designable.endsWith(')')) continue; fprintf(out, " case %d: *_b = %s; break;\n", propindex, p.designable.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::QueryPropertyScriptable) {\n"); if (needScriptable) { fprintf(out, " bool *_b = reinterpret_cast(_a[0]);\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (!p.scriptable.endsWith(')')) continue; fprintf(out, " case %d: *_b = %s; break;\n", propindex, p.scriptable.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::QueryPropertyStored) {\n"); if (needStored) { fprintf(out, " bool *_b = reinterpret_cast(_a[0]);\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (!p.stored.endsWith(')')) continue; fprintf(out, " case %d: *_b = %s; break;\n", propindex, p.stored.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::QueryPropertyEditable) {\n"); if (needEditable) { fprintf(out, " bool *_b = reinterpret_cast(_a[0]);\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (!p.editable.endsWith(')')) continue; fprintf(out, " case %d: *_b = %s; break;\n", propindex, p.editable.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::QueryPropertyUser) {\n"); if (needUser) { fprintf(out, " bool *_b = reinterpret_cast(_a[0]);\n"); fprintf(out, " switch (_id) {\n"); for (int propindex = 0; propindex < cdef->propertyList.size(); ++propindex) { const PropertyDef &p = cdef->propertyList.at(propindex); if (!p.user.endsWith(')')) continue; fprintf(out, " case %d: *_b = %s; break;\n", propindex, p.user.constData()); } fprintf(out, " }\n"); } fprintf(out, " _id -= %d;\n" " }", cdef->propertyList.count()); fprintf(out, " else "); fprintf(out, "if (_c == QMetaObject::RegisterPropertyMetaType) {\n"); fprintf(out, " if (_id < %d)\n", cdef->propertyList.size()); if (automaticPropertyMetaTypesHelper().isEmpty()) fprintf(out, " *reinterpret_cast(_a[0]) = -1;\n"); else fprintf(out, " qt_static_metacall(this, _c, _id, _a);\n"); fprintf(out, " _id -= %d;\n }", cdef->propertyList.size()); fprintf(out, "\n#endif // QT_NO_PROPERTIES"); } if (methodList.size() || cdef->signalList.size() || cdef->propertyList.size()) fprintf(out, "\n "); fprintf(out,"return _id;\n}\n"); } QMultiMap Generator::automaticPropertyMetaTypesHelper() { QMultiMap automaticPropertyMetaTypes; for (int i = 0; i < cdef->propertyList.size(); ++i) { const QByteArray propertyType = cdef->propertyList.at(i).type; if (registerableMetaType(propertyType) && !isBuiltinType(propertyType)) automaticPropertyMetaTypes.insert(propertyType, i); } return automaticPropertyMetaTypes; } QMap > Generator::methodsWithAutomaticTypesHelper(const QList &methodList) { QMap > methodsWithAutomaticTypes; for (int i = 0; i < methodList.size(); ++i) { const FunctionDef &f = methodList.at(i); for (int j = 0; j < f.arguments.count(); ++j) { const QByteArray argType = f.arguments.at(j).normalizedType; if (registerableMetaType(argType) && !isBuiltinType(argType)) methodsWithAutomaticTypes[i].insert(argType, j); } } return methodsWithAutomaticTypes; } void Generator::generateStaticMetacall() { fprintf(out, "void %s::qt_static_metacall(QObject *_o, QMetaObject::Call _c, int _id, void **_a)\n{\n", cdef->qualified.constData()); bool needElse = false; bool isUsed_a = false; if (!cdef->constructorList.isEmpty()) { fprintf(out, " if (_c == QMetaObject::CreateInstance) {\n"); fprintf(out, " switch (_id) {\n"); for (int ctorindex = 0; ctorindex < cdef->constructorList.count(); ++ctorindex) { fprintf(out, " case %d: { %s *_r = new %s(", ctorindex, cdef->classname.constData(), cdef->classname.constData()); const FunctionDef &f = cdef->constructorList.at(ctorindex); int offset = 1; int argsCount = f.arguments.count(); for (int j = 0; j < argsCount; ++j) { const ArgumentDef &a = f.arguments.at(j); if (j) fprintf(out, ","); fprintf(out, "(*reinterpret_cast< %s>(_a[%d]))", a.typeNameForCast.constData(), offset++); } if (f.isPrivateSignal) { if (argsCount > 0) fprintf(out, ", "); fprintf(out, "%s", QByteArray("QPrivateSignal()").constData()); } fprintf(out, ");\n"); fprintf(out, " if (_a[0]) *reinterpret_cast(_a[0]) = _r; } break;\n"); } fprintf(out, " }\n"); fprintf(out, " }"); needElse = true; isUsed_a = true; } QList methodList; methodList += cdef->signalList; methodList += cdef->slotList; methodList += cdef->methodList; if (!methodList.isEmpty()) { if (needElse) fprintf(out, " else "); else fprintf(out, " "); fprintf(out, "if (_c == QMetaObject::InvokeMetaMethod) {\n"); #ifndef QT_NO_DEBUG fprintf(out, " Q_ASSERT(staticMetaObject.cast(_o));\n"); #endif fprintf(out, " %s *_t = static_cast<%s *>(_o);\n", cdef->classname.constData(), cdef->classname.constData()); fprintf(out, " switch (_id) {\n"); for (int methodindex = 0; methodindex < methodList.size(); ++methodindex) { const FunctionDef &f = methodList.at(methodindex); Q_ASSERT(!f.normalizedType.isEmpty()); fprintf(out, " case %d: ", methodindex); if (f.normalizedType != "void") fprintf(out, "{ %s _r = ", noRef(f.normalizedType).constData()); fprintf(out, "_t->"); if (f.inPrivateClass.size()) fprintf(out, "%s->", f.inPrivateClass.constData()); fprintf(out, "%s(", f.name.constData()); int offset = 1; int argsCount = f.arguments.count(); for (int j = 0; j < argsCount; ++j) { const ArgumentDef &a = f.arguments.at(j); if (j) fprintf(out, ","); fprintf(out, "(*reinterpret_cast< %s>(_a[%d]))",a.typeNameForCast.constData(), offset++); isUsed_a = true; } if (f.isPrivateSignal) { if (argsCount > 0) fprintf(out, ", "); fprintf(out, "%s", "QPrivateSignal()"); } fprintf(out, ");"); if (f.normalizedType != "void") { fprintf(out, "\n if (_a[0]) *reinterpret_cast< %s*>(_a[0]) = _r; } ", noRef(f.normalizedType).constData()); isUsed_a = true; } fprintf(out, " break;\n"); } fprintf(out, " default: ;\n"); fprintf(out, " }\n"); fprintf(out, " }"); needElse = true; QMap > methodsWithAutomaticTypes = methodsWithAutomaticTypesHelper(methodList); if (!methodsWithAutomaticTypes.isEmpty()) { fprintf(out, " else if (_c == QMetaObject::RegisterMethodArgumentMetaType) {\n"); fprintf(out, " switch (_id) {\n"); fprintf(out, " default: *reinterpret_cast(_a[0]) = -1; break;\n"); QMap >::const_iterator it = methodsWithAutomaticTypes.constBegin(); const QMap >::const_iterator end = methodsWithAutomaticTypes.constEnd(); for ( ; it != end; ++it) { fprintf(out, " case %d:\n", it.key()); fprintf(out, " switch (*reinterpret_cast(_a[1])) {\n"); fprintf(out, " default: *reinterpret_cast(_a[0]) = -1; break;\n"); foreach (const QByteArray &key, it->uniqueKeys()) { foreach (int argumentID, it->values(key)) fprintf(out, " case %d:\n", argumentID); fprintf(out, " *reinterpret_cast(_a[0]) = qRegisterMetaType< %s >(); break;\n", key.constData()); } fprintf(out, " }\n"); fprintf(out, " break;\n"); } fprintf(out, " }\n"); fprintf(out, " }"); isUsed_a = true; } } if (!cdef->signalList.isEmpty()) { Q_ASSERT(needElse); // if there is signal, there was method. fprintf(out, " else if (_c == QMetaObject::IndexOfMethod) {\n"); fprintf(out, " int *result = reinterpret_cast(_a[0]);\n"); fprintf(out, " void **func = reinterpret_cast(_a[1]);\n"); bool anythingUsed = false; for (int methodindex = 0; methodindex < cdef->signalList.size(); ++methodindex) { const FunctionDef &f = cdef->signalList.at(methodindex); if (f.wasCloned || !f.inPrivateClass.isEmpty() || f.isStatic) continue; anythingUsed = true; fprintf(out, " {\n"); fprintf(out, " typedef %s (%s::*_t)(",f.type.rawName.constData() , cdef->classname.constData()); int argsCount = f.arguments.count(); for (int j = 0; j < argsCount; ++j) { const ArgumentDef &a = f.arguments.at(j); if (j) fprintf(out, ", "); fprintf(out, "%s", QByteArray(a.type.name + ' ' + a.rightType).constData()); } if (f.isPrivateSignal) { if (argsCount > 0) fprintf(out, ", "); fprintf(out, "%s", "QPrivateSignal"); } if (f.isConst) fprintf(out, ") const;\n"); else fprintf(out, ");\n"); fprintf(out, " if (*reinterpret_cast<_t *>(func) == static_cast<_t>(&%s::%s)) {\n", cdef->classname.constData(), f.name.constData()); fprintf(out, " *result = %d;\n", methodindex); fprintf(out, " }\n }\n"); } if (!anythingUsed) fprintf(out, " Q_UNUSED(result);\n Q_UNUSED(func);\n"); fprintf(out, " }"); needElse = true; } QMultiMap automaticPropertyMetaTypes = automaticPropertyMetaTypesHelper(); if (!automaticPropertyMetaTypes.isEmpty()) { if (needElse) fprintf(out, " else "); else fprintf(out, " "); fprintf(out, "if (_c == QMetaObject::RegisterPropertyMetaType) {\n"); fprintf(out, " switch (_id) {\n"); fprintf(out, " default: *reinterpret_cast(_a[0]) = -1; break;\n"); foreach (const QByteArray &key, automaticPropertyMetaTypes.uniqueKeys()) { foreach (int propertyID, automaticPropertyMetaTypes.values(key)) fprintf(out, " case %d:\n", propertyID); fprintf(out, " *reinterpret_cast(_a[0]) = qRegisterMetaType< %s >(); break;\n", key.constData()); } fprintf(out, " }\n"); fprintf(out, " }\n"); isUsed_a = true; needElse = true; } if (needElse) fprintf(out, "\n"); if (methodList.isEmpty()) { fprintf(out, " Q_UNUSED(_o);\n"); if (cdef->constructorList.isEmpty() && automaticPropertyMetaTypes.isEmpty() && methodsWithAutomaticTypesHelper(methodList).isEmpty()) { fprintf(out, " Q_UNUSED(_id);\n"); fprintf(out, " Q_UNUSED(_c);\n"); } } if (!isUsed_a) fprintf(out, " Q_UNUSED(_a);\n"); fprintf(out, "}\n\n"); } void Generator::generateSignal(FunctionDef *def,int index) { if (def->wasCloned || def->isAbstract) return; fprintf(out, "\n// SIGNAL %d\n%s %s::%s(", index, def->type.name.constData(), cdef->qualified.constData(), def->name.constData()); QByteArray thisPtr = "this"; const char *constQualifier = ""; if (def->isConst) { thisPtr = "const_cast< "; thisPtr += cdef->qualified; thisPtr += " *>(this)"; constQualifier = "const"; } Q_ASSERT(!def->normalizedType.isEmpty()); if (def->arguments.isEmpty() && def->normalizedType == "void") { if (def->isPrivateSignal) fprintf(out, "QPrivateSignal"); fprintf(out, ")%s\n{\n" " QMetaObject::activate(%s, &staticMetaObject, %d, 0);\n" "}\n", constQualifier, thisPtr.constData(), index); return; } int offset = 1; for (int j = 0; j < def->arguments.count(); ++j) { const ArgumentDef &a = def->arguments.at(j); if (j) fprintf(out, ", "); fprintf(out, "%s _t%d%s", a.type.name.constData(), offset++, a.rightType.constData()); } if (def->isPrivateSignal) { if (!def->arguments.isEmpty()) fprintf(out, ", "); fprintf(out, "QPrivateSignal"); } fprintf(out, ")%s\n{\n", constQualifier); if (def->type.name.size() && def->normalizedType != "void") { QByteArray returnType = noRef(def->normalizedType); if (returnType.endsWith('*')) { fprintf(out, " %s _t0 = 0;\n", returnType.constData()); } else { fprintf(out, " %s _t0 = %s();\n", returnType.constData(), returnType.constData()); } } fprintf(out, " void *_a[] = { "); if (def->normalizedType == "void") { fprintf(out, "0"); } else { if (def->returnTypeIsVolatile) fprintf(out, "const_cast(reinterpret_cast(&_t0))"); else fprintf(out, "const_cast(reinterpret_cast(&_t0))"); } int i; for (i = 1; i < offset; ++i) if (def->arguments.at(i - 1).type.isVolatile) fprintf(out, ", const_cast(reinterpret_cast(&_t%d))", i); else fprintf(out, ", const_cast(reinterpret_cast(&_t%d))", i); fprintf(out, " };\n"); fprintf(out, " QMetaObject::activate(%s, &staticMetaObject, %d, _a);\n", thisPtr.constData(), index); if (def->normalizedType != "void") fprintf(out, " return _t0;\n"); fprintf(out, "}\n"); } static void writePluginMetaData(FILE *out, const QJsonObject &data) { const QJsonDocument doc(data); fputs("\nQT_PLUGIN_METADATA_SECTION\n" "static const unsigned char qt_pluginMetaData[] = {\n" " 'Q', 'T', 'M', 'E', 'T', 'A', 'D', 'A', 'T', 'A', ' ', ' ',\n ", out); #if 0 fprintf(out, "\"%s\";\n", doc.toJson().constData()); #else const QByteArray binary = doc.toBinaryData(); const int last = binary.size() - 1; for (int i = 0; i < last; ++i) { fprintf(out, " 0x%02x,", (uchar)binary.at(i)); if (!((i + 1) % 8)) fputs("\n ", out); } fprintf(out, " 0x%02x\n};\n", (uchar)binary.at(last)); #endif } void Generator::generatePluginMetaData() { if (cdef->pluginData.iid.isEmpty()) return; // Write plugin meta data #ifdefed QT_NO_DEBUG with debug=false, // true, respectively. QJsonObject data; const QString debugKey = QStringLiteral("debug"); data.insert(QStringLiteral("IID"), QLatin1String(cdef->pluginData.iid.constData())); data.insert(QStringLiteral("className"), QLatin1String(cdef->classname.constData())); data.insert(QStringLiteral("version"), (int)QT_VERSION); data.insert(debugKey, QJsonValue(false)); data.insert(QStringLiteral("MetaData"), cdef->pluginData.metaData.object()); fputs("\nQT_PLUGIN_METADATA_SECTION const uint qt_section_alignment_dummy = 42;\n\n" "#ifdef QT_NO_DEBUG\n", out); writePluginMetaData(out, data); fputs("\n#else // QT_NO_DEBUG\n", out); data.remove(debugKey); data.insert(debugKey, QJsonValue(true)); writePluginMetaData(out, data); fputs("#endif // QT_NO_DEBUG\n\n", out); // 'Use' all namespaces. int pos = cdef->qualified.indexOf("::"); for ( ; pos != -1 ; pos = cdef->qualified.indexOf("::", pos + 2) ) fprintf(out, "using namespace %s;\n", cdef->qualified.left(pos).constData()); fprintf(out, "QT_MOC_EXPORT_PLUGIN(%s, %s)\n\n", cdef->qualified.constData(), cdef->classname.constData()); } QT_END_NAMESPACE