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43d716bb5ab7f933337a51b0f1635715cb15bc6f
qt-creator/tests/manual/debugger/simple/simple_test_app.cpp
Eike Ziller 9926fc2ab1 Merge commit '3c85058694ee2e41658d17f524fb48f0b187d2fe' 
Conflicts:
	src/libs/utils/tooltip/tipcontents.cpp
	src/libs/utils/tooltip/tipcontents.h
	src/plugins/android/androiddeployqtstep.cpp
	src/plugins/baremetal/baremetalconstants.h
	src/plugins/baremetal/baremetaldevice.cpp
	src/plugins/baremetal/baremetaldevice.h
	src/plugins/baremetal/baremetaldeviceconfigurationwidget.cpp
	src/plugins/baremetal/baremetaldeviceconfigurationwidget.h
	src/plugins/baremetal/baremetaldeviceconfigurationwizard.cpp
	src/plugins/baremetal/baremetaldeviceconfigurationwizardpages.cpp
	src/plugins/baremetal/baremetaldeviceconfigurationwizardpages.h
	src/plugins/baremetal/baremetalplugin.cpp
	src/plugins/baremetal/baremetalplugin.h
	src/plugins/baremetal/baremetalruncontrolfactory.cpp
	src/plugins/baremetal/baremetalruncontrolfactory.h
	src/plugins/cppeditor/cppcodemodelinspectordialog.cpp
	src/plugins/cppeditor/cppdoxygen_test.cpp
	src/plugins/cppeditor/cppdoxygen_test.h
	src/plugins/debugger/breakpointmarker.cpp
	src/plugins/debugger/debuggeritemmodel.cpp
	src/plugins/debugger/debuggeritemmodel.h
	src/plugins/debugger/loadcoredialog.cpp
	src/plugins/genericprojectmanager/cppmodelmanagerhelper.cpp
	src/plugins/projectexplorer/addnewmodel.cpp
	src/plugins/projectexplorer/addnewmodel.h
	src/plugins/projectexplorer/jsonwizard/jsonfieldpage.cpp
	src/plugins/qmlprofiler/abstracttimelinemodel.cpp
	src/plugins/qmlprofiler/abstracttimelinemodel.h
	src/plugins/qmlprofiler/notesmodel.cpp
	src/plugins/qmlprofiler/qml/CategoryLabel.qml
	src/plugins/qmlprofiler/qml/MainView.qml
	src/plugins/qmlprofiler/qml/Overview.js
	src/plugins/qmlprofiler/qml/Overview.qml
	src/plugins/qmlprofiler/qml/TimeDisplay.qml
	src/plugins/qmlprofiler/qml/TimeMarks.qml
	src/plugins/qmlprofiler/qmlprofilertimelinemodelproxy.cpp
	src/plugins/qmlprofiler/sortedtimelinemodel.cpp
	src/plugins/qmlprofiler/sortedtimelinemodel.h
	src/plugins/qmlprofiler/timelinemodelaggregator.cpp
	src/plugins/qmlprofiler/timelinemodelaggregator.h
	src/plugins/qmlprofiler/timelinerenderer.cpp
	src/plugins/qmlprofiler/timelinerenderer.h
	src/plugins/qmlprojectmanager/QmlProjectManager.json.in
	src/plugins/texteditor/findinfiles.cpp
	src/plugins/vcsbase/vcsconfigurationpage.cpp
	src/shared/qbs
	src/shared/scriptwrapper/interface_wrap_helpers.h
	src/shared/scriptwrapper/wrap_helpers.h
	tests/auto/qmlprofiler/abstracttimelinemodel/tst_abstracttimelinemodel.cpp
	tests/system/suite_debugger/tst_debug_empty_main/test.py
	tests/system/suite_debugger/tst_qml_js_console/test.py
	tests/system/suite_debugger/tst_qml_locals/test.py

Change-Id: I67540b648f8b162496f4aa606b04d50c7c9125c6
2015-02-12 17:29:21 +01:00

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/****************************************************************************
**
** Copyright (C) 2015 The Qt Company Ltd.
** Contact: http://www.qt.io/licensing
**
** This file is part of Qt Creator.
**
** 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 The Qt Company. For licensing terms and
** conditions see http://www.qt.io/terms-conditions. For further information
** use the contact form at http://www.qt.io/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 or version 3 as published by the Free
** Software Foundation and appearing in the file LICENSE.LGPLv21 and
** LICENSE.LGPLv3 included in the packaging of this file. Please review the
** following information to ensure the GNU Lesser General Public License
** requirements will be met: https://www.gnu.org/licenses/lgpl.html and
** http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** In addition, as a special exception, The Qt Company gives you certain additional
** rights. These rights are described in The Qt Company LGPL Exception
** version 1.1, included in the file LGPL_EXCEPTION.txt in this package.
**
****************************************************************************/
//////////////// Some global configuration below ////////////////
// The following defines can be used to steer the kind of tests that
// can be done.
// With USE_AUTORUN, creator will automatically "execute" the commands
// in a comment following a BREAK_HERE line.
// The following commands are supported:
// // Check <name> <value> <type>
// - Checks whether the local variable is displayed with value and type.
// // CheckType <name> <type>
// - Checks whether the local variable is displayed with type.
// The value is untested, so it can be used with pointers values etc.
// that would change between test runs
// // Continue
// - Continues execution
// On the TODO list:
// // Expand <name1>[ <name2> ...].
// - Expands local variables with given names.
// There should be at most one "Expand" line per BREAK_HERE,
// and this should placed on the line following the BREAK_HERE
// FIXME: Not implemented yet.
// Value: 1
// If the line after a BREAK_HERE line does not contain one of the
// supported commands, the test stops.
// Value: 2
// Same as 1, except that the debugger will stop automatically when
// a test after a BREAK_HERE failed
// Default: 0
// Before using this, make sure that "Show a message box when receiving a signal"
// is disabled in "Tools" -> "Options..." -> "Debugger" -> "GDB".
#ifndef USE_AUTORUN
#define USE_AUTORUN 0
#endif
// With USE_AUTOBREAK, the debugger will stop automatically on all
// lines containing the BREAK_HERE macro. This should be enabled
// during manual testing.
// Default: 0
#ifndef USE_AUTOBREAK
#define USE_AUTOBREAK 0
#endif
// With USE_UNINITIALIZED_AUTOBREAK, the debugger will stop automatically
// on all lines containing the BREAK_UNINITIALIZED_HERE macro.
// This should be enabled during manual testing.
// Default: 0
#ifndef USE_UNINITIALIZED_AUTOBREAK
#define USE_UNINITIALIZED_AUTOBREAK 0
#endif
////////////// No further global configuration below ////////////////
// AUTORUN is only sensibly with AUTOBREAK and without UNINITIALIZED_AUTOBREAK
#if USE_AUTORUN
#if !(USE_AUTOBREAK)
#undef USE_AUTOBREAK
#define USE_AUTOBREAK 1
#pragma message ("Switching on USE_AUTOBREAK")
#endif // !USE_AUTOBREAK
#if USE_UNINITIALIZED_AUTOBREAK
#undef USE_UNINITIALIZED_AUTOBREAK
#define USE_UNINITIALIZED_AUTOBREAK 0
#pragma message ("Switching off USE_UNINITIALIZED_AUTOBREAK")
#endif // USE_UNINITIALIZED_AUTOBREAK
#endif
#ifdef HAS_BOOST
#ifndef ANDROID
#define USE_BOOST 1
#endif
#endif
#ifdef HAS_PRIVATE
#define USE_PRIVATE 1
#endif
#ifdef HAS_EIGEN2
#define USE_EIGEN 1
#endif
#ifdef HAS_EIGEN3
#define USE_EIGEN 1
#endif
#ifdef QT_SCRIPT_LIB
#define USE_SCRIPTLIB 1
#else
#define USE_SCRIPTLIB 0
#endif
#ifdef QT_WEBKIT_LIB
#define USE_WEBKITLIB 1
#else
#define USE_WEBKITLIB 0
#endif
#if QT_VERSION >= 0x050200
#define USE_TIMEZONE 1
#else
#define USE_TIMEZONE 0
#endif
void dummyStatement(...) {}
#if defined(__GNUC__) && defined(__STRICT_ANSI__)
#undef __STRICT_ANSI__ // working around compile error with MinGW
#endif
#include <QCoreApplication>
#include <QDebug>
#include <QDateTime>
#include <QDir>
#include <QHash>
#include <QLibrary>
#include <QLinkedList>
#include <QList>
#include <QMap>
#include <QPointer>
#include <QProcess>
#include <QRegExp>
#include <QString>
#include <QStringList>
#include <QSettings>
#include <QSharedPointer>
#include <QStack>
#include <QThread>
#include <QVariant>
#include <QVector>
#include <QUrl>
#if USE_GUILIB
#include <QAction>
#include <QApplication> // QWidgets: Separate module as of Qt 5
#include <QColor>
#include <QFont>
#include <QLabel>
#include <QPainter>
#include <QPainterPath>
#include <QRegion>
#include <QStandardItemModel>
#include <QTextCursor>
#include <QTextDocument>
# if QT_VERSION >= QT_VERSION_CHECK(5, 2, 0)
# include <QTimeZone>
# endif
#endif
#if USE_SCRIPTLIB
#include <QScriptEngine>
#include <QScriptValue>
#endif
#if USE_WEBKITLIB
#include <QWebPage>
#endif
#include <QXmlAttributes>
#include <QHostAddress>
#include <QNetworkRequest>
#include <array>
#include <unordered_map>
#include <complex>
#include <deque>
#include <iostream>
#include <iterator>
#include <fstream>
#include <map>
#include <memory>
#include <list>
#include <limits>
#include <set>
#include <stack>
#include <string>
#include <vector>
#include <stdarg.h>
#include <stdint.h>
#include "../simple/deep/deep/simple_test_app.h"
#if USE_BOOST
#include <boost/optional.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/date_time.hpp>
#include <boost/date_time/gregorian/gregorian.hpp>
#include <boost/date_time/posix_time/posix_time.hpp>
#include <boost/bimap.hpp>
#endif
#if USE_EIGEN
#include <Eigen/Core>
#endif
#if USE_PRIVATE
#include <private/qobject_p.h>
#endif
#if defined(__GNUC__) && !defined(__llvm__) && !defined(Q_OS_MAC)
# ifndef ANDROID
# define USE_GCC_EXT 1
# undef __DEPRECATED
# include <ext/hash_set>
# endif
#endif
#ifdef Q_OS_WIN
#include <windows.h>
#undef min
#undef max
#endif
#if USE_SSE && !defined(__SSE__)
#undef USE_SSE
#endif
#if USE_SSE
#include <xmmintrin.h>
#include <stddef.h>
#else
#endif
#if USE_AUTOBREAK
# ifdef Q_CC_MSVC
# include <crtdbg.h>
# define BREAK_HERE _CrtDbgReport(_CRT_WARN, NULL, NULL, "simple_test_app", NULL)
# else
# define BREAK_HERE asm("int $3; mov %eax, %eax")
# endif
#else
# define BREAK_HERE dummyStatement()
#endif
#if USE_UNINITIALIZED_AUTOBREAK
# ifdef Q_CC_MSVC
# include <crtdbg.h>
# define BREAK_UNINITIALIZED_HERE _CrtDbgReport(_CRT_WARN, NULL, NULL, "simple_test_app", NULL)
# else
# define BREAK_UNINITIALIZED_HERE asm("int $3; mov %eax, %eax")
# endif
#else
# define BREAK_UNINITIALIZED_HERE dummyStatement()
#endif
QT_BEGIN_NAMESPACE
uint qHash(const QMap<int, int> &) { return 0; }
uint qHash(const double & f) { return int(f); }
uint qHash(const QPointer<QObject> &p) { return (ulong)p.data(); }
QT_END_NAMESPACE
namespace nsA {
namespace nsB {
struct SomeType
{
SomeType(int a) : a(a) {}
int a;
};
} // namespace nsB
} // namespace nsA
struct BaseClass
{
BaseClass() : a(1) {}
virtual ~BaseClass() {}
virtual int foo() { return a; }
int a;
};
struct DerivedClass : BaseClass
{
DerivedClass() : b(2) {}
int foo() { return b; }
int b;
};
namespace multibp {
// This tests multiple breakpoints.
template <typename T> class Vector
{
public:
explicit Vector(int size)
: m_size(size), m_data(new T[size])
{
BREAK_HERE;
// Check size 10 int.
// Continue.
// Manual: Add a breakpoint in the constructor
// Manual: Check there are multiple entries in the Breakpoint view.
dummyStatement(this);
}
~Vector() { delete [] m_data; }
int size() const { return m_size; }
private:
int m_size;
T *m_data;
};
void testMultiBp()
{
Vector<int> vi(10);
Vector<float> vf(10);
Vector<double> vd(10);
Vector<char> vc(10);
dummyStatement(&vi, &vf, &vd, &vc);
}
} // namespace multibp
class Foo
{
public:
Foo(int i = 0)
: a(i), b(2)
{
int s = 1;
int t = 2;
b = 2 + s + t;
dummyStatement(&s, &t);
}
virtual ~Foo()
{
a = 5;
}
void doit()
{
static QObject ob;
m["1"] = "2";
h[&ob] = m.begin();
a += 1;
--b;
dummyStatement(&a, &b);
}
public:
int a, b;
char x[6];
private:
typedef QMap<QString, QString> Map;
Map m;
QHash<QObject *, Map::iterator> h;
};
class Fooooo : public Foo
{
public:
Fooooo(int x) : Foo(x), a(x + 2) {}
int a;
};
class X : virtual public Foo { public: X() { } };
class XX : virtual public Foo { public: XX() { } };
class Y : virtual public Foo { public: Y() { } };
class D : public X, public Y { int diamond; D(){Q_UNUSED(diamond);} };
namespace peekandpoke {
void testAnonymousStructs()
{
union {
struct { int i; int b; };
struct { float f; };
double d;
} a = { { 42, 43 } };
BREAK_HERE;
// Expand a.
// CheckType a union {...}.
// Check a.b 43 int.
// Check a.d 9.1245819032257467e-313 double.
// Check a.f 5.88545355e-44 float.
// Check a.i 42 int.
// Continue.
a.i = 1;
BREAK_HERE;
// Expand a.
// CheckType a union {...}.
// Check a.b 43 int.
// Check a.d 9.1245819012000775e-313 double.
// Check a.f 1.40129846e-45 float.
// Check a.i 1 int.
// Continue.
a.i = 2;
BREAK_HERE;
// Expand a.
// CheckType a union {...}.
// Check a.b 43 int.
// Check a.d 9.1245819012494841e-313 double.
// Check a.f 2.80259693e-45 float.
// Check a.i 2 int.
// Continue.
dummyStatement(&a);
}
void testComplexWatchers()
{
struct S { int a; double b; } s[10];
BREAK_HERE;
// Expand s and s[0].
// CheckType s peekandpoke::S [10].
// Continue.
// Manual: Watcher Context: "Add New Watcher".
// Manual: Type ['s[%d].a' % i for i in range(5)]
// Manual: Expand it, continue stepping. This should result in a list
// Manual: of five items containing the .a fields of s[0]..s[4].
for (int i = 0; i != 10; ++i)
s[i].a = i;
dummyStatement(&s);
}
void testQImageDisplay()
{
#if USE_GUILIB
QImage im(QSize(200, 200), QImage::Format_RGB32);
im.fill(QColor(200, 10, 30).rgba());
QPainter pain;
pain.begin(&im);
pain.setPen(QPen(Qt::black, 5.0, Qt::SolidLine, Qt::RoundCap));
BREAK_HERE;
// Check im (200x200) QImage.
// CheckType pain QPainter.
// Continue.
pain.drawEllipse(20, 20, 160, 160);
BREAK_HERE;
// Continue.
// Manual: Toggle between "Normal" and "Displayed" in L&W Context Menu,
// Manual: entry "Display of Type QImage".
pain.drawArc(70, 115, 60, 30, 200 * 16, 140 * 16);
BREAK_HERE;
// Continue.
pain.setBrush(Qt::black);
BREAK_HERE;
// Continue.
pain.drawEllipse(65, 70, 15, 15);
BREAK_HERE;
// Continue.
// Manual: Toggle between "Normal" and "Displayed" in L&W Context Menu,
// Manual: entry "Display of Type QImage".
pain.drawEllipse(120, 70, 15, 15);
BREAK_HERE;
// Continue.
pain.end();
dummyStatement(&pain);
#endif
}
void testPeekAndPoke3()
{
testAnonymousStructs();
testComplexWatchers();
testQImageDisplay();
}
} // namespace peekandpoke
namespace anon {
#ifndef Q_CC_RVCT
struct TestAnonymous
{
union {
struct { int i; int b; };
struct { float f; };
double d;
};
};
namespace {
struct Something
{
Something() { a = b = 1; }
void foo()
{
a = 42;
b = 43;
}
int a, b;
};
}
#endif
void testAnonymous()
{
TestAnonymous a;
BREAK_HERE;
// Expand a a.#1 a.#2.
// CheckType a anon::TestAnonymous.
// Check a.#1 {...}.
// CheckType a.#1.b int.
// CheckType a.#1.i int.
// CheckType a.#2.f float.
// CheckType a.d double.
// Continue.
a.i = 1;
a.i = 2;
a.i = 3;
Something s;
BREAK_HERE;
// Expand s.
// CheckType s anon::(anonymous namespace)::Something.
// Check s.a 1 int.
// Check s.b 1 int.
// Continue.
s.foo();
BREAK_HERE;
// Expand s.
// Check s.a 42 int.
// Check s.b 43 int.
// Continue.
std::map<int, Something> m;
BREAK_HERE;
// CheckType m std::map<int, anon::{anonymous}::Something>.
// Continue.
dummyStatement(&a, &s, &m);
}
} // namespace anon
namespace qbytearray {
void testQByteArray1()
{
QByteArray ba;
BREAK_HERE;
// Check ba "" QByteArray.
// Continue.
ba += "Hello";
ba += '"';
ba += "World";
ba += char(0);
ba += 1;
ba += 2;
BREAK_HERE;
// Expand ba.
// Check ba "Hello"World" QByteArray.
// Check ba.0 72 'H' char.
// Check ba.11 0 '\0' char.
// Check ba.12 1 char.
// Check ba.13 2 char.
// Continue.
dummyStatement(&ba);
}
void testQByteArray2()
{
QByteArray ba;
for (int i = 256; --i >= 0; )
ba.append(char(i));
QString s(10000, 'x');
std::string ss(10000, 'c');
BREAK_HERE;
// CheckType ba QByteArray.
// Check s "xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx..." QString.
// Check ss "ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc..." std::string.
// Continue.
dummyStatement(&ba, &ss, &s);
}
void testQByteArray3()
{
const char *str1 = "\356";
const char *str2 = "\xee";
const char *str3 = "\\ee";
QByteArray buf1(str1);
QByteArray buf2(str2);
QByteArray buf3(str3);
BREAK_HERE;
// Check buf1 "î" QByteArray.
// Check buf2 "î" QByteArray.
// Check buf3 "\ee" QByteArray.
// CheckType str1 char *.
// Continue.
dummyStatement(&buf1, &buf2, &buf3);
}
void testQByteArray4()
{
char data[] = { 'H', 'e', 'l', 'l', 'o' };
QByteArray ba1 = QByteArray::fromRawData(data, 4);
QByteArray ba2 = QByteArray::fromRawData(data + 1, 4);
BREAK_HERE;
// Check ba1 "Hell" QByteArray.
// Check ba2 "ello" QByteArray.
// Continue.
dummyStatement(&ba1, &ba2, &data);
}
void testQByteArray()
{
testQByteArray1();
testQByteArray2();
testQByteArray3();
testQByteArray4();
}
} // namespace qbytearray
namespace catchthrow {
static void throwit1()
{
BREAK_HERE;
// Continue.
// Set a breakpoint on "throw" in the BreakWindow context menu
// before stepping further.
throw 14;
}
static void throwit()
{
throwit1();
}
void testCatchThrow()
{
int gotit = 0;
try {
throwit();
} catch (int what) {
gotit = what;
}
dummyStatement(&gotit);
}
} // namespace catchthrow
namespace undefined {
void testUndefined()
{
int *i = new int;
delete i;
BREAK_HERE;
// Continue.
// Manual: Uncomment the following line. Step.
// On Linux, a SIGABRT should be received.
//delete i;
dummyStatement(&i);
}
} // namespace undefined
namespace qdatetime {
void testQTimeZone()
{
#if QT_VERSION >= QT_VERSION_CHECK(5, 2, 0)
QTimeZone zz;
QTimeZone tz("UTC+05:00");
BREAK_HERE;
dummyStatement(&zz, &tz);
#endif
}
void testQDate()
{
QDate date;
BREAK_HERE;
// Expand date.
// CheckType date QDate.
// Check date.(ISO) "" QString.
// Check date.(Locale) "" QString.
// Check date.(SystemLocale) "" QString.
// Check date.toString "" QString.
// Continue.
// Step, check display.
date = QDate::currentDate();
date = date.addDays(5);
date = date.addDays(5);
dummyStatement(&date);
}
void testQTime()
{
QTime time;
BREAK_HERE;
// Expand time.
// CheckType time QTime.
// Check time.(ISO) "" QString.
// Check time.(Locale) "" QString.
// Check time.(SystemLocale) "" QString.
// Check time.toString "" QString.
// Continue.
// Step, check display.
time = QTime::currentTime();
time = time.addSecs(5);
time = time.addSecs(5);
dummyStatement(&time);
}
void testQDateTime()
{
QDateTime date;
BREAK_HERE;
// Expand date.
// CheckType date QDateTime.
// Check date.(ISO) "" QString.
// Check date.(Locale) "" QString.
// Check date.(SystemLocale) "" QString.
// Check date.toString "" QString.
// Check date.toUTC QDateTime.
// Continue.
// Step, check display
date = QDateTime::currentDateTime();
date = date.addDays(5);
date = date.addDays(5);
dummyStatement(&date);
}
void testDateTime()
{
testQTimeZone();
testQDate();
testQDateTime();
testQTime();
}
} // namespace qdatetime
namespace qdir {
void testQDir()
{
#ifdef Q_OS_WIN
QDir dir("C:\\Program Files");
dir.absolutePath(); // Keep in to facilitate stepping
BREAK_HERE;
// Check dir "C:/Program Files" QDir.
// Check dir.absolutePath "C:/Program Files" QString.
// Check dir.canonicalPath "C:/Program Files" QString.
// Continue.
#else
QDir dir("/tmp");
dir.absolutePath(); // Keep in to facilitate stepping
BREAK_HERE;
// Check dir "/tmp" QDir.
// Check dir.absolutePath "/tmp" QString.
// Check dir.canonicalPath "/tmp" QString.
// Continue.
#endif
dummyStatement(&dir);
}
} // namespace qdir
namespace qfileinfo {
void testQFileInfo()
{
#ifdef Q_OS_WIN
QFile file("C:\\Program Files\\t");
file.setObjectName("A QFile instance");
QFileInfo fi("C:\\Program Files\\tt");
QString s = fi.absoluteFilePath();
BREAK_HERE;
// Check fi "C:/Program Files/tt" QFileInfo.
// Check file "C:\Program Files\t" QFile.
// Check s "C:/Program Files/tt" QString.
// Continue.
dummyStatement(&file, &s);
#else
QFile file("/tmp/t");
file.setObjectName("A QFile instance");
QFileInfo fi("/tmp/tt");
QString s = fi.absoluteFilePath();
BREAK_HERE;
// Check fi "/tmp/tt" QFileInfo.
// Check file "/tmp/t" QFile.
// Check s "/tmp/tt" QString.
// Continue.
dummyStatement(&file, &s);
#endif
}
} // namespace qfileinfo
namespace qhash {
void testQHash1()
{
QHash<QString, QList<int> > hash;
hash.insert("Hallo", QList<int>());
hash.insert("Welt", QList<int>() << 1);
hash.insert("!", QList<int>() << 1 << 2);
hash.insert("!", QList<int>() << 1 << 2);
BREAK_HERE;
// Expand hash hash.0 hash.1 hash.1.value hash.2 hash.2.value.
// Check hash <3 items> QHash<QString, QList<int>>.
// Check hash.0 QHashNode<QString, QList<int>>.
// Check hash.0.key "Hallo" QString.
// Check hash.0.value <0 items> QList<int>.
// Check hash.1 QHashNode<QString, QList<int>>.
// Check hash.1.key "Welt" QString.
// Check hash.1.value <1 items> QList<int>.
// Check hash.1.value.0 1 int.
// Check hash.2 QHashNode<QString, QList<int>>.
// Check hash.2.key "!" QString.
// Check hash.2.value <2 items> QList<int>.
// Check hash.2.value.0 1 int.
// Check hash.2.value.1 2 int.
// Continue.
dummyStatement(&hash);
}
void testQHash2()
{
QHash<int, float> hash;
hash[11] = 11.0;
hash[22] = 22.0;
BREAK_HERE;
// Expand hash.
// Check hash <2 items> QHash<int, float>.
// Check hash.22 22 float.
// Check hash.11 11 float.
// Continue.
dummyStatement(&hash);
}
void testQHash3()
{
QHash<QString, int> hash;
hash["22.0"] = 22.0;
hash["123.0"] = 22.0;
hash["111111ss111128.0"] = 28.0;
hash["11124.0"] = 22.0;
hash["1111125.0"] = 22.0;
hash["11111126.0"] = 22.0;
hash["111111127.0"] = 27.0;
hash["111111111128.0"] = 28.0;
hash["111111111111111111129.0"] = 29.0;
BREAK_HERE;
// Expand hash hash.0 hash.8.
// Check hash <9 items> QHash<QString, int>.
// Check hash.0 QHashNode<QString, int>.
// Check hash.0.key "123.0" QString.
// Check hash.0.value 22 int.
// Check hash.8 QHashNode<QString, int>.
// Check hash.8.key "11124.0" QString.
// Check hash.8.value 22 int.
// Continue.
dummyStatement(&hash);
}
void testQHash4()
{
QHash<QByteArray, float> hash;
hash["22.0"] = 22.0;
hash["123.0"] = 22.0;
hash["111111ss111128.0"] = 28.0;
hash["11124.0"] = 22.0;
hash["1111125.0"] = 22.0;
hash["11111126.0"] = 22.0;
hash["111111127.0"] = 27.0;
hash["111111111128.0"] = 28.0;
hash["111111111111111111129.0"] = 29.0;
BREAK_HERE;
// Expand hash hash.0 hash.8/
// Check hash <9 items> QHash<QByteArray, float>.
// Check hash.0 QHashNode<QByteArray, float>.
// Check hash.0.key "123.0" QByteArray.
// Check hash.0.value 22 float.
// Check hash.8 QHashNode<QByteArray, float>.
// Check hash.8.key "11124.0" QByteArray.
// Check hash.8.value 22 float.
// Continue.
dummyStatement(&hash);
}
void testQHash5()
{
QHash<int, QString> hash;
hash[22] = "22.0";
BREAK_HERE;
// Expand hash hash.0.
// Check hash <1 items> QHash<int, QString>.
// Check hash.0 QHashNode<int, QString>.
// Check hash.0.key 22 int.
// Check hash.0.value "22.0" QString.
// Continue.
dummyStatement(&hash);
}
void testQHash6()
{
QHash<QString, Foo> hash;
hash["22.0"] = Foo(22);
hash["33.0"] = Foo(33);
BREAK_HERE;
// Expand hash hash.0 hash.0.value hash.1.
// Check hash <2 items> QHash<QString, Foo>.
// Check hash.0 QHashNode<QString, Foo>.
// Check hash.0.key "22.0" QString.
// CheckType hash.0.value Foo.
// Check hash.0.value.a 22 int.
// Check hash.1 QHashNode<QString, Foo>.
// Check hash.1.key "33.0" QString.
// CheckType hash.1.value Foo.
// Continue.
dummyStatement(&hash);
}
void testQHash7()
{
QObject ob;
QHash<QString, QPointer<QObject> > hash;
hash.insert("Hallo", QPointer<QObject>(&ob));
hash.insert("Welt", QPointer<QObject>(&ob));
hash.insert(".", QPointer<QObject>(&ob));
BREAK_HERE;
// Expand hash hash.0 hash.0.value hash.2.
// Check hash <3 items> QHash<QString, QPointer<QObject>>.
// Check hash.0 QHashNode<QString, QPointer<QObject>>.
// Check hash.0.key "Hallo" QString.
// CheckType hash.0.value QPointer<QObject>.
// CheckType hash.0.value.o QObject.
// Check hash.2 QHashNode<QString, QPointer<QObject>>.
// Check hash.2.key "." QString.
// CheckType hash.2.value QPointer<QObject>.
// Continue.
dummyStatement(&hash, &ob);
}
void testQHashIntFloatIterator()
{
typedef QHash<int, float> Hash;
Hash hash;
hash[11] = 11.0;
hash[22] = 22.0;
hash[33] = 33.0;
hash[44] = 44.0;
hash[55] = 55.0;
hash[66] = 66.0;
Hash::iterator it1 = hash.begin();
Hash::iterator it2 = it1; ++it2;
Hash::iterator it3 = it2; ++it3;
Hash::iterator it4 = it3; ++it4;
Hash::iterator it5 = it4; ++it5;
Hash::iterator it6 = it5; ++it6;
BREAK_HERE;
// Expand hash.
// Check hash <6 items> qhash::Hash.
// Check hash.11 11 float.
// Check it1.key 55 int.
// Check it1.value 55 float.
// Check it6.key 33 int.
// Check it6.value 33 float.
// Continue.
dummyStatement(&hash, &it1, &it2, &it3, &it4, &it5, &it6);
}
void testQHash()
{
testQHash1();
testQHash2();
testQHash3();
testQHash4();
testQHash5();
testQHash6();
testQHash7();
testQHashIntFloatIterator();
}
} // namespace qhash
namespace qhostaddress {
void testQHostAddress1()
{
QHostAddress ha1(129u * 256u * 256u * 256u + 130u);
QHostAddress ha2("127.0.0.1");
uint ip2 = ha2.toIPv4Address();
BREAK_HERE;
// Check ha1 129.0.0.130 QHostAddress.
// Check ha2 "127.0.0.1" QHostAddress.
// Continue.
dummyStatement(&ha1, &ha2, &ip2);
}
void testQHostAddress2()
{
QIPv6Address addr;
for (int i = 0; i != 16; ++i)
addr.c[i] = i;
addr.c[4] = 0;
addr.c[5] = 0;
addr.c[6] = 0;
addr.c[7] = 0;
addr.c[12] = 0;
addr.c[13] = 0;
addr.c[14] = 0;
addr.c[15] = 0;
QHostAddress ha1(addr);
ha1.setScopeId(QLatin1String("wlan0"));
BREAK_HERE;
// Continue.
dummyStatement(&ha1);
}
void testQHostAddress()
{
testQHostAddress1();
testQHostAddress2();
}
} // namespace qhostaddress
namespace painting {
void testQImage()
{
#if USE_GUILIB
// only works with Python dumper
QImage im(QSize(200, 200), QImage::Format_RGB32);
im.fill(QColor(200, 100, 130).rgba());
QPainter pain;
pain.begin(&im);
BREAK_HERE;
// Check im (200x200) QImage.
// CheckType pain QPainter.
// Continue.
// Step.
pain.drawLine(2, 2, 130, 130);
pain.drawLine(4, 2, 130, 140);
pain.drawRect(30, 30, 80, 80);
pain.end();
dummyStatement(&pain, &im);
#endif
}
void testQPixmap()
{
#if USE_GUILIB
QImage im(QSize(200, 200), QImage::Format_RGB32);
im.fill(QColor(200, 100, 130).rgba());
QPainter pain;
pain.begin(&im);
pain.drawLine(2, 2, 130, 130);
pain.end();
QPixmap pm = QPixmap::fromImage(im);
BREAK_HERE;
// Check im (200x200) QImage.
// CheckType pain QPainter.
// Check pm (200x200) QPixmap.
// Continue.
dummyStatement(&im, &pm);
#endif
}
void testPainting()
{
testQImage();
testQPixmap();
}
} // namespace painting
namespace qlinkedlist {
void testQLinkedListInt()
{
QLinkedList<int> list;
list.append(101);
list.append(102);
BREAK_HERE;
// Expand list.
// Check list <2 items> QLinkedList<int>.
// Check list.0 101 int.
// Check list.1 102 int.
// Continue.
dummyStatement(&list);
}
void testQLinkedListUInt()
{
QLinkedList<uint> list;
list.append(103);
list.append(104);
BREAK_HERE;
// Expand list.
// Check list <2 items> QLinkedList<unsigned int>.
// Check list.0 103 unsigned int.
// Check list.1 104 unsigned int.
// Continue.
dummyStatement(&list);
}
void testQLinkedListFooStar()
{
QLinkedList<Foo *> list;
list.append(new Foo(1));
list.append(0);
list.append(new Foo(3));
BREAK_HERE;
// Expand list list.0 list.2.
// Check list <3 items> QLinkedList<Foo*>.
// CheckType list.0 Foo.
// Check list.0.a 1 int.
// Check list.1 0x0 Foo *.
// CheckType list.2 Foo.
// Check list.2.a 3 int.
// Continue.
dummyStatement(&list);
}
void testQLinkedListULongLong()
{
QLinkedList<qulonglong> list;
list.append(42);
list.append(43);
BREAK_HERE;
// Expand list.
// Check list <2 items> QLinkedList<unsigned long long>.
// Check list.0 42 unsigned long long.
// Check list.1 43 unsigned long long.
// Continue.
dummyStatement(&list);
}
void testQLinkedListFoo()
{
QLinkedList<Foo> list;
list.append(Foo(1));
list.append(Foo(2));
BREAK_HERE;
// Expand list list.0 list.1.
// Check list <2 items> QLinkedList<Foo>.
// CheckType list.0 Foo.
// Check list.0.a 1 int.
// CheckType list.1 Foo.
// Check list.1.a 2 int.
// Continue.
dummyStatement(&list);
}
void testQLinkedListStdString()
{
QLinkedList<std::string> list;
list.push_back("aa");
list.push_back("bb");
BREAK_HERE;
// Expand list.
// Check list <2 items> QLinkedList<std::string>.
// Check list.0 "aa" std::string.
// Check list.1 "bb" std::string.
// Continue.
dummyStatement(&list);
}
void testQLinkedList()
{
testQLinkedListInt();
testQLinkedListUInt();
testQLinkedListFooStar();
testQLinkedListULongLong();
testQLinkedListFoo();
testQLinkedListStdString();
}
} // namespace qlinkedlist
namespace qlist {
void testQListInt()
{
QList<int> big;
for (int i = 0; i < 10000; ++i)
big.push_back(i);
BREAK_HERE;
// Expand big.
// Check big <10000 items> QList<int>.
// Check big.0 0 int.
// Check big.1999 1999 int.
// Continue.
dummyStatement(&big);
}
void testQListIntTakeFirst()
{
QList<int> l;
l.append(0);
l.append(1);
l.append(2);
l.takeFirst();
BREAK_HERE;
// Expand l.
// Check l <2 items> QList<int>.
// Check l.0 1 int.
// Continue.
dummyStatement(&l);
}
void testQListStringTakeFirst()
{
QList<QString> l;
l.append("0");
l.append("1");
l.append("2");
l.takeFirst();
BREAK_HERE;
// Expand l.
// Check l <2 items> QList<QString>.
// Check l.0 "1" QString.
// Continue.
dummyStatement(&l);
}
void testQStringListTakeFirst()
{
QStringList l;
l.append("0");
l.append("1");
l.append("2");
l.takeFirst();
BREAK_HERE;
// Expand l.
// Check l <2 items> QStringList.
// Check l.0 "1" QString.
// Continue.
dummyStatement(&l);
}
void testQListIntStar()
{
QList<int *> l;
BREAK_HERE;
// Check l <0 items> QList<int*>.
// Continue.
l.append(new int(1));
l.append(new int(2));
l.append(new int(3));
BREAK_HERE;
// Expand l.
// Check l <3 items> QList<int*>.
// CheckType l.0 int.
// CheckType l.2 int.
// Continue.
dummyStatement(&l);
}
void testQListUInt()
{
QList<uint> l;
BREAK_HERE;
// Check l <0 items> QList<unsigned int>.
// Continue.
l.append(101);
l.append(102);
l.append(102);
BREAK_HERE;
// Expand l.
// Check l <3 items> QList<unsigned int>.
// Check l.0 101 unsigned int.
// Check l.2 102 unsigned int.
// Continue.
dummyStatement(&l);
}
void testQListUShort()
{
QList<ushort> l;
BREAK_HERE;
// Check l <0 items> QList<unsigned short>.
// Continue.
l.append(101);
l.append(102);
l.append(102);
BREAK_HERE;
// Expand l.
// Check l <3 items> QList<unsigned short>.
// Check l.0 101 unsigned short.
// Check l.2 102 unsigned short.
// Continue.
dummyStatement(&l);
}
void testQListQChar()
{
QList<QChar> l;
BREAK_HERE;
// Check l <0 items> QList<QChar>.
// Continue.
l.append(QChar('a'));
l.append(QChar('b'));
l.append(QChar('c'));
BREAK_HERE;
// Expand l.
// Check l <3 items> QList<QChar>.
// Check l.0 'a' (97) QChar.
// Check l.2 'c' (99) QChar.
// Continue.
dummyStatement(&l);
}
void testQListQULongLong()
{
QList<qulonglong> l;
BREAK_HERE;
// Check l <0 items> QList<unsigned long long>.
// Continue.
l.append(101);
l.append(102);
l.append(102);
BREAK_HERE;
// Expand l.
// Check l <3 items> QList<unsigned long long>.
// CheckType l.0 unsigned long long.
// CheckType l.2 unsigned long long.
// Continue.
dummyStatement(&l);
}
void testQListStdString()
{
QList<std::string> l;
BREAK_HERE;
// Check l <0 items> QList<std::string>.
// Continue.
l.push_back("aa");
l.push_back("bb");
l.push_back("cc");
l.push_back("dd");
BREAK_HERE;
// Expand l.
// Check l <4 items> QList<std::string>.
// CheckType l.0 std::string.
// CheckType l.3 std::string.
// Continue.
dummyStatement(&l);
}
void testQListFoo()
{
QList<Foo> l;
BREAK_HERE;
// Check l <0 items> QList<Foo>.
// Continue.
for (int i = 0; i < 100; ++i)
l.push_back(i + 15);
BREAK_HERE;
// Check l <100 items> QList<Foo>.
// Expand l.
// CheckType l.0 Foo.
// CheckType l.99 Foo.
// Continue.
l.push_back(1000);
l.push_back(1001);
l.push_back(1002);
BREAK_HERE;
// Check l <103 items> QList<Foo>.
// Continue.
dummyStatement(&l);
}
void testQListReverse()
{
QList<int> l = QList<int>() << 1 << 2 << 3;
typedef std::reverse_iterator<QList<int>::iterator> Reverse;
Reverse rit(l.end());
Reverse rend(l.begin());
QList<int> r;
while (rit != rend)
r.append(*rit++);
BREAK_HERE;
// Expand l r.
// Check l <3 items> QList<int>.
// Check l.0 1 int.
// Check l.1 2 int.
// Check l.2 3 int.
// Check r <3 items> QList<int>.
// Check r.0 3 int.
// Check r.1 2 int.
// Check r.2 1 int.
// CheckType rend qlist::Reverse.
// CheckType rit qlist::Reverse.
// Continue.
dummyStatement();
}
void testQList()
{
testQListInt();
testQListIntStar();
testQListUInt();
testQListUShort();
testQListQChar();
testQListQULongLong();
testQListStdString();
testQListFoo();
testQListReverse();
testQListIntTakeFirst();
testQListStringTakeFirst();
testQStringListTakeFirst();
}
} // namespace qlist
namespace qlocale {
void testQLocale()
{
QLocale loc = QLocale::system();
//QString s = loc.name();
//QVariant v = loc;
QLocale::MeasurementSystem m = loc.measurementSystem();
BREAK_HERE;
// CheckType loc QLocale.
// CheckType m QLocale::MeasurementSystem.
// Continue.
dummyStatement(&loc, &m);
}
} // namespace qlocale
namespace qmap {
void testQMapUIntStringList()
{
QMap<uint, QStringList> map;
map[11] = QStringList() << "11";
map[22] = QStringList() << "22";
BREAK_HERE;
// Expand map map.0 map.0.value map.1 map.1.value.
// Check map <2 items> QMap<unsigned int, QStringList>.
// Check map.0 QMapNode<unsigned int, QStringList>.
// Check map.0.key 11 unsigned int.
// Check map.0.value <1 items> QStringList.
// Check map.0.value.0 "11" QString.
// Check map.1 QMapNode<unsigned int, QStringList>.
// Check map.1.key 22 unsigned int.
// Check map.1.value <1 items> QStringList.
// Check map.1.value.0 "22" QString.
// Continue.
dummyStatement(&map);
}
void testQMapUIntStringListTypedef()
{
// only works with Python dumper
typedef QMap<uint, QStringList> T;
T map;
map[11] = QStringList() << "11";
map[22] = QStringList() << "22";
BREAK_HERE;
// Check map <2 items> qmap::T.
// Continue.
dummyStatement(&map);
}
void testQMapUIntFloat()
{
QMap<uint, float> map;
map[11] = 11.0;
map[22] = 22.0;
BREAK_HERE;
// Expand map.
// Check map <2 items> QMap<unsigned int, float>.
// Check map.11 11 float.
// Check map.22 22 float.
// Continue.
dummyStatement(&map);
}
void testQMapStringFloat()
{
QMap<QString, float> map;
map["22.0"] = 22.0;
BREAK_HERE;
// Expand map map.0.
// Check map <1 items> QMap<QString, float>.
// Check map.0 QMapNode<QString, float>.
// Check map.0.key "22.0" QString.
// Check map.0.value 22 float.
// Continue.
dummyStatement(&map);
}
void testQMapIntString()
{
QMap<int, QString> map;
map[22] = "22.0";
BREAK_HERE;
// Expand map map.0.
// Check map <1 items> QMap<int, QString>.
// Check map.0 QMapNode<int, QString>.
// Check map.0.key 22 int.
// Check map.0.value "22.0" QString.
// Continue.
dummyStatement(&map);
}
void testQMapStringFoo()
{
QMap<QString, Foo> map;
map["22.0"] = Foo(22);
map["33.0"] = Foo(33);
BREAK_HERE;
// Expand map map.0 map.0.key map.0.value map.1 map.1.value.
// Check map <2 items> QMap<QString, Foo>.
// Check map.0 QMapNode<QString, Foo>.
// Check map.0.key "22.0" QString.
// CheckType map.0.value Foo.
// Check map.0.value.a 22 int.
// Check map.1 QMapNode<QString, Foo>.
// Check map.1.key "33.0" QString.
// CheckType map.1.value Foo.
// Check map.1.value.a 33 int.
// Continue.
dummyStatement(&map);
}
void testQMapStringPointer()
{
// only works with Python dumper
QObject ob;
QMap<QString, QPointer<QObject> > map;
map.insert("Hallo", QPointer<QObject>(&ob));
map.insert("Welt", QPointer<QObject>(&ob));
map.insert(".", QPointer<QObject>(&ob));
BREAK_HERE;
// Expand map map.0 map.0.key map.0.value map.1 map.2.
// Check map <3 items> QMap<QString, QPointer<QObject>>.
// Check map.0 QMapNode<QString, QPointer<QObject>>.
// Check map.0.key "." QString.
// CheckType map.0.value QPointer<QObject>.
// CheckType map.0.value.o QObject.
// Check map.1 QMapNode<QString, QPointer<QObject>>.
// Check map.1.key "Hallo" QString.
// Check map.2 QMapNode<QString, QPointer<QObject>>.
// Check map.2.key "Welt" QString.
// Continue.
dummyStatement(&map);
}
void testQMapStringList()
{
// only works with Python dumper
QList<nsA::nsB::SomeType *> x;
x.append(new nsA::nsB::SomeType(1));
x.append(new nsA::nsB::SomeType(2));
x.append(new nsA::nsB::SomeType(3));
QMap<QString, QList<nsA::nsB::SomeType *> > map;
map["foo"] = x;
map["bar"] = x;
map["1"] = x;
map["2"] = x;
BREAK_HERE;
// Expand map map.0 map.0.key map.0.value map.1 map.1.value.1 map.1.value.2 map.3 map.3.value map.3.value.2.
// Check map <4 items> QMap<QString, QList<nsA::nsB::SomeType*>>.
// Check map.0 QMapNode<QString, QList<nsA::nsB::SomeType*>>.
// Check map.0.key "1" QString.
// Check map.0.value <3 items> QList<nsA::nsB::SomeType*>.
// CheckType map.0.value.0 nsA::nsB::SomeType.
// Check map.0.value.0.a 1 int.
// CheckType map.0.value.1 nsA::nsB::SomeType.
// Check map.0.value.1.a 2 int.
// CheckType map.0.value.2 nsA::nsB::SomeType.
// Check map.0.value.2.a 3 int.
// Check map.3 QMapNode<QString, QList<nsA::nsB::SomeType*>>.
// Check map.3.key "foo" QString.
// Check map.3.value <3 items> QList<nsA::nsB::SomeType*>.
// CheckType map.3.value.2 nsA::nsB::SomeType.
// Check map.3.value.2.a 3 int.
// Check x <3 items> QList<nsA::nsB::SomeType*>.
// Continue.
dummyStatement(&map);
}
void testQMultiMapUintFloat()
{
QMultiMap<uint, float> map;
map.insert(11, 11.0);
map.insert(22, 22.0);
map.insert(22, 33.0);
map.insert(22, 34.0);
map.insert(22, 35.0);
map.insert(22, 36.0);
BREAK_HERE;
// Expand map.
// Check map <6 items> QMultiMap<unsigned int, float>.
// Check map.0 11 float.
// Check map.5 22 float.
// Continue.
dummyStatement(&map);
}
void testQMultiMapStringFloat()
{
QMultiMap<QString, float> map;
map.insert("22.0", 22.0);
BREAK_HERE;
// Expand map map.0.
// Check map <1 items> QMultiMap<QString, float>.
// Check map.0 QMapNode<QString, float>.
// Check map.0.key "22.0" QString.
// Check map.0.value 22 float.
// Continue.
dummyStatement(&map);
}
void testQMultiMapIntString()
{
QMultiMap<int, QString> map;
map.insert(22, "22.0");
BREAK_HERE;
// Expand map map.0.
// Check map <1 items> QMultiMap<int, QString>.
// Check map.0 QMapNode<int, QString>.
// Check map.0.key 22 int.
// Check map.0.value "22.0" QString.
// Continue.
dummyStatement(&map);
}
void testQMultiMapStringFoo()
{
QMultiMap<QString, Foo> map;
map.insert("22.0", Foo(22));
map.insert("33.0", Foo(33));
map.insert("22.0", Foo(22));
BREAK_HERE;
// Expand map map.0 map.0.value.
// Check map <3 items> QMultiMap<QString, Foo>.
// Check map.0 QMapNode<QString, Foo>.
// Check map.0.key "22.0" QString.
// CheckType map.0.value Foo.
// Check map.0.value.a 22 int.
// Check map.2 QMapNode<QString, Foo>.
// Continue.
dummyStatement(&map);
}
void testQMultiMapStringPointer()
{
QObject ob;
QMultiMap<QString, QPointer<QObject> > map;
map.insert("Hallo", QPointer<QObject>(&ob));
map.insert("Welt", QPointer<QObject>(&ob));
map.insert(".", QPointer<QObject>(&ob));
map.insert(".", QPointer<QObject>(&ob));
BREAK_HERE;
// Expand map map.0 map.1 map.2 map.3.
// Check map <4 items> QMultiMap<QString, QPointer<QObject>>.
// Check map.0 QMapNode<QString, QPointer<QObject>>.
// Check map.0.key "." QString.
// CheckType map.0.value QPointer<QObject>.
// Check map.1 QMapNode<QString, QPointer<QObject>>.
// Check map.1.key "." QString.
// Check map.2 QMapNode<QString, QPointer<QObject>>.
// Check map.2.key "Hallo" QString.
// Check map.3 QMapNode<QString, QPointer<QObject>>.
// Check map.3.key "Welt" QString.
// Continue.
dummyStatement(&map);
}
void testQMap()
{
testQMapUIntStringList();
testQMapUIntStringListTypedef();
testQMapUIntFloat();
testQMapStringFloat();
testQMapIntString();
testQMapStringFoo();
testQMapStringPointer();
testQMapStringList();
testQMultiMapUintFloat();
testQMultiMapStringFloat();
testQMultiMapIntString();
testQMultiMapStringFoo();
testQMapUIntStringList();
testQMultiMapStringFoo();
testQMultiMapStringPointer();
}
} // namespace qmap
namespace qobject {
void testQObject1()
{
// This checks whether signal-slot connections are displayed.
QObject parent;
parent.setObjectName("A Parent");
QObject child(&parent);
child.setObjectName("A Child");
QObject::connect(&child, SIGNAL(destroyed()), &parent, SLOT(deleteLater()));
QObject::connect(&child, SIGNAL(destroyed()), &child, SLOT(deleteLater()));
QObject::disconnect(&child, SIGNAL(destroyed()), &parent, SLOT(deleteLater()));
QObject::disconnect(&child, SIGNAL(destroyed()), &child, SLOT(deleteLater()));
child.setObjectName("A renamed Child");
BREAK_HERE;
// Check child "A renamed Child" QObject.
// Check parent "A Parent" QObject.
// Continue.
dummyStatement(&parent, &child);
}
namespace Names {
namespace Bar {
struct Ui { Ui() { w = 0; } QWidget *w; };
class TestObject : public QObject
{
Q_OBJECT
public:
TestObject(QObject *parent = 0)
: QObject(parent)
{
m_ui = new Ui;
#if USE_GUILIB
m_ui->w = new QWidget;
#else
m_ui->w = 0;
#endif
}
Q_PROPERTY(QString myProp1 READ myProp1 WRITE setMyProp1)
QString myProp1() const { return m_myProp1; }
Q_SLOT void setMyProp1(const QString&mt) { m_myProp1 = mt; }
Q_INVOKABLE void foo() {}
Q_PROPERTY(QString myProp2 READ myProp2 WRITE setMyProp2)
QString myProp2() const { return m_myProp2; }
Q_SLOT void setMyProp2(const QString&mt) { m_myProp2 = mt; }
Q_PROPERTY(long myProp3 READ myProp3)
long myProp3() const { return 54; }
Q_PROPERTY(long myProp4 READ myProp4)
long myProp4() const { return 44; }
Q_SIGNAL void sigFoo();
Q_SIGNAL void sigBar(int);
public:
Ui *m_ui;
QString m_myProp1;
QString m_myProp2;
};
} // namespace Bar
} // namespace Names
void testQObject2()
{
//QString longString = QString(10000, QLatin1Char('A'));
Names::Bar::TestObject test;
test.setMyProp1("HELLO");
test.setMyProp2("WORLD");
test.setObjectName("An object");
QString s = test.myProp1();
s += test.myProp2();
BREAK_HERE;
// Check s "HELLOWORLD" QString.
// Check test qobject::Names::Bar::TestObject.
// Continue.
dummyStatement(&s);
}
void testQObject3()
{
QAction act("xxx", qApp);
QString t = act.text();
t += "y";
t += "y";
t += "y";
t += "y";
t += "y";
dummyStatement(&act, &t);
}
void testQObject4()
{
#if USE_GUILIB
QWidget ob;
ob.setObjectName("An Object");
ob.setProperty("USER DEFINED 1", 44);
ob.setProperty("USER DEFINED 2", QStringList() << "FOO" << "BAR");
QObject ob1;
ob1.setObjectName("Another Object");
QObject::connect(&ob, SIGNAL(destroyed()), &ob1, SLOT(deleteLater()));
QObject::connect(&ob1, SIGNAL(destroyed()), &ob, SLOT(deleteLater()));
BREAK_HERE;
QObject::disconnect(&ob, SIGNAL(destroyed()), &ob1, SLOT(deleteLater()));
QObject::disconnect(&ob1, SIGNAL(destroyed()), &ob, SLOT(deleteLater()));
dummyStatement(&ob, &ob1);
#endif
}
void testQObject5()
{
QWidget ob;
ob.setObjectName("An Object");
ob.setProperty("USER DEFINED 1", 44);
ob.setProperty("USER DEFINED 2", QStringList() << "FOO" << "BAR");
QObject ob1;
QList<QObject *> obs;
obs.append(&ob);
obs.append(&ob1);
obs.append(0);
obs.append(qApp);
ob1.setObjectName("Another Object");
BREAK_HERE;
dummyStatement(&obs);
}
class Sender : public QObject
{
Q_OBJECT
public:
Sender() { setObjectName("Sender"); }
void doEmit() { emit aSignal(); }
signals:
void aSignal();
};
class Receiver : public QObject
{
Q_OBJECT
public:
Receiver() { setObjectName("Receiver"); }
public slots:
void aSlot() {
QObject *s = sender();
if (s) {
qDebug() << "SENDER: " << s;
} else {
qDebug() << "NO SENDER";
}
}
};
void testSignalSlot()
{
Sender sender;
Receiver receiver;
QObject::connect(&sender, SIGNAL(aSignal()), &receiver, SLOT(aSlot()));
// Break here.
// Single step through signal emission.
sender.doEmit();
dummyStatement(&sender, &receiver);
}
#if USE_PRIVATE
class DerivedObjectPrivate : public QObjectPrivate
{
public:
DerivedObjectPrivate() {
m_extraX = 43;
m_extraY.append("xxx");
m_extraZ = 1;
}
int m_extraX;
QStringList m_extraY;
uint m_extraZ : 1;
bool m_extraA : 1;
bool m_extraB;
};
class DerivedObject : public QObject
{
Q_OBJECT
public:
DerivedObject() : QObject(*new DerivedObjectPrivate, 0) {}
Q_PROPERTY(int x READ x WRITE setX)
Q_PROPERTY(QStringList y READ y WRITE setY)
Q_PROPERTY(uint z READ z WRITE setZ)
int x() const;
void setX(int x);
QStringList y() const;
void setY(QStringList y);
uint z() const;
void setZ(uint z);
private:
Q_DECLARE_PRIVATE(DerivedObject)
};
int DerivedObject::x() const
{
Q_D(const DerivedObject);
return d->m_extraX;
}
void DerivedObject::setX(int x)
{
Q_D(DerivedObject);
d->m_extraX = x;
d->m_extraA = !d->m_extraA;
d->m_extraB = !d->m_extraB;
}
QStringList DerivedObject::y() const
{
Q_D(const DerivedObject);
return d->m_extraY;
}
void DerivedObject::setY(QStringList y)
{
Q_D(DerivedObject);
d->m_extraY = y;
}
uint DerivedObject::z() const
{
Q_D(const DerivedObject);
return d->m_extraZ;
}
void DerivedObject::setZ(uint z)
{
Q_D(DerivedObject);
d->m_extraZ = z;
}
#endif
void testQObjectData()
{
// This checks whether QObject-derived classes with Q_PROPERTYs
// are displayed properly.
#if USE_PRIVATE
DerivedObject ob;
BREAK_HERE;
// Expand ob ob.properties.
// Check ob.properties.x 43 QVariant (int).
// Continue.
// expand ob and ob.properties
// step, and check whether x gets updated.
ob.setX(23);
ob.setX(25);
ob.setX(26);
BREAK_HERE;
// Expand ob ob.properties.
// Check ob.properties.x 26 QVariant (int).
// Continue.
#endif
}
void testQObject()
{
testQObjectData();
testQObject1();
testQObject2();
testQObject3();
testQObject4();
testQObject5();
testSignalSlot();
}
} // namespace qobject
namespace qregexp {
void testQRegExp()
{
// Works with Python dumpers only.
QRegExp re(QString("a(.*)b(.*)c"));
BREAK_HERE;
// Check re "a(.*)b(.*)c" QRegExp.
// Continue.
QString str1 = "a1121b344c";
QString str2 = "Xa1121b344c";
BREAK_HERE;
// Check str1 "a1121b344c" QString.
// Check str2 "Xa1121b344c" QString.
// Continue.
int pos2 = re.indexIn(str2);
int pos1 = re.indexIn(str1);
BREAK_HERE;
// Check pos1 0 int.
// Check pos2 1 int.
// Continue.
dummyStatement(&pos1, &pos2);
}
} // namespace qregexp
namespace qrect {
#if USE_GUILIB
void testQPoint()
{
QPoint s;
BREAK_HERE;
// Check s (0, 0) QPoint.
// Continue.
// Step over, check display looks sane.
s = QPoint(100, 200);
BREAK_HERE;
// Check s (100, 200) QPoint.
// Continue.
dummyStatement(&s);
}
void testQPointF()
{
QPointF s;
BREAK_HERE;
// Check s (0, 0) QPointF.
// Continue.
// Step over, check display looks sane.
s = QPointF(100, 200);
BREAK_HERE;
// Check s (100, 200) QPointF.
// Continue.
dummyStatement(&s);
}
void testQRect()
{
QRect rect;
BREAK_HERE;
// Check rect 0x0+0+0 QRect.
// Continue.
// Step over, check display looks sane.
rect = QRect(100, 100, 200, 200);
BREAK_HERE;
// Check rect 200x200+100+100 QRect.
// Continue.
dummyStatement(&rect);
}
void testQRectF()
{
QRectF rect;
BREAK_HERE;
// Check rect 0x0+0+0 QRectF.
// Continue.
// Step over, check display looks sane.
rect = QRectF(100, 100, 200, 200);
BREAK_HERE;
// Check rect 200x200+100+100 QRectF.
// Continue.
dummyStatement(&rect);
}
void testQSize()
{
QSize s;
BREAK_HERE;
// Check s (-1, -1) QSize.
// Continue.
s = QSize(100, 200);
BREAK_HERE;
// Check s (100, 200) QSize.
// Continue.
dummyStatement(&s);
}
void testQSizeF()
{
QSizeF s;
BREAK_HERE;
// Check s (-1, -1) QSizeF.
// Continue.
s = QSizeF(100, 200);
BREAK_HERE;
// Check s (100, 200) QSizeF.
// Continue.
dummyStatement(&s);
}
#endif
void testGeometry()
{
#if USE_GUILIB
testQPoint();
testQPointF();
testQRect();
testQRectF();
testQSize();
testQSizeF();
#endif
}
} // namespace qrect
namespace qregion {
void testQRegion()
{
#if USE_GUILIB
// Works with Python dumpers only.
QRegion region;
BREAK_HERE;
// Check region <empty> QRegion.
// Continue.
// Step over until end, check display looks sane.
region += QRect(100, 100, 200, 200);
BREAK_HERE;
// Expand region.
// Check region <1 items> QRegion.
// CheckType region.extents QRect.
// Check region.innerArea 40000 int.
// CheckType region.innerRect QRect.
// Check region.numRects 1 int.
// Check region.rects <0 items> QVector<QRect>.
// Continue.
region += QRect(300, 300, 400, 500);
BREAK_HERE;
// Expand region.
// Check region <2 items> QRegion.
// CheckType region.extents QRect.
// Check region.innerArea 200000 int.
// CheckType region.innerRect QRect.
// Check region.numRects 2 int.
// Check region.rects <2 items> QVector<QRect>.
// Continue.
region += QRect(500, 500, 600, 600);
BREAK_HERE;
// Expand region.
// Check region <4 items> QRegion.
// CheckType region.extents QRect.
// Check region.innerArea 360000 int.
// CheckType region.innerRect QRect.
// Check region.numRects 4 int.
// Check region.rects <8 items> QVector<QRect>.
// Continue.
region += QRect(500, 500, 600, 600);
BREAK_HERE;
// Check region <4 items> QRegion.
// Continue.
region += QRect(500, 500, 600, 600);
BREAK_HERE;
// Check region <4 items> QRegion.
// Continue.
region += QRect(500, 500, 600, 600);
BREAK_HERE;
// Check region <4 items> QRegion.
// Continue.
dummyStatement(&region);
#endif
}
} // namespace qregion
namespace plugin {
void testPlugin()
{
QString dir = QDir::currentPath();
#ifdef Q_OS_LINUX
QLibrary lib(dir + "/libsimple_test_plugin.so");
#endif
#ifdef Q_OS_MAC
dir = QFileInfo(dir + "/../..").canonicalPath();
QLibrary lib(dir + "/libsimple_test_plugin.dylib");
#endif
#ifdef Q_OS_WIN
QLibrary lib(dir + "/debug/simple_test_plugin.dll");
#endif
BREAK_HERE;
// CheckType dir QString.
// CheckType lib QLibrary.
// CheckType name QString.
// CheckType res int.
// Continue.
// Step
int (*foo)() = (int(*)()) lib.resolve("pluginTest");
QString name = lib.fileName();
int res = 4;
if (foo) {
BREAK_HERE;
// Check res 4 int.
// Continue.
// Step
res = foo();
} else {
BREAK_HERE;
// Step
name = lib.errorString();
}
dummyStatement(&name, &res);
}
} // namespace plugin
namespace final {
void testQSettings()
{
// Note: Construct a QCoreApplication first.
QSettings settings("/tmp/test.ini", QSettings::IniFormat);
QVariant value = settings.value("item1","").toString();
BREAK_HERE;
// Expand settings.
// Check settings QSettings.
// Check settings.@1 "" QObject.
// Check value "" QVariant (QString).
// Continue.
dummyStatement(&settings, &value);
}
void testNullPointerDeref()
{
int a = 'a';
int b = 'b';
BREAK_HERE;
// Continue.
return; // Uncomment.
*(int *)0 = a + b;
}
void testEndlessRecursion(int i = 0)
{
BREAK_HERE;
// Continue.
return; // Uncomment.
testEndlessRecursion(i + 1);
}
void testEndlessLoop()
{
qlonglong a = 1;
// gdb:
// Breakpoint at "while" will stop only once
// Hitting "Pause" button might show backtrace of different thread
BREAK_HERE;
// Continue.
// Jump over next line.
return;
while (a > 0)
++a;
dummyStatement(&a);
}
void testUncaughtException()
{
BREAK_HERE;
// Continue.
// Jump over next line.
return;
throw 42;
}
void testApplicationStart(QCoreApplication *app)
{
#if USE_GUILIB
QString str = QString::fromUtf8("XXXXXXXXXXXXXXyyXXX ö");
QLabel l(str);
l.setObjectName("Some Label");
l.show();
#endif
// Jump over next line.
return;
app->exec();
dummyStatement(&app);
}
void testNullReferenceHelper(int &i, int &j)
{
i += 1;
j += 1;
}
void testNullReference()
{
int i = 21;
int *p = &i;
int *q = 0;
int &pp = *p;
int &qq = *q;
BREAK_HERE;
// Check i 21 int.
// CheckType p int.
// Check p 21 int.
// Check q 0x0 int *.
// Check pp 21 int &.
// Check qq <null reference> int &.
// Continue.
return; // Uncomment.
testNullReferenceHelper(pp, qq);
dummyStatement(p, q, &i);
}
void testFinal(QCoreApplication *app)
{
// This contains all "final" tests that do not allow proceeding
// with further tests.
BREAK_HERE;
// Continue.
testQSettings();
testNullPointerDeref();
testNullReference();
testEndlessLoop();
testEndlessRecursion();
testUncaughtException();
testApplicationStart(app);
}
} // namespace final
namespace qset {
void testQSet1()
{
QSet<int> s;
s.insert(11);
s.insert(22);
BREAK_HERE;
// Expand s.
// Check s <2 items> QSet<int>.
// Check s.22 22 int.
// Check s.11 11 int.
// Continue.
dummyStatement(&s);
}
void testQSet2()
{
QSet<QString> s;
s.insert("11.0");
s.insert("22.0");
BREAK_HERE;
// Expand s.
// Check s <2 items> QSet<QString>.
// Check s.0 "11.0" QString.
// Check s.1 "22.0" QString.
// Continue.
dummyStatement(&s);
}
void testQSet3()
{
QObject ob;
QSet<QPointer<QObject> > s;
QPointer<QObject> ptr(&ob);
s.insert(ptr);
s.insert(ptr);
s.insert(ptr);
BREAK_HERE;
// Expand s.
// Check s <1 items> QSet<QPointer<QObject>>.
// CheckType s.0 QPointer<QObject>.
// Continue.
dummyStatement(&ptr, &s);
}
void testQSet()
{
testQSet1();
testQSet2();
testQSet3();
}
} // namespace qset
namespace qsharedpointer {
class EmployeeData : public QSharedData
{
public:
EmployeeData() : id(-1) { name.clear(); }
EmployeeData(const EmployeeData &other)
: QSharedData(other), id(other.id), name(other.name) { }
~EmployeeData() { }
int id;
QString name;
};
class Employee
{
public:
Employee() { d = new EmployeeData; }
Employee(int id, QString name) {
d = new EmployeeData;
setId(id);
setName(name);
}
Employee(const Employee &other)
: d (other.d)
{
}
void setId(int id) { d->id = id; }
void setName(QString name) { d->name = name; }
int id() const { return d->id; }
QString name() const { return d->name; }
private:
QSharedDataPointer<EmployeeData> d;
};
void testQSharedPointer1()
{
QSharedPointer<int> ptr(new int(43));
QSharedPointer<int> ptr2 = ptr;
QSharedPointer<int> ptr3 = ptr;
BREAK_HERE;
dummyStatement(&ptr, &ptr2, &ptr3);
}
void testQSharedPointer2()
{
QSharedPointer<QString> ptr(new QString("hallo"));
QSharedPointer<QString> ptr2 = ptr;
QSharedPointer<QString> ptr3 = ptr;
BREAK_HERE;
dummyStatement(&ptr, &ptr2, &ptr3);
}
void testQSharedPointer3()
{
QSharedPointer<int> iptr(new int(43));
QWeakPointer<int> ptr(iptr);
QWeakPointer<int> ptr2 = ptr;
QWeakPointer<int> ptr3 = ptr;
BREAK_HERE;
dummyStatement(&ptr, &ptr2, &ptr3);
}
void testQSharedPointer4()
{
QSharedPointer<QString> sptr(new QString("hallo"));
QWeakPointer<QString> ptr(sptr);
QWeakPointer<QString> ptr2 = ptr;
QWeakPointer<QString> ptr3 = ptr;
BREAK_HERE;
dummyStatement(&ptr, &ptr2, &ptr3);
}
void testQSharedPointer5()
{
QSharedPointer<Foo> fptr(new Foo(1));
QWeakPointer<Foo> ptr(fptr);
QWeakPointer<Foo> ptr2 = ptr;
QWeakPointer<Foo> ptr3 = ptr;
BREAK_HERE;
dummyStatement(&ptr, &ptr2, &ptr3);
}
void testQSharedPointer()
{
testQSharedPointer1();
testQSharedPointer2();
testQSharedPointer3();
testQSharedPointer4();
testQSharedPointer5();
}
} // namespace qsharedpointer
namespace qxml {
void testQXmlAttributes()
{
// only works with Python dumper
QXmlAttributes atts;
atts.append("name1", "uri1", "localPart1", "value1");
atts.append("name2", "uri2", "localPart2", "value2");
atts.append("name3", "uri3", "localPart3", "value3");
BREAK_HERE;
// Expand atts atts.attList atts.attList.1 atts.attList.2.
// CheckType atts QXmlAttributes.
// CheckType atts.[vptr] .
// Check atts.attList <3 items> QXmlAttributes::AttributeList.
// CheckType atts.attList.0 QXmlAttributes::Attribute.
// Check atts.attList.0.localname "localPart1" QString.
// Check atts.attList.0.qname "name1" QString.
// Check atts.attList.0.uri "uri1" QString.
// Check atts.attList.0.value "value1" QString.
// CheckType atts.attList.1 QXmlAttributes::Attribute.
// Check atts.attList.1.localname "localPart2" QString.
// Check atts.attList.1.qname "name2" QString.
// Check atts.attList.1.uri "uri2" QString.
// Check atts.attList.1.value "value2" QString.
// CheckType atts.attList.2 QXmlAttributes::Attribute.
// Check atts.attList.2.localname "localPart3" QString.
// Check atts.attList.2.qname "name3" QString.
// Check atts.attList.2.uri "uri3" QString.
// Check atts.attList.2.value "value3" QString.
// CheckType atts.d QXmlAttributesPrivate.
// Continue.
dummyStatement();
}
} // namespace qxml
namespace stdarray {
void testStdArray()
{
std::array<int, 4> a = { { 1, 2, 3, 4} };
std::array<QString, 4> b = { { "1", "2", "3", "4"} };
BREAK_HERE;
// Expand a.
// Check a <4 items> std::array<int, 4u>.
// Check a <4 items> std::array<QString, 4u>.
// Continue.
dummyStatement(&a, &b);
}
} // namespace stdcomplex
namespace stdcomplex {
void testStdComplex()
{
std::complex<double> c(1, 2);
BREAK_HERE;
// Expand c.
// Check c (1.000000, 2.000000) std::complex<double>.
// Continue.
dummyStatement(&c);
}
} // namespace stdcomplex
namespace stddeque {
void testStdDequeInt()
{
std::deque<int> deque;
deque.push_back(1);
deque.push_back(2);
BREAK_HERE;
// Expand deque.
// Check deque <2 items> std::deque<int>.
// Check deque.0 1 int.
// Check deque.1 2 int.
// Continue.
dummyStatement(&deque);
}
void testStdDequeIntStar()
{
// This is not supposed to work with the compiled dumpers.
std::deque<int *> deque;
deque.push_back(new int(1));
deque.push_back(0);
deque.push_back(new int(2));
BREAK_HERE;
// Expand deque.
// Check deque <3 items> std::deque<int*>.
// CheckType deque.0 int.
// Check deque.1 0x0 int *.
// Continue.
deque.pop_back();
deque.pop_front();
deque.pop_front();
dummyStatement(&deque);
}
void testStdDequeFoo()
{
std::deque<Foo> deque;
deque.push_back(1);
deque.push_front(2);
BREAK_HERE;
// Expand deque deque.0 deque.1.
// Check deque <2 items> std::deque<Foo>.
// CheckType deque.0 Foo.
// Check deque.0.a 2 int.
// CheckType deque.1 Foo.
// Check deque.1.a 1 int.
// Continue.
dummyStatement(&deque);
}
void testStdDequeFooStar()
{
std::deque<Foo *> deque;
deque.push_back(new Foo(1));
deque.push_back(new Foo(2));
BREAK_HERE;
// Expand deque deque.0 deque.1.
// Check deque <2 items> std::deque<Foo*>.
// CheckType deque.0 Foo.
// Check deque.0.a 1 int.
// CheckType deque.1 Foo.
// Check deque.1.a 2 int.
// Continue.
dummyStatement(&deque);
}
void testStdDeque()
{
testStdDequeInt();
testStdDequeIntStar();
testStdDequeFoo();
testStdDequeFooStar();
}
} // namespace stddeque
namespace stdhashset {
void testStdHashSet()
{
// This is not supposed to work with the compiled dumpers.
#if USE_GCC_EXT
using namespace __gnu_cxx;
hash_set<int> h;
h.insert(1);
h.insert(194);
h.insert(2);
h.insert(3);
BREAK_HERE;
// Expand h.
// Check h <4 items> __gnu__cxx::hash_set<int>.
// Check h.0 194 int.
// Check h.1 1 int.
// Check h.2 2 int.
// Check h.3 3 int.
// Continue.
dummyStatement(&h);
#endif
}
} // namespace stdhashset
namespace stdlist {
void testStdListInt()
{
std::list<int> list;
list.push_back(1);
list.push_back(2);
BREAK_HERE;
// Expand list.
// Check list <2 items> std::list<int>.
// Check list.0 1 int.
// Check list.1 2 int.
// Continue.
dummyStatement(&list);
}
void testStdListIntStar()
{
std::list<int *> list;
list.push_back(new int(1));
list.push_back(0);
list.push_back(new int(2));
BREAK_HERE;
// Expand list.
// Check list <3 items> std::list<int*>.
// CheckType list.0 int.
// Check list.1 0x0 int *.
// CheckType list.2 int.
// Continue.
dummyStatement(&list);
}
void testStdListIntBig()
{
// This is not supposed to work with the compiled dumpers.
std::list<int> list;
for (int i = 0; i < 10000; ++i)
list.push_back(i);
BREAK_HERE;
// Expand list.
// Check list <more than 1000 items> std::list<int>.
// Check list.0 0 int.
// Check list.999 999 int.
// Continue.
dummyStatement(&list);
}
void testStdListFoo()
{
std::list<Foo> list;
list.push_back(15);
list.push_back(16);
BREAK_HERE;
// Expand list list.0 list.1.
// Check list <2 items> std::list<Foo>.
// CheckType list.0 Foo.
// Check list.0.a 15 int.
// CheckType list.1 Foo.
// Check list.1.a 16 int.
// Continue.
dummyStatement(&list);
}
void testStdListFooStar()
{
std::list<Foo *> list;
list.push_back(new Foo(1));
list.push_back(0);
list.push_back(new Foo(2));
BREAK_HERE;
// Expand list list.0 list.2.
// Check list <3 items> std::list<Foo*>.
// CheckType list.0 Foo.
// Check list.0.a 1 int.
// Check list.1 0x0 Foo *.
// CheckType list.2 Foo.
// Check list.2.a 2 int.
// Continue.
dummyStatement(&list);
}
void testStdListBool()
{
std::list<bool> list;
list.push_back(true);
list.push_back(false);
BREAK_HERE;
// Expand list.
// Check list <2 items> std::list<bool>.
// Check list.0 true bool.
// Check list.1 false bool.
// Continue.
dummyStatement(&list);
}
void testStdList()
{
testStdListInt();
testStdListIntStar();
testStdListIntBig();
testStdListFoo();
testStdListFooStar();
testStdListBool();
}
} // namespace stdlist
namespace stdunorderedmap {
void testStdUnorderedMapStringFoo()
{
// This is not supposed to work with the compiled dumpers.
std::unordered_map<std::string, Foo> map;
map["22.0"] = Foo(22);
map["33.0"] = Foo(33);
map["44.0"] = Foo(44);
BREAK_HERE;
// Expand map map.0 map.0.second map.2 map.2.second.
// Check map <3 items> std::unordered_map<QString, Foo>.
// Check map.0 std::pair<QString const, Foo>.
// Check map.0.first "22.0" QString.
// CheckType map.0.second Foo.
// Check map.0.second.a 22 int.
// Check map.1 std::pair<QString const, Foo>.
// Check map.2.first "44.0" QString.
// CheckType map.2.second Foo.
// Check map.2.second.a 44 int.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMapCharStarFoo()
{
std::unordered_map<const char *, Foo> map;
map["22.0"] = Foo(22);
map["33.0"] = Foo(33);
BREAK_HERE;
// Expand map map.0 map.0.first map.0.second map.1 map.1.second.
// Check map <2 items> std::unordered_map<char const*, Foo>.
// Check map.0 std::pair<char const* const, Foo>.
// CheckType map.0.first char *.
// Check map.0.first.*first 50 '2' char.
// CheckType map.0.second Foo.
// Check map.0.second.a 22 int.
// Check map.1 std::pair<char const* const, Foo>.
// CheckType map.1.first char *.
// Check map.1.first.*first 51 '3' char.
// CheckType map.1.second Foo.
// Check map.1.second.a 33 int.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMapUIntUInt()
{
std::unordered_map<uint, uint> map;
map[11] = 1;
map[22] = 2;
BREAK_HERE;
// Expand map.
// Check map <2 items> std::unordered_map<unsigned int, unsigned int>.
// Check map.11 1 unsigned int.
// Check map.22 2 unsigned int.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMapUIntStringList()
{
#if 0
std::unordered_map<uint, QStringList> map;
map[11] = QStringList() << "11";
map[22] = QStringList() << "22";
BREAK_HERE;
// Expand map map.0 map.0.first map.0.second map.1 map.1.second.
// Check map <2 items> std::unordered_map<unsigned int, QStringList>.
// Check map.0 std::pair<unsigned int const, QStringList>.
// Check map.0.first 11 unsigned int.
// Check map.0.second <1 items> QStringList.
// Check map.0.second.0 "11" QString.
// Check map.1 std::pair<unsigned int const, QStringList>.
// Check map.1.first 22 unsigned int.
// Check map.1.second <1 items> QStringList.
// Check map.1.second.0 "22" QString.
// Continue.
dummyStatement(&map);
#endif
}
void testStdUnorderedMapUIntStringListTypedef()
{
#if 0
typedef std::unordered_map<uint, QStringList> T;
T map;
map[11] = QStringList() << "11";
map[22] = QStringList() << "22";
BREAK_HERE;
// Check map <2 items> stdmap::T.
// Continue.
dummyStatement(&map);
#endif
}
void testStdUnorderedMapUIntFloat()
{
std::unordered_map<uint, float> map;
map[11] = 11.0;
map[22] = 22.0;
BREAK_HERE;
// Expand map.
// Check map <2 items> std::unordered_map<unsigned int, float>.
// Check map.11 11 float.
// Check map.22 22 float.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMapUIntFloatIterator()
{
typedef std::unordered_map<int, float> Map;
Map map;
map[11] = 11.0;
map[22] = 22.0;
map[33] = 33.0;
map[44] = 44.0;
map[55] = 55.0;
map[66] = 66.0;
Map::iterator it1 = map.begin();
Map::iterator it2 = it1; ++it2;
Map::iterator it3 = it2; ++it3;
Map::iterator it4 = it3; ++it4;
Map::iterator it5 = it4; ++it5;
Map::iterator it6 = it5; ++it6;
BREAK_HERE;
// Expand map.
// Check map <6 items> stdmap::Map.
// Check map.11 11 float.
// Check it1.first 11 int.
// Check it1.second 11 float.
// Check it6.first 66 int.
// Check it6.second 66 float.
// Continue.
dummyStatement(&map, &it1, &it2, &it3, &it4, &it5, &it6);
}
void testStdUnorderedMapStringFloat()
{
std::unordered_map<std::string, float> map;
map["11.0"] = 11.0;
map["22.0"] = 22.0;
BREAK_HERE;
// Expand map map.0 map.1.
// Check map <2 items> std::unordered_map<QString, float>.
// Check map.0 std::pair<QString const, float>.
// Check map.0.first "11.0" QString.
// Check map.0.second 11 float.
// Check map.1 std::pair<QString const, float>.
// Check map.1.first "22.0" QString.
// Check map.1.second 22 float.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMapIntString()
{
std::unordered_map<int, QString> map;
map[11] = "11.0";
map[22] = "22.0";
BREAK_HERE;
// Expand map map.0 map.1.
// Check map <2 items> std::unordered_map<int, QString>.
// Check map.0 std::pair<int const, QString>.
// Check map.0.first 11 int.
// Check map.0.second "11.0" QString.
// Check map.1 std::pair<int const, QString>.
// Check map.1.first 22 int.
// Check map.1.second "22.0" QString.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMapStringPointer()
{
QObject ob;
std::unordered_map<std::string, QPointer<QObject> > map;
map["Hallo"] = QPointer<QObject>(&ob);
map["Welt"] = QPointer<QObject>(&ob);
map["."] = QPointer<QObject>(&ob);
BREAK_HERE;
// Expand map map.0 map.2.
// Check map <3 items> std::unordered_map<QString, QPointer<QObject>>.
// Check map.0 std::pair<QString const, QPointer<QObject>>.
// Check map.0.first "." QString.
// CheckType map.0.second QPointer<QObject>.
// Check map.2 std::pair<QString const, QPointer<QObject>>.
// Check map.2.first "Welt" QString.
// Continue.
dummyStatement(&map);
}
void testStdUnorderedMap()
{
testStdUnorderedMapStringFoo();
testStdUnorderedMapCharStarFoo();
testStdUnorderedMapUIntUInt();
testStdUnorderedMapUIntStringList();
testStdUnorderedMapUIntStringListTypedef();
testStdUnorderedMapUIntFloat();
testStdUnorderedMapUIntFloatIterator();
testStdUnorderedMapStringFloat();
testStdUnorderedMapIntString();
testStdUnorderedMapStringPointer();
}
} // namespace stdunorderedmap
namespace stdmap {
void testStdMapStringFoo()
{
// This is not supposed to work with the compiled dumpers.
std::map<QString, Foo> map;
map["22.0"] = Foo(22);
map["33.0"] = Foo(33);
map["44.0"] = Foo(44);
BREAK_HERE;
// Expand map map.0 map.0.second map.2 map.2.second.
// Check map <3 items> std::map<QString, Foo>.
// Check map.0 std::pair<QString const, Foo>.
// Check map.0.first "22.0" QString.
// CheckType map.0.second Foo.
// Check map.0.second.a 22 int.
// Check map.1 std::pair<QString const, Foo>.
// Check map.2.first "44.0" QString.
// CheckType map.2.second Foo.
// Check map.2.second.a 44 int.
// Continue.
dummyStatement(&map);
}
void testStdMapCharStarFoo()
{
std::map<const char *, Foo> map;
map["22.0"] = Foo(22);
map["33.0"] = Foo(33);
BREAK_HERE;
// Expand map map.0 map.0.first map.0.second map.1 map.1.second.
// Check map <2 items> std::map<char const*, Foo>.
// Check map.0 std::pair<char const* const, Foo>.
// CheckType map.0.first char *.
// Check map.0.first.*first 50 '2' char.
// CheckType map.0.second Foo.
// Check map.0.second.a 22 int.
// Check map.1 std::pair<char const* const, Foo>.
// CheckType map.1.first char *.
// Check map.1.first.*first 51 '3' char.
// CheckType map.1.second Foo.
// Check map.1.second.a 33 int.
// Continue.
dummyStatement(&map);
}
void testStdMapUIntUInt()
{
std::map<uint, uint> map;
map[11] = 1;
map[22] = 2;
BREAK_HERE;
// Expand map.
// Check map <2 items> std::map<unsigned int, unsigned int>.
// Check map.11 1 unsigned int.
// Check map.22 2 unsigned int.
// Continue.
dummyStatement(&map);
}
void testStdMapUIntStringList()
{
std::map<uint, QStringList> map;
map[11] = QStringList() << "11";
map[22] = QStringList() << "22";
BREAK_HERE;
// Expand map map.0 map.0.first map.0.second map.1 map.1.second.
// Check map <2 items> std::map<unsigned int, QStringList>.
// Check map.0 std::pair<unsigned int const, QStringList>.
// Check map.0.first 11 unsigned int.
// Check map.0.second <1 items> QStringList.
// Check map.0.second.0 "11" QString.
// Check map.1 std::pair<unsigned int const, QStringList>.
// Check map.1.first 22 unsigned int.
// Check map.1.second <1 items> QStringList.
// Check map.1.second.0 "22" QString.
// Continue.
dummyStatement(&map);
}
void testStdMapUIntStringListTypedef()
{
typedef std::map<uint, QStringList> T;
T map;
map[11] = QStringList() << "11";
map[22] = QStringList() << "22";
BREAK_HERE;
// Check map <2 items> stdmap::T.
// Continue.
dummyStatement(&map);
}
void testStdMapUIntFloat()
{
std::map<uint, float> map;
map[11] = 11.0;
map[22] = 22.0;
BREAK_HERE;
// Expand map.
// Check map <2 items> std::map<unsigned int, float>.
// Check map.11 11 float.
// Check map.22 22 float.
// Continue.
dummyStatement(&map);
}
void testStdMapUIntFloatIterator()
{
typedef std::map<int, float> Map;
Map map;
map[11] = 11.0;
map[22] = 22.0;
map[33] = 33.0;
map[44] = 44.0;
map[55] = 55.0;
map[66] = 66.0;
Map::iterator it1 = map.begin();
Map::iterator it2 = it1; ++it2;
Map::iterator it3 = it2; ++it3;
Map::iterator it4 = it3; ++it4;
Map::iterator it5 = it4; ++it5;
Map::iterator it6 = it5; ++it6;
BREAK_HERE;
// Expand map.
// Check map <6 items> stdmap::Map.
// Check map.11 11 float.
// Check it1.first 11 int.
// Check it1.second 11 float.
// Check it6.first 66 int.
// Check it6.second 66 float.
// Continue.
dummyStatement(&map, &it1, &it2, &it3, &it4, &it5, &it6);
}
void testStdMapStringFloat()
{
std::map<QString, float> map;
map["11.0"] = 11.0;
map["22.0"] = 22.0;
BREAK_HERE;
// Expand map map.0 map.1.
// Check map <2 items> std::map<QString, float>.
// Check map.0 std::pair<QString const, float>.
// Check map.0.first "11.0" QString.
// Check map.0.second 11 float.
// Check map.1 std::pair<QString const, float>.
// Check map.1.first "22.0" QString.
// Check map.1.second 22 float.
// Continue.
dummyStatement(&map);
}
void testStdMapIntString()
{
std::map<int, QString> map;
map[11] = "11.0";
map[22] = "22.0";
BREAK_HERE;
// Expand map map.0 map.1.
// Check map <2 items> std::map<int, QString>.
// Check map.0 std::pair<int const, QString>.
// Check map.0.first 11 int.
// Check map.0.second "11.0" QString.
// Check map.1 std::pair<int const, QString>.
// Check map.1.first 22 int.
// Check map.1.second "22.0" QString.
// Continue.
dummyStatement(&map);
}
void testStdMapStringPointer()
{
QObject ob;
std::map<QString, QPointer<QObject> > map;
map["Hallo"] = QPointer<QObject>(&ob);
map["Welt"] = QPointer<QObject>(&ob);
map["."] = QPointer<QObject>(&ob);
BREAK_HERE;
// Expand map map.0 map.2.
// Check map <3 items> std::map<QString, QPointer<QObject>>.
// Check map.0 std::pair<QString const, QPointer<QObject>>.
// Check map.0.first "." QString.
// CheckType map.0.second QPointer<QObject>.
// Check map.2 std::pair<QString const, QPointer<QObject>>.
// Check map.2.first "Welt" QString.
// Continue.
dummyStatement(&map);
}
void testStdMultiMapUIntFloat()
{
typedef std::pair<uint, float> V;
std::multimap<uint, float> map;
map.insert(V(11, 11.0f));
map.insert(V(22, 22.0f));
map.insert(V(22, 33.0f));
map.insert(V(22, 34.0f));
map.insert(V(22, 35.0f));
map.insert(V(22, 36.0f));
BREAK_HERE;
// Expand map.
// Check map <6 items> std:multimap<unsigned int, float>.
// Check map.0 11 float.
// Check map.5 22 float.
// Continue.
dummyStatement(&map);
}
void testStdMultiSetInt()
{
#ifndef Q_CC_MSVC
std::multiset<int> set = {1, 1, 2, 3, 3, 3};
BREAK_HERE;
dummyStatement(&set);
#endif
}
void testStdMap()
{
testStdMapStringFoo();
testStdMapCharStarFoo();
testStdMapUIntUInt();
testStdMapUIntStringList();
testStdMapUIntStringListTypedef();
testStdMapUIntFloat();
testStdMapUIntFloatIterator();
testStdMapStringFloat();
testStdMapIntString();
testStdMapStringPointer();
testStdMultiMapUIntFloat();
testStdMultiSetInt();
}
} // namespace stdmap
namespace stdptr {
void testStdUniquePtrInt()
{
std::unique_ptr<int> p(new int(32));
BREAK_HERE;
// Check p 32 std::unique_ptr<int, std::default_delete<int> >.
// Continue.
dummyStatement(&p);
}
void testStdUniquePtrFoo()
{
std::unique_ptr<Foo> p(new Foo);
BREAK_HERE;
// Check p 32 std::unique_ptr<Foo, std::default_delete<Foo> >.
// Continue.
dummyStatement(&p);
}
void testStdSharedPtrInt()
{
std::shared_ptr<int> p(new int(32));
BREAK_HERE;
// Check p 32 std::shared_ptr<int, std::default_delete<int> >.
// Continue.
dummyStatement(&p);
}
void testStdSharedPtrFoo()
{
std::shared_ptr<Foo> p(new Foo);
BREAK_HERE;
// Check p 32 std::shared_ptr<Foo, std::default_delete<int> >.
// Continue.
dummyStatement(&p);
}
void testStdPtr()
{
testStdUniquePtrInt();
testStdUniquePtrFoo();
testStdSharedPtrInt();
testStdSharedPtrFoo();
}
} // namespace stdptr
namespace lambda {
void testLambda()
{
std::string x;
auto f = [&] () -> const std::string & {
int z = x.size();
Q_UNUSED(z);
return x;
};
auto c = f();
BREAK_HERE;
dummyStatement(&x, &f, &c);
}
} // namespace lambda
namespace stdset {
void testStdSetInt()
{
// This is not supposed to work with the compiled dumpers.
std::set<int> set;
set.insert(11);
set.insert(22);
set.insert(33);
BREAK_HERE;
// Check set <3 items> std::set<int>
// Continue.
dummyStatement(&set);
}
void testStdSetIntIterator()
{
typedef std::set<int> Set;
Set set;
set.insert(11);
set.insert(22);
set.insert(33);
set.insert(44);
set.insert(55);
set.insert(66);
Set::iterator it1 = set.begin();
Set::iterator it2 = it1; ++it2;
Set::iterator it3 = it2; ++it3;
Set::iterator it4 = it3; ++it4;
Set::iterator it5 = it4; ++it5;
Set::iterator it6 = it5; ++it6;
BREAK_HERE;
// Check set <6 items> stdset::Set.
// Check it1.value 11 int.
// Check it6.value 66 int.
// Continue.
dummyStatement(&set, &it1, &it2, &it3, &it4, &it5, &it6);
}
void testStdSetString()
{
std::set<QString> set;
set.insert("22.0");
BREAK_HERE;
// Expand set.
// Check set <1 items> std::set<QString>.
// Check set.0 "22.0" QString.
// Continue.
dummyStatement(&set);
}
void testStdSetPointer()
{
QObject ob;
std::set<QPointer<QObject> > hash;
QPointer<QObject> ptr(&ob);
BREAK_HERE;
// Check hash <0 items> std::set<QPointer<QObject>, std::less<QPointer<QObject>>, std::allocator<QPointer<QObject>>>.
// Check ob "" QObject.
// CheckType ptr QPointer<QObject>.
// Continue.
dummyStatement(&ptr);
}
void testStdSet()
{
testStdSetInt();
testStdSetIntIterator();
testStdSetString();
testStdSetPointer();
}
} // namespace stdset
namespace stdstack {
void testStdStack1()
{
// This does not work with the compiled dumpers.
std::stack<int *> s;
BREAK_HERE;
// Check s <0 items> std::stack<int*>.
// Continue.
s.push(new int(1));
BREAK_HERE;
// Check s <1 items> std::stack<int*>.
// Continue.
s.push(0);
BREAK_HERE;
// Check s <2 items> std::stack<int*>.
// Continue.
s.push(new int(2));
BREAK_HERE;
// Expand s.
// Check s <3 items> std::stack<int*>.
// CheckType s.0 int.
// Check s.1 0x0 int *.
// CheckType s.2 int.
// Continue.
s.pop();
BREAK_HERE;
// Check s <2 items> std::stack<int*>.
// Continue.
s.pop();
BREAK_HERE;
// Check s <1 items> std::stack<int*>.
// Continue.
s.pop();
BREAK_HERE;
// Check s <0 items> std::stack<int*>.
// Continue.
dummyStatement(&s);
}
void testStdStack2()
{
std::stack<int> s;
BREAK_HERE;
// Check s <0 items> std::stack<int>.
// Continue.
s.push(1);
BREAK_HERE;
// Check s <1 items> std::stack<int>.
// Continue.
s.push(2);
BREAK_HERE;
// Expand s.
// Check s <2 items> std::stack<int>.
// Check s.0 1 int.
// Check s.1 2 int.
// Continue.
dummyStatement(&s);
}
void testStdStack3()
{
std::stack<Foo *> s;
BREAK_HERE;
// Check s <0 items> std::stack<Foo*>.
// Continue.
s.push(new Foo(1));
BREAK_HERE;
// Check s <1 items> std::stack<Foo*>.
// Continue.
s.push(new Foo(2));
BREAK_HERE;
// Expand s s.0 s.1.
// Check s <2 items> std::stack<Foo*>.
// CheckType s.0 Foo.
// Check s.0.a 1 int.
// CheckType s.1 Foo.
// Check s.1.a 2 int.
// Continue.
dummyStatement(&s);
}
void testStdStack4()
{
std::stack<Foo> s;
BREAK_HERE;
// Check s <0 items> std::stack<Foo>.
// Continue.
s.push(1);
BREAK_HERE;
// Check s <1 items> std::stack<Foo>.
// Continue.
s.push(2);
BREAK_HERE;
// Expand s s.0 s.1.
// Check s <2 items> std::stack<Foo>.
// CheckType s.0 Foo.
// Check s.0.a 1 int.
// CheckType s.1 Foo.
// Check s.1.a 2 int.
// Continue.
dummyStatement(&s);
}
void testStdStack()
{
testStdStack1();
testStdStack2();
testStdStack3();
testStdStack4();
}
} // namespace stdstack
namespace stdstring {
void testStdString1()
{
std::string str;
std::wstring wstr;
BREAK_HERE;
// Check str "" std::string.
// Check wstr "" std::wstring.
// Continue.
str += "b";
wstr += wchar_t('e');
str += "d";
wstr += wchar_t('e');
str += "e";
str += "b";
str += "d";
str += "e";
wstr += wchar_t('e');
wstr += wchar_t('e');
str += "e";
BREAK_HERE;
// Check str "bdebdee" std::string.
// Check wstr "eeee" std::wstring.
// Continue.
dummyStatement(&str, &wstr);
}
void testStdString2()
{
std::string str = "foo";
QList<std::string> l;
BREAK_HERE;
// Check l <0 items> QList<std::string>.
// Check str "foo" std::string.
// Continue.
l.push_back(str);
BREAK_HERE;
// Check l <1 items> QList<std::string>.
// Continue.
l.push_back(str);
BREAK_HERE;
// Check l <2 items> QList<std::string>.
// Continue.
l.push_back(str);
BREAK_HERE;
// Check l <3 items> QList<std::string>.
// Continue.
l.push_back(str);
BREAK_HERE;
// Expand l.
// Check l <4 items> QList<std::string>.
// CheckType l.0 std::string.
// CheckType l.3 std::string.
// Check str "foo" std::string.
// Continue.
dummyStatement(&str, &l);
}
void testStdString3()
{
std::string str = "foo";
std::vector<std::string> v;
BREAK_HERE;
// Check str "foo" std::string.
// Check v <0 items> std::vector<std::string>.
// Continue.
v.push_back(str);
BREAK_HERE;
// Check v <1 items> std::vector<std::string>.
// Continue.
v.push_back(str);
BREAK_HERE;
// Check v <2 items> std::vector<std::string>.
// Continue.
v.push_back(str);
BREAK_HERE;
// Check v <3 items> std::vector<std::string>.
// Continue.
v.push_back(str);
BREAK_HERE;
// Expand v.
// Check v <4 items> std::vector<std::string>.
// Check v.0 "foo" std::string.
// Check v.3 "foo" std::string.
// Continue.
dummyStatement(&str, &v);
}
void testStdString()
{
testStdString1();
testStdString2();
testStdString3();
}
} // namespace stdstring
namespace stdvector {
void testStdVector1()
{
std::vector<int *> v;
BREAK_HERE;
// Check v <0 items> std::vector<int*>.
// Continue.
v.push_back(new int(1));
BREAK_HERE;
// Check v <1 items> std::vector<int*>.
// Continue.
v.push_back(0);
BREAK_HERE;
// Check v <2 items> std::vector<int*>.
// Continue.
v.push_back(new int(2));
BREAK_HERE;
// Expand v.
// Check v <3 items> std::vector<int*>.
// Check v.0 1 int.
// Check v.1 0x0 int *.
// Check v.2 2 int.
// Continue.
dummyStatement(&v);
}
void testStdVector2()
{
std::vector<int> v;
v.push_back(1);
v.push_back(2);
v.push_back(3);
v.push_back(4);
BREAK_HERE;
// Expand v.
// Check v <4 items> std::vector<int>.
// Check v.0 1 int.
// Check v.3 4 int.
// Continue.
dummyStatement(&v);
}
void testStdVector3()
{
std::vector<Foo *> v;
v.push_back(new Foo(1));
v.push_back(0);
v.push_back(new Foo(2));
BREAK_HERE;
// Expand v v.0 v.0.x v.2.
// Check v <3 items> std::vector<Foo*>.
// CheckType v.0 Foo.
// Check v.0.a 1 int.
// Check v.1 0x0 Foo *.
// CheckType v.2 Foo.
// Check v.2.a 2 int.
// Continue.
dummyStatement(&v);
}
void testStdVector4()
{
std::vector<Foo> v;
v.push_back(1);
v.push_back(2);
v.push_back(3);
v.push_back(4);
BREAK_HERE;
// Expand v v.0 v.0.x.
// Check v <4 items> std::vector<Foo>.
// CheckType v.0 Foo.
// Check v.1.a 2 int.
// CheckType v.3 Foo.
// Continue.
dummyStatement(&v);
}
void testStdVectorBool1()
{
std::vector<bool> v;
v.push_back(true);
v.push_back(false);
v.push_back(false);
v.push_back(true);
v.push_back(false);
BREAK_HERE;
// Expand v.
// Check v <5 items> std::vector<bool>.
// Check v.0 true bool.
// Check v.1 false bool.
// Check v.2 false bool.
// Check v.3 true bool.
// Check v.4 false bool.
// Continue.
dummyStatement(&v);
}
void testStdVectorBool2()
{
std::vector<bool> v1(65, true);
std::vector<bool> v2(65);
BREAK_HERE;
// Expand v1.
// Expand v2.
// Check v1 <65 items> std::vector<bool>.
// Check v1.0 true bool.
// Check v1.64 true bool.
// Check v2 <65 items> std::vector<bool>.
// Check v2.0 false bool.
// Check v2.64 false bool.
// Continue.
dummyStatement(&v1, &v2);
}
void testStdVector6()
{
std::vector<std::list<int> *> vector;
std::list<int> list;
vector.push_back(new std::list<int>(list));
vector.push_back(0);
list.push_back(45);
vector.push_back(new std::list<int>(list));
vector.push_back(0);
BREAK_HERE;
// Expand list vector vector.2.
// Check list <1 items> std::list<int>.
// Check list.0 45 int.
// Check vector <4 items> std::vector<std::list<int>*>.
// Check vector.0 <0 items> std::list<int>.
// Check vector.2 <1 items> std::list<int>.
// Check vector.2.0 45 int.
// Check vector.3 0x0 std::list<int> *.
// Continue.
dummyStatement(&vector, &list);
}
void testStdVector()
{
testStdVector1();
testStdVector2();
testStdVector3();
testStdVector4();
testStdVectorBool1();
testStdVectorBool2();
testStdVector6();
}
} // namespace stdvector
namespace stdstream {
void testStdStream()
{
using namespace std;
ifstream is;
BREAK_HERE;
// CheckType is std::ifstream.
// Continue.
#ifdef Q_OS_WIN
is.open("C:\\Program Files\\Windows NT\\Accessories\\wordpad.exe");
#else
is.open("/etc/passwd");
#endif
BREAK_HERE;
// Continue.
bool ok = is.good();
BREAK_HERE;
// Check ok true bool.
// Continue.
dummyStatement(&is, &ok);
}
} // namespace stdstream
namespace itemmodel {
void testItemModel()
{
#if USE_GUILIB
//char buf[100];
//QString *s = static_cast<QString *>(static_cast<void *>(&(v.data_ptr().data.c)));
//QString *t = (QString *)&(v.data_ptr());
QStandardItemModel m;
QStandardItem *i1, *i2, *i11;
m.appendRow(QList<QStandardItem *>()
<< (i1 = new QStandardItem("1")) << (new QStandardItem("a")) << (new QStandardItem("a2")));
QModelIndex mi = i1->index();
m.appendRow(QList<QStandardItem *>()
<< (i2 = new QStandardItem("2")) << (new QStandardItem("b")));
i1->appendRow(QList<QStandardItem *>()
<< (i11 = new QStandardItem("11")) << (new QStandardItem("aa")));
BREAK_HERE;
// CheckType i1 QStandardItem.
// CheckType i11 QStandardItem.
// CheckType i2 QStandardItem.
// Check m QStandardItemModel.
// Check mi "1" QModelIndex.
// Continue.
dummyStatement(&i1, &mi, &m, &i2, &i11);
#endif
}
} // namespace itemmodel
namespace qstack {
void testQStackInt()
{
QStack<int> s;
s.append(1);
s.append(2);
BREAK_HERE;
// Expand s.
// Check s <2 items> QStack<int>.
// Check s.0 1 int.
// Check s.1 2 int.
// Continue.
dummyStatement(&s);
}
void testQStackBig()
{
QStack<int> s;
for (int i = 0; i != 10000; ++i)
s.append(i);
BREAK_HERE;
// Expand s.
// Check s <10000 items> QStack<int>.
// Check s.0 0 int.
// Check s.1999 1999 int.
// Continue.
dummyStatement(&s);
}
void testQStackFooPointer()
{
QStack<Foo *> s;
s.append(new Foo(1));
s.append(0);
s.append(new Foo(2));
BREAK_HERE;
// Expand s s.0 s.2.
// Check s <3 items> QStack<Foo*>.
// CheckType s.0 Foo.
// Check s.0.a 1 int.
// Check s.1 0x0 Foo *.
// CheckType s.2 Foo.
// Check s.2.a 2 int.
// Continue.
dummyStatement(&s);
}
void testQStackFoo()
{
QStack<Foo> s;
s.append(1);
s.append(2);
s.append(3);
s.append(4);
BREAK_HERE;
// Expand s s.0 s.3.
// Check s <4 items> QStack<Foo>.
// CheckType s.0 Foo.
// Check s.0.a 1 int.
// CheckType s.3 Foo.
// Check s.3.a 4 int.
// Continue.
dummyStatement(&s);
}
void testQStackBool()
{
QStack<bool> s;
s.append(true);
s.append(false);
BREAK_HERE;
// Expand s.
// Check s <2 items> QStack<bool>.
// Check s.0 true bool.
// Check s.1 false bool.
// Continue.
dummyStatement(&s);
}
void testQStack()
{
testQStackInt();
testQStackBig();
testQStackFoo();
testQStackFooPointer();
testQStackBool();
}
} // namespace qstack
namespace qurl {
void testQUrl()
{
QUrl url(QString("http://qt-project.org"));
BREAK_HERE;
// Check url "http://qt-project.org" QUrl.
// Continue.
dummyStatement(&url);
}
} // namespace qurl
namespace qstring {
void testQStringQuotes()
{
QString str1("Hello Qt"); // --> Value: "Hello Qt"
QString str2("Hello\nQt"); // --> Value: ""Hello\nQt"" (double quote not expected)
QString str3("Hello\rQt"); // --> Value: ""HelloQt"" (double quote and missing \r not expected)
QString str4("Hello\tQt"); // --> Value: "Hello\9Qt" (expected \t instead of \9)
BREAK_HERE;
// Check str1 "Hello Qt" QString.
// Check str2 "Hello\nQt" QString.
// Check str3 "Hello\rQt" QString.
// Check str4 "Hello\tQt" QString.
// Continue.
dummyStatement(&str1, &str2, &str3, &str4);
}
void testQString1()
{
QString str = "Hello ";
str += " big, ";
str += "\t";
str += "\r";
str += "\n";
str += QLatin1Char(0);
str += QLatin1Char(1);
str += " fat ";
str += " World";
str.prepend("Prefix: ");
BREAK_HERE;
// Check str "Prefix: Hello big, \t\r\n\000\001 fat World" QString.
// Continue.
dummyStatement(&str);
}
void testQString2()
{
QChar data[] = { 'H', 'e', 'l', 'l', 'o' };
QString str1 = QString::fromRawData(data, 4);
QString str2 = QString::fromRawData(data + 1, 4);
BREAK_HERE;
// Check str1 "Hell" QString.
// Check str2 "ello" QString.
// Continue.
dummyStatement(&str1, &str2, &data);
}
void stringRefTest(const QString &refstring)
{
dummyStatement(&refstring);
}
void testQString3()
{
QString str = "Hello ";
str += " big, ";
str += " fat ";
str += " World ";
QString string("String Test");
QString *pstring = new QString("Pointer String Test");
stringRefTest(QString("Ref String Test"));
string = "Hi";
string += "Du";
qDebug() << string;
BREAK_HERE;
// CheckType pstring QString.
// Check str "Hello big, fat World " QString.
// Check string "HiDu" QString.
// Continue.
delete pstring;
dummyStatement(&str, &string, pstring);
}
void testQString4()
{
QString str;
for (int i = 0; i < 1000000; ++i)
str += QString::fromLatin1("%1 ").arg(i);
BREAK_HERE;
BREAK_HERE;
BREAK_HERE;
BREAK_HERE;
dummyStatement(&str);
}
void testQStringRef()
{
QString str = "Hello";
QStringRef ref(&str, 1, 2);
BREAK_HERE;
// Check ref "el" QStringRef.
// Continue.
dummyStatement(&str, &ref);
}
void testQString()
{
testQString1();
testQString2();
testQString3();
testQString4();
testQStringRef();
testQStringQuotes();
}
} // namespace qstring
namespace qstringlist {
void testQStringList()
{
QStringList l;
l << "Hello ";
l << " big, ";
l << " fat ";
l.takeFirst();
l << " World ";
BREAK_HERE;
// Expand l.
// Check l <3 items> QStringList.
// Check l.0 " big, " QString.
// Check l.1 " fat " QString.
// Check l.2 " World " QString.
// Continue.
dummyStatement(&l);
}
} // namespace qstringlist
namespace formats {
void testString()
{
const wchar_t *w = L"aöa";
QString u;
if (sizeof(wchar_t) == 4)
u = QString::fromUcs4((uint *)w);
else
u = QString::fromUtf16((ushort *)w);
BREAK_HERE;
// Check u "aöa" QString.
// CheckType w wchar_t *.
// Continue.
// All: Select UTF-8 in "Change Format for Type" in L&W context menu.
// Windows: Select UTF-16 in "Change Format for Type" in L&W context menu.
// Other: Select UCS-6 in "Change Format for Type" in L&W context menu.
dummyStatement(&u, &w);
}
void testCharPointers()
{
// These tests should result in properly displayed umlauts in the
// Locals&Watchers view. It is only support on gdb with Python.
const char *s = "aöa";
const char *t = "a\xc3\xb6";
const wchar_t *w = L"aöa";
BREAK_HERE;
// CheckType s char *.
// CheckType t char *.
// CheckType w wchar_t *.
// Continue.
// All: Select UTF-8 in "Change Format for Type" in L&W context menu.
// Windows: Select UTF-16 in "Change Format for Type" in L&W context menu.
// Other: Select UCS-6 in "Change Format for Type" in L&W context menu.
const unsigned char uu[] = { 'a', 153 /* ö Latin1 */, 'a' };
const unsigned char *u = uu;
BREAK_HERE;
// CheckType u unsigned char *.
// CheckType uu unsigned char [3].
// Continue.
// Make sure to undo "Change Format".
dummyStatement(&s, &w, &t, &u);
}
void testCharArrays()
{
// These tests should result in properly displayed umlauts in the
// Locals&Watchers view. It is only support on gdb with Python.
const char s[] = "aöa";
const char t[] = "aöax";
const wchar_t w[] = L"aöa";
BREAK_HERE;
// CheckType s char [5].
// CheckType t char [6].
// CheckType w wchar_t [4].
// Continue.
// All: Select UTF-8 in "Change Format for Type" in L&W context menu.
// Windows: Select UTF-16 in "Change Format for Type" in L&W context menu.
// Other: Select UCS-6 in "Change Format for Type" in L&W context menu.
// Make sure to undo "Change Format".
dummyStatement(&s, &w, &t);
}
void testFormats()
{
testCharPointers();
testCharArrays();
testString();
}
} // namespace formats
namespace text {
void testText()
{
#if USE_GUILIB
//char *argv[] = { "xxx", 0 };
QTextDocument doc;
doc.setPlainText("Hallo\nWorld");
QTextCursor tc;
BREAK_HERE;
// CheckType doc QTextDocument.
// Continue.
tc = doc.find("all");
BREAK_HERE;
// Check tc 4 QTextCursor.
// Continue.
int pos = tc.position();
BREAK_HERE;
// Check pos 4 int.
// Continue.
int anc = tc.anchor();
BREAK_HERE;
// Check anc 1 int.
// Continue.
dummyStatement(&pos, &anc);
#endif
}
} // namespace text
namespace qprocess {
void testQProcess()
{
return;
const int N = 14;
QProcess proc[N];
for (int i = 0; i != N; ++i) {
proc[i].start("sleep 10");
proc[i].waitForStarted();
}
BREAK_HERE;
dummyStatement(&proc);
}
} // namespace qprocess
namespace qthread {
class Thread : public QThread
{
public:
Thread() {}
void setId(int id) { m_id = id; }
void run()
{
int j = 2;
++j;
for (int i = 0; i != 1000; ++i) {
//sleep(1);
std::cerr << m_id;
}
if (m_id == 2) {
++j;
}
if (m_id == 3) {
BREAK_HERE;
// Expand this.
// Expand this.@1.
// Check j 3 int.
// CheckType this qthread::Thread.
// Check this.@1 QThread.
// Check this.@1.@1 "Thread #3" QObject.
// Continue.
dummyStatement(this);
}
std::cerr << j;
}
private:
int m_id;
};
void testQThread()
{
//return;
const int N = 14;
Thread thread[N];
for (int i = 0; i != N; ++i) {
thread[i].setId(i);
thread[i].setObjectName("Thread #" + QString::number(i));
thread[i].start();
}
BREAK_HERE;
// Expand thread.
// Expand thread.0.
// Expand thread.0.@1.
// Expand thread.13.
// Expand thread.13.@1.
// CheckType thread qthread::Thread [14].
// Check thread.0 qthread::Thread.
// Check thread.0.@1.@1 "Thread #0" qthread::Thread.
// Check thread.13 qthread::Thread.
// Check thread.13.@1.@1 "Thread #13" qthread::Thread.
// Continue.
for (int i = 0; i != N; ++i) {
thread[i].wait();
}
dummyStatement(&thread);
}
}
Q_DECLARE_METATYPE(QHostAddress)
Q_DECLARE_METATYPE(QList<int>)
Q_DECLARE_METATYPE(QStringList)
typedef QMap<uint, QStringList> QMapUIntQStringList;
Q_DECLARE_METATYPE(QMapUIntQStringList)
namespace qvariant {
void testQVariant1()
{
QVariant value;
QVariant::Type t = QVariant::String;
value = QVariant(t, (void*)0);
*(QString*)value.data() = QString("Some string");
int i = 1;
BREAK_HERE;
// Check t QVariant::String (10) QVariant::Type.
// Check value "Some string" QVariant (QString).
// Continue.
// Check the variant contains a proper QString.
dummyStatement(&i);
}
void testQVariant2()
{
// Check var contains objects of the types indicated.
QVariant var; // Type 0, invalid
BREAK_HERE;
// Check var (invalid) QVariant (invalid).
// Continue.
var.setValue(true); // 1, bool
BREAK_HERE;
// Check var true QVariant (bool).
// Continue.
var.setValue(2); // 2, int
BREAK_HERE;
// Check var 2 QVariant (int).
// Continue.
var.setValue(3u); // 3, uint
BREAK_HERE;
// Check var 3 QVariant (uint).
// Continue.
var.setValue(qlonglong(4)); // 4, qlonglong
BREAK_HERE;
// Check var 4 QVariant (qlonglong).
// Continue.
var.setValue(qulonglong(5)); // 5, qulonglong
BREAK_HERE;
// Check var 5 QVariant (qulonglong).
// Continue.
var.setValue(double(6)); // 6, double
BREAK_HERE;
// Check var 6 QVariant (double).
// Continue.
var.setValue(QChar(7)); // 7, QChar
BREAK_HERE;
// Check var '?' (7) QVariant (QChar).
// Continue.
//None, # 8, QVariantMap
// None, # 9, QVariantList
var.setValue(QString("Hello 10")); // 10, QString
BREAK_HERE;
// Check var "Hello 10" QVariant (QString).
// Continue.
#if USE_GUILIB
var.setValue(QRect(100, 200, 300, 400)); // 19 QRect
BREAK_HERE;
// Check var 300x400+100+200 QVariant (QRect).
// Continue.
var.setValue(QRectF(100, 200, 300, 400)); // 19 QRectF
BREAK_HERE;
// Check var 300x400+100+200 QVariant (QRectF).
// Continue.
#endif
/*
"QStringList", # 11
"QByteArray", # 12
"QBitArray", # 13
"QDate", # 14
"QTime", # 15
"QDateTime", # 16
"QUrl", # 17
"QLocale", # 18
"QRect", # 19
"QRectF", # 20
"QSize", # 21
"QSizeF", # 22
"QLine", # 23
"QLineF", # 24
"QPoint", # 25
"QPointF", # 26
"QRegExp", # 27
*/
dummyStatement(&var);
}
void testQVariant3()
{
QVariant var;
BREAK_HERE;
// Check var (invalid) QVariant (invalid).
// Continue.
// Check the list is updated properly.
var.setValue(QStringList() << "World");
BREAK_HERE;
// Expand var.
// Check var <1 items> QVariant (QStringList).
// Check var.0 "World" QString.
// Continue.
var.setValue(QStringList() << "World" << "Hello");
BREAK_HERE;
// Expand var.
// Check var <2 items> QVariant (QStringList).
// Check var.1 "Hello" QString.
// Continue.
var.setValue(QStringList() << "Hello" << "Hello");
BREAK_HERE;
// Expand var.
// Check var <2 items> QVariant (QStringList).
// Check var.0 "Hello" QString.
// Check var.1 "Hello" QString.
// Continue.
var.setValue(QStringList() << "World" << "Hello" << "Hello");
BREAK_HERE;
// Expand var.
// Check var <3 items> QVariant (QStringList).
// Check var.0 "World" QString.
// Continue.
dummyStatement(&var);
}
void testQVariant4()
{
QVariant var;
QHostAddress ha("127.0.0.1");
var.setValue(ha);
QHostAddress ha1 = var.value<QHostAddress>();
BREAK_HERE;
// Expand ha ha1 var.
// Check ha "127.0.0.1" QHostAddress.
// Check ha.a 0 quint32.
// CheckType ha.a6 Q_IPV6ADDR.
// Check ha.ipString "127.0.0.1" QString.
// Check ha.isParsed false bool.
// Check ha.protocol QAbstractSocket::UnknownNetworkLayerProtocol (-1) QAbstractSocket::NetworkLayerProtocol.
// Check ha.scopeId "" QString.
// Check ha1 "127.0.0.1" QHostAddress.
// Check ha1.a 0 quint32.
// CheckType ha1.a6 Q_IPV6ADDR.
// Check ha1.ipString "127.0.0.1" QString.
// Check ha1.isParsed false bool.
// Check ha1.protocol QAbstractSocket::UnknownNetworkLayerProtocol (-1) QAbstractSocket::NetworkLayerProtocol.
// Check ha1.scopeId "" QString.
// CheckType var QVariant (QHostAddress).
// Check var.data "127.0.0.1" QHostAddress.
// Continue.
dummyStatement(&ha1);
}
void testQVariant5()
{
// This checks user defined types in QVariants.
typedef QMap<uint, QStringList> MyType;
MyType my;
my[1] = (QStringList() << "Hello");
my[3] = (QStringList() << "World");
QVariant var;
var.setValue(my);
// FIXME: Known to break
//QString type = var.typeName();
var.setValue(my);
const char *name = QMetaType::typeName(var.userType());
BREAK_HERE;
// Expand my my.0 my.0.value my.1 my.1.value var var.data var.data.0 var.data.0.value var.data.1 var.data.1.value.
// Check my <2 items> qvariant::MyType.
// Check my.0 QMapNode<unsigned int, QStringList>.
// Check my.0.key 1 unsigned int.
// Check my.0.value <1 items> QStringList.
// Check my.0.value.0 "Hello" QString.
// Check my.1 QMapNode<unsigned int, QStringList>.
// Check my.1.key 3 unsigned int.
// Check my.1.value <1 items> QStringList.
// Check my.1.value.0 "World" QString.
// CheckType var QVariant (QMap<unsigned int , QStringList>).
// Check var.data <2 items> QMap<unsigned int, QStringList>.
// Check var.data.0 QMapNode<unsigned int, QStringList>.
// Check var.data.0.key 1 unsigned int.
// Check var.data.0.value <1 items> QStringList.
// Check var.0.value.0 "Hello" QString.
// Check var.data.1 QMapNode<unsigned int, QStringList>.
// Check var.data.1.key 3 unsigned int.
// Check var.data.1.value <1 items> QStringList.
// Check var.data.1.value.0 "World" QString.
// Continue.
var.setValue(my);
var.setValue(my);
var.setValue(my);
dummyStatement(&var, &name);
}
void testQVariant6()
{
QList<int> list;
list << 1 << 2 << 3;
QVariant variant = qVariantFromValue(list);
BREAK_HERE;
// Expand list variant variant.data.
// Check list <3 items> QList<int>.
// Check list.0 1 int.
// Check list.1 2 int.
// Check list.2 3 int.
// CheckType variant QVariant (QList<int>).
// Check variant.data <3 items> QList<int>.
// Check variant.data.0 1 int.
// Check variant.data.1 2 int.
// Check variant.data.2 3 int.
// Continue.
list.clear();
list = variant.value<QList<int> >();
BREAK_HERE;
// Expand list.
// Check list <3 items> QList<int>.
// Check list.0 1 int.
// Check list.1 2 int.
// Check list.2 3 int.
// Continue.
dummyStatement(&list);
}
void testQVariantList()
{
QVariantList vl;
BREAK_HERE;
// Check vl <0 items> QVariantList.
// Continue.
vl.append(QVariant(1));
vl.append(QVariant(2));
vl.append(QVariant("Some String"));
vl.append(QVariant(21));
vl.append(QVariant(22));
vl.append(QVariant("2Some String"));
BREAK_HERE;
// Expand vl.
// Check vl <6 items> QVariantList.
// CheckType vl.0 QVariant (int).
// CheckType vl.2 QVariant (QString).
// Continue.
dummyStatement(&vl);
}
void testQVariantMap()
{
QVariantMap vm;
BREAK_HERE;
// Check vm <0 items> QVariantMap.
// Continue.
vm["abd"] = QVariant(1);
BREAK_HERE;
// Expand vm vm.0 vm.5.
// Check vm <6 items> QVariantMap.
// Check vm.0 QMapNode<QString, QVariant>.
// Check vm.0.key "a" QString.
// Check vm.0.value 1 QVariant (int).
// Check vm.5 QMapNode<QString, QVariant>.
// Check vm.5.key "f" QString.
// Check vm.5.value "2Some String" QVariant (QString).
// Continue.
dummyStatement(&vm);
}
void testQVariant()
{
testQVariant1();
testQVariant2();
testQVariant3();
testQVariant4();
testQVariant5();
testQVariant6();
testQVariantList();
testQVariantMap();
}
} // namespace qvariant
namespace qvector {
void testQVectorIntBig()
{
// This tests the display of a big vector.
QVector<int> vec(10000);
for (int i = 0; i != vec.size(); ++i)
vec[i] = i * i;
BREAK_HERE;
// Expand vec.
// Check vec <10000 items> QVector<int>.
// Check vec.0 0 int.
// Check vec.1999 3996001 int.
// Continue.
// step over
// check that the display updates in reasonable time
vec[1] = 1;
vec[2] = 2;
vec.append(1);
vec.append(1);
BREAK_HERE;
// Expand vec.
// Check vec <10002 items> QVector<int>.
// Check vec.1 1 int.
// Check vec.2 2 int.
// Continue.
dummyStatement(&vec);
}
void testQVectorFoo()
{
// This tests the display of a vector of pointers to custom structs.
QVector<Foo> vec;
BREAK_HERE;
// Check vec <0 items> QVector<Foo>.
// Continue.
// step over, check display.
vec.append(1);
vec.append(2);
BREAK_HERE;
// Expand vec vec.0 vec.1.
// Check vec <2 items> QVector<Foo>.
// CheckType vec.0 Foo.
// Check vec.0.a 1 int.
// CheckType vec.1 Foo.
// Check vec.1.a 2 int.
// Continue.
dummyStatement(&vec);
}
typedef QVector<Foo> FooVector;
void testQVectorFooTypedef()
{
FooVector vec;
vec.append(Foo(2));
vec.append(Foo(3));
dummyStatement(&vec);
}
void testQVectorFooStar()
{
// This tests the display of a vector of pointers to custom structs.
QVector<Foo *> vec;
BREAK_HERE;
// Check vec <0 items> QVector<Foo*>.
// Continue.
// step over
// check that the display is ok.
vec.append(new Foo(1));
vec.append(0);
vec.append(new Foo(2));
vec.append(new Fooooo(3));
// switch "Auto derefencing pointers" in Locals context menu
// off and on again, and check result looks sane.
BREAK_HERE;
// Expand vec vec.0 vec.2.
// Check vec <4 items> QVector<Foo*>.
// CheckType vec.0 Foo.
// Check vec.0.a 1 int.
// Check vec.1 0x0 Foo *.
// CheckType vec.2 Foo.
// Check vec.2.a 2 int.
// CheckType vec.3 Fooooo.
// Check vec.3.a 5 int.
// Continue.
dummyStatement(&vec);
}
void testQVectorBool()
{
// This tests the display of a vector of custom structs.
QVector<bool> vec;
BREAK_HERE;
// Check vec <0 items> QVector<bool>.
// Continue.
// step over
// check that the display is ok.
vec.append(true);
vec.append(false);
BREAK_HERE;
// Expand vec.
// Check vec <2 items> QVector<bool>.
// Check vec.0 true bool.
// Check vec.1 false bool.
// Continue.
dummyStatement(&vec);
}
void testQVectorListInt()
{
QVector<QList<int> > vec;
QVector<QList<int> > *pv = &vec;
BREAK_HERE;
// CheckType pv QVector<QList<int>>.
// Check vec <0 items> QVector<QList<int>>.
// Continue.
vec.append(QList<int>() << 1);
vec.append(QList<int>() << 2 << 3);
BREAK_HERE;
// Expand pv pv.0 pv.1 vec vec.0 vec.1.
// CheckType pv QVector<QList<int>>.
// Check pv.0 <1 items> QList<int>.
// Check pv.0.0 1 int.
// Check pv.1 <2 items> QList<int>.
// Check pv.1.0 2 int.
// Check pv.1.1 3 int.
// Check vec <2 items> QVector<QList<int>>.
// Check vec.0 <1 items> QList<int>.
// Check vec.0.0 1 int.
// Check vec.1 <2 items> QList<int>.
// Check vec.1.0 2 int.
// Check vec.1.1 3 int.
// Continue.
dummyStatement(pv, &vec);
}
void testQVector()
{
testQVectorIntBig();
testQVectorFoo();
testQVectorFooTypedef();
testQVectorFooStar();
testQVectorBool();
testQVectorListInt();
}
} // namespace qvector
namespace noargs {
class Goo
{
public:
Goo(const QString &str, const int n) : str_(str), n_(n) {}
private:
QString str_;
int n_;
};
typedef QList<Goo> GooList;
void testNoArgumentName(int i, int, int k)
{
// This is not supposed to work with the compiled dumpers.
GooList list;
list.append(Goo("Hello", 1));
list.append(Goo("World", 2));
QList<Goo> list2;
list2.append(Goo("Hello", 1));
list2.append(Goo("World", 2));
BREAK_HERE;
// Expand list list.0 list.1 list2 list2.1.
// Check i 1 int.
// Check k 3 int.
// Check list <2 items> noargs::GooList.
// CheckType list.0 noargs::Goo.
// Check list.0.n_ 1 int.
// Check list.0.str_ "Hello" QString.
// CheckType list.1 noargs::Goo.
// Check list.1.n_ 2 int.
// Check list.1.str_ "World" QString.
// Check list2 <2 items> QList<noargs::Goo>.
// CheckType list2.0 noargs::Goo.
// Check list2.0.n_ 1 int.
// Check list2.0.str_ "Hello" QString.
// CheckType list2.1 noargs::Goo.
// Check list2.1.n_ 2 int.
// Check list2.1.str_ "World" QString.
// Continue.
dummyStatement(&i, &k);
}
} // namespace noargs
void foo() {}
void foo(int) {}
void foo(QList<int>) {}
void foo(QList<QVector<int> >) {}
void foo(QList<QVector<int> *>) {}
void foo(QList<QVector<int *> *>) {}
template <class T>
void foo(QList<QVector<T> *>) {}
namespace namespc {
class MyBase : public QObject
{
public:
MyBase() {}
virtual void doit(int i)
{
n = i;
}
protected:
int n;
};
namespace nested {
class MyFoo : public MyBase
{
public:
MyFoo() {}
virtual void doit(int i)
{
// Note there's a local 'n' and one in the base class.
n = i;
}
protected:
int n;
};
class MyBar : public MyFoo
{
public:
virtual void doit(int i)
{
n = i + 1;
}
};
namespace {
class MyAnon : public MyBar
{
public:
virtual void doit(int i)
{
n = i + 3;
}
};
namespace baz {
class MyBaz : public MyAnon
{
public:
virtual void doit(int i)
{
n = i + 5;
}
};
} // namespace baz
} // namespace anon
} // namespace nested
void testNamespace()
{
// This checks whether classes with "special" names are
// properly displayed.
using namespace nested;
MyFoo foo;
MyBar bar;
MyAnon anon;
baz::MyBaz baz;
BREAK_HERE;
// CheckType anon namespc::nested::(anonymous namespace)::MyAnon.
// CheckType bar namespc::nested::MyBar.
// CheckType baz namespc::nested::(anonymous namespace)::baz::MyBaz.
// CheckType foo namespc::nested::MyFoo.
// Continue.
// step into the doit() functions
baz.doit(1);
anon.doit(1);
foo.doit(1);
bar.doit(1);
dummyStatement();
}
} // namespace namespc
namespace gccextensions {
void testGccExtensions()
{
#ifdef __GNUC__
char v[8] = { 1, 2 };
char w __attribute__ ((vector_size (8))) = { 1, 2 };
int y[2] = { 1, 2 };
int z __attribute__ ((vector_size (8))) = { 1, 2 };
BREAK_HERE;
// Expand v.
// Check v.0 1 char.
// Check v.1 2 char.
// Check w.0 1 char.
// Check w.1 2 char.
// Check y.0 1 int.
// Check y.1 2 int.
// Check z.0 1 int.
// Check z.1 2 int.
// Continue.
dummyStatement(&v, &w, &y, &z);
#endif
}
} // namespace gccextension
class Z : public QObject
{
public:
Z() {
f = new Foo();
i = 0;
i = 1;
i = 2;
i = 3;
}
int i;
Foo *f;
};
void testMemoryView()
{
int a[20];
for (int i = 0; i != 20; ++i)
a[i] = i;
dummyStatement(&a);
}
QString fooxx()
{
return "bababa";
}
namespace basic {
struct Empty {};
struct Data { Data() : a(42) {} int a; };
struct VEmpty {};
struct VData { VData() : v(42) {} int v; };
struct S1 : Empty, Data, virtual VEmpty, virtual VData
{
S1() : i1(1) {}
int i1;
};
struct S2 : Empty, Data, virtual VEmpty, virtual VData
{
S2() : i2(1) {}
int i2;
};
struct Combined : S1, S2
{
Combined() : c(1) {} int c;
};
void testInheritance()
{
Combined combined;
combined.S1::a = 42;
combined.S2::a = 43;
combined.S1::v = 44;
combined.S2::v = 45;
BREAK_HERE;
// Continue.
dummyStatement(&combined);
}
// This tests display of basic types.
void testInt()
{
quint64 u64 = ULLONG_MAX;
qint64 s64 = LLONG_MAX;
quint32 u32 = UINT_MAX;
qint32 s32 = INT_MAX;
quint64 u64s = 0;
qint64 s64s = LLONG_MIN;
quint32 u32s = 0;
qint32 s32s = INT_MIN;
BREAK_HERE;
// Check u64 18446744073709551615 quint64.
// Check s64 9223372036854775807 qint64.
// Check u32 4294967295 quint32.
// Check s32 2147483647 qint32.
// Check u64s 0 quint64.
// Check s64s -9223372036854775808 qint64.
// Check u32s 0 quint32.
// Check s32s -2147483648 qint32.
// Continue.
dummyStatement(&u64, &s64, &u32, &s32, &u64s, &s64s, &u32s, &s32s);
}
void testStdInt()
{
uint8_t u8 = 64;
int8_t s8 = 65;
BREAK_HERE;
// Check u8 64 uint8_t
// Check u8 65 int8_t
dummyStatement(&u8, &s8);
}
void testArray1()
{
double d[3][3];
for (int i = 0; i != 3; ++i)
for (int j = 0; j != 3; ++j)
d[i][j] = i + j;
BREAK_HERE;
// Expand d d.0.
// CheckType d double [3][3].
// CheckType d.0 double [3].
// Check d.0.0 0 double.
// Check d.0.2 2 double.
// CheckType d.2 double [3].
// Continue.
dummyStatement(&d);
}
void testArray2()
{
char c[20];
c[0] = 'a';
c[1] = 'b';
c[2] = 'c';
c[3] = 'd';
BREAK_HERE;
// Expand c.
// CheckType c char [20].
// Check c.0 97 'a' char.
// Check c.3 100 'd' char.
// Continue.
dummyStatement(&c);
}
void testArray3()
{
QString s[20];
s[0] = "a";
s[1] = "b";
s[2] = "c";
s[3] = "d";
BREAK_HERE;
// Expand s.
// CheckType s QString [20].
// Check s.0 "a" QString.
// Check s.3 "d" QString.
// Check s.4 "" QString.
// Check s.19 "" QString.
// Continue.
dummyStatement(&s);
}
void testArray4()
{
QByteArray b[20];
b[0] = "a";
b[1] = "b";
b[2] = "c";
b[3] = "d";
BREAK_HERE;
// Expand b.
// CheckType b QByteArray [20].
// Check b.0 "a" QByteArray.
// Check b.3 "d" QByteArray.
// Check b.4 "" QByteArray.
// Check b.19 "" QByteArray.
// Continue.
dummyStatement(&b);
}
void testArray5()
{
Foo foo[10];
//for (int i = 0; i != sizeof(foo)/sizeof(foo[0]); ++i) {
for (int i = 0; i < 5; ++i) {
foo[i].a = i;
foo[i].doit();
}
BREAK_HERE;
// Expand foo.
// CheckType foo Foo [10].
// CheckType foo.0 Foo.
// CheckType foo.9 Foo.
// Continue.
dummyStatement(&foo);
}
// https://bugreports.qt.io/browse/QTCREATORBUG-5326
void testChar()
{
char s[6];
s[0] = 0;
BREAK_HERE;
// Expand s.
// CheckType s char [6].
// Check s.0 0 '\0' char.
// Continue.
// Manual: Open pinnable tooltip.
// Manual: Step over.
// Manual: Check that display and tooltip look sane.
strcat(s, "\"");
strcat(s, "\"");
strcat(s, "a");
strcat(s, "b");
strcat(s, "\"");
// Manual: Close tooltip.
dummyStatement(&s);
}
static char buf[20] = { 0 };
void testCharStar()
{
char *s = buf;
BREAK_HERE;
// Expand s.
// CheckType s char *.
// Continue.
// Manual: Open pinnable tooltip.
// Manual: Step over.
// Manual: Check that display and tooltip look sane.
s = strcat(s,"\"");
s = strcat(s,"\"");
s = strcat(s,"a");
s = strcat(s,"b");
s = strcat(s,"\"");
// Close tooltip.
dummyStatement(&s);
}
struct S
{
uint x : 1;
uint y : 1;
bool c : 1;
bool b;
float f;
double d;
qreal q;
int i;
};
void testBitfields()
{
// This checks whether bitfields are properly displayed
S s;
BREAK_HERE;
// Expand s.
// CheckType s basic::S.
// CheckType s.b bool.
// CheckType s.c bool.
// CheckType s.d double.
// CheckType s.f float.
// CheckType s.i int.
// CheckType s.q qreal.
// CheckType s.x uint.
// CheckType s.y uint.
// Continue.
s.i = 0;
dummyStatement(&s);
}
struct Function
{
Function(QByteArray var, QByteArray f, double min, double max)
: var(var), f(f), min(min), max(max) {}
QByteArray var;
QByteArray f;
double min;
double max;
};
void testFunction()
{
// In order to use this, switch on the 'qDump__Function' in dumper.py
Function func("x", "sin(x)", 0, 1);
BREAK_HERE;
// Expand func.
// CheckType func basic::Function.
// Check func.f "sin(x)" QByteArray.
// Check func.max 1 double.
// Check func.min 0 double.
// Check func.var "x" QByteArray.
// Continue.
func.max = 10;
func.f = "cos(x)";
func.max = 4;
func.max = 5;
func.max = 6;
func.max = 7;
BREAK_HERE;
// Expand func.
// CheckType func basic::Function.
// Check func.f "cos(x)" QByteArray.
// Check func.max 7 double.
// Continue.
dummyStatement(&func);
}
struct Color
{
int r,g,b,a;
Color() { r = 1, g = 2, b = 3, a = 4; }
};
void testAlphabeticSorting()
{
// This checks whether alphabetic sorting of structure
// members work.
Color c;
BREAK_HERE;
// Expand c.
// CheckType c basic::Color.
// Check c.a 4 int.
// Check c.b 3 int.
// Check c.g 2 int.
// Check c.r 1 int.
// Continue.
// Manual: Toogle "Sort Member Alphabetically" in context menu
// Manual: of "Locals and Expressions" view.
// Manual: Check that order of displayed members changes.
dummyStatement(&c);
}
namespace ns {
typedef unsigned long long vl;
typedef vl verylong;
}
void testTypedef()
{
typedef quint32 myType1;
typedef unsigned int myType2;
myType1 t1 = 0;
myType2 t2 = 0;
ns::vl j = 1000;
ns::verylong k = 1000;
BREAK_HERE;
// Check j 1000 basic::ns::vl.
// Check k 1000 basic::ns::verylong.
// Check t1 0 basic::myType1.
// Check t2 0 basic::myType2.
// Continue.
dummyStatement(&j, &k, &t1, &t2);
}
void testStruct()
{
Foo f(2);
f.doit();
f.doit();
f.doit();
BREAK_HERE;
// Expand f.
// CheckType f Foo.
// Check f.a 5 int.
// Check f.b 2 int.
// Continue.
dummyStatement(&f);
}
void testUnion()
{
union U
{
int a;
int b;
} u;
BREAK_HERE;
// Expand u.
// CheckType u basic::U.
// CheckType u.a int.
// CheckType u.b int.
// Continue.
dummyStatement(&u);
}
void testUninitialized()
{
// This tests the display of uninitialized data.
BREAK_UNINITIALIZED_HERE;
// Check hii <not accessible> QHash<int, int>.
// Check hss <not accessible> QHash<QString, QString>.
// Check li <not accessible> QList<int>.
// CheckType mii <not accessible> QMap<int, int>.
// Check mss <not accessible> QMap<QString, QString>.
// Check s <not accessible> QString.
// Check si <not accessible> QStack<int>.
// Check sl <not accessible> QStringList.
// Check sli <not accessible> std::list<int>.
// CheckType smii std::map<int, int>.
// CheckType smss std::map<std::string, std::string>.
// CheckType ss std::string.
// Check ssi <not accessible> std::stack<int>.
// Check ssl <not accessible> std::list<std::string>.
// CheckType svi std::vector<int>.
// Check vi <not accessible> QVector<int>.
// Continue.
// Manual: Note: All values should be <uninitialized> or random data.
// Manual: Check that nothing bad happens if items with random data
// Manual: are expanded.
QString s;
QStringList sl;
QMap<int, int> mii;
QMap<QString, QString> mss;
QHash<int, int> hii;
QHash<QString, QString> hss;
QList<int> li;
QVector<int> vi;
QStack<int> si;
std::string ss;
std::map<int, int> smii;
std::map<std::string, std::string> smss;
std::list<int> sli;
std::list<std::string> ssl;
std::vector<int> svi;
std::stack<int> ssi;
dummyStatement(&s, &sl, &mii, &mss, &hii, &hss, &si, &vi, &li,
&ss, &smii, &smss, &sli, &svi, &ssi, &ssl);
}
void testTypeFormats()
{
// These tests should result in properly displayed umlauts in the
// Locals and Expressions view. It is only support on gdb with Python.
const char *s = "aöa";
const char cs[] = "aöa";
char cc[] = "aöa";
const wchar_t *w = L"aöa";
const wchar_t cw[] = L"aöa";
wchar_t ww[] = L"aöa";
QString u;
BREAK_HERE;
// Expand s.
// CheckType s char *.
// Skip Check s.*s 97 'a' char.
// Check u "" QString.
// CheckType w wchar_t *.
// Continue.
// All: Select UTF-8 in "Change Format for Type" in L&W context menu.
// Windows: Select UTF-16 in "Change Format for Type" in L&W context menu.
// Other: Select UCS-6 in "Change Format for Type" in L&W context menu.
if (sizeof(wchar_t) == 4)
u = QString::fromUcs4((uint *)w);
else
u = QString::fromUtf16((ushort *)w);
// Make sure to undo "Change Format".
dummyStatement(s, w, &ww, &cw, &cc, &cs);
}
typedef void *VoidPtr;
typedef const void *CVoidPtr;
struct A
{
A() : test(7) {}
int test;
void doSomething(CVoidPtr cp) const;
};
void A::doSomething(CVoidPtr cp) const
{
BREAK_HERE;
// CheckType cp basic::CVoidPtr.
// Continue.
dummyStatement(&cp);
}
void testPointer()
{
Foo *f = new Foo();
BREAK_HERE;
// Expand f.
// CheckType f Foo.
// Check f.a 0 int.
// Check f.b 5 int.
// Continue.
dummyStatement(f);
}
void testPointerTypedef()
{
A a;
VoidPtr p = &a;
CVoidPtr cp = &a;
BREAK_HERE;
// CheckType a basic::A.
// CheckType cp basic::CVoidPtr.
// CheckType p basic::VoidPtr.
// Continue.
a.doSomething(cp);
dummyStatement(&a, &p);
}
void testStringWithNewline()
{
QString hallo = "hallo\nwelt";
BREAK_HERE;
// Check hallo "hallo\nwelt" QString.
// Continue.
// Check that string is properly displayed.
dummyStatement(&hallo);
}
void testMemoryView()
{
int a[20];
BREAK_HERE;
// CheckType a int [20].
// Continue.
// Select "Open Memory View" from Locals and Expressions
// context menu for item 'a'.
// Step several times.
// Check the contents of the memory view updates.
for (int i = 0; i != 20; ++i)
a[i] = i;
dummyStatement(&a);
}
void testColoredMemoryView()
{
int i = 42;
double d = 23;
QString s = "Foo";
BREAK_HERE;
// Check d 23 double.
// Check i 42 int.
// Check s "Foo" QString.
// Continue.
// Select "Open Memory Editor->Open Memory Editor Showing Stack Layout"
// from Locals and Expressions context menu.
// Check that the opened memory view contains coloured items
// for 'i', 'd', and 's'.
dummyStatement(&i, &d, &s);
}
void testReference1()
{
int a = 43;
const int &b = a;
typedef int &Ref;
const int c = 44;
const Ref d = a;
BREAK_HERE;
// Check a 43 int.
// Check b 43 int &.
// Check c 44 int.
// Check d 43 basic::Ref.
// Continue.
dummyStatement(&a, &b, &c, &d);
}
void testReference2()
{
QString a = "hello";
const QString &b = fooxx();
typedef QString &Ref;
const QString c = "world";
const Ref d = a;
BREAK_HERE;
// Check a "hello" QString.
// Check b "bababa" QString &.
// Check c "world" QString.
// Check d "hello" basic::Ref.
// Continue.
dummyStatement(&a, &b, &c, &d);
}
void testReference3(const QString &a)
{
const QString &b = a;
typedef QString &Ref;
const Ref d = const_cast<Ref>(a);
BREAK_HERE;
// Check a "hello" QString &.
// Check b "hello" QString &.
// Check d "hello" basic::Ref.
// Continue.
dummyStatement(&a, &b, &d);
}
void testDynamicReference()
{
DerivedClass d;
BaseClass *b1 = &d;
BaseClass &b2 = d;
BREAK_HERE;
// CheckType b1 DerivedClass *.
// CheckType b2 DerivedClass &.
// Continue.
int x = b1->foo();
int y = b2.foo();
dummyStatement(&d, &b1, &b2, &x, &y);
}
void testLongEvaluation1()
{
QDateTime time = QDateTime::currentDateTime();
const int N = 10000;
QDateTime x = time;
#if QT_VERSION >= QT_VERSION_CHECK(5, 2, 0)
QTimeZone tz("UTC+05:00");
x.setTimeZone(tz);
#endif
QDateTime bigv[N];
for (int i = 0; i < 10000; ++i) {
bigv[i] = time;
time = time.addDays(1);
}
BREAK_HERE;
// Expand bigv.
// Check N 10000 int.
// CheckType bigv QDateTime [10000].
// CheckType bigv.0 QDateTime.
// CheckType bigv.9999 QDateTime.
// CheckType time QDateTime.
// Continue.
// Note: This is expected to _not_ take up to a minute.
dummyStatement(&bigv);
}
void testLongEvaluation2()
{
const int N = 10000;
int bigv[N];
for (int i = 0; i < 10000; ++i)
bigv[i] = i;
BREAK_HERE;
// Expand bigv.
// Check N 10000 int.
// CheckType bigv int [10000].
// Check bigv.0 0 int.
// Check bigv.9999 9999 int.
// Continue.
// Note: This is expected to take up to a minute.
dummyStatement(&bigv);
}
void testFork()
{
QProcess proc;
proc.start("/bin/ls");
proc.waitForFinished();
QByteArray ba = proc.readAllStandardError();
ba.append('x');
BREAK_HERE;
// Check ba "x" QByteArray.
// Check proc QProcess.
// Continue.
// Check there is some contents in ba. Error message is expected.
dummyStatement(&ba);
}
int testFunctionPointerHelper(int x) { return x; }
void testFunctionPointer()
{
typedef int (*func_t)(int);
func_t f = testFunctionPointerHelper;
int a = f(43);
BREAK_HERE;
// CheckType f basic::func_t.
// Continue.
// Check there's a valid display for f.
dummyStatement(&f, &a);
}
struct Class
{
Class() : a(34) {}
int testFunctionPointerHelper(int x) { return x; }
int a;
};
void testMemberFunctionPointer()
{
Class x;
typedef int (Class::*func_t)(int);
func_t f = &Class::testFunctionPointerHelper;
int a = (x.*f)(43);
BREAK_HERE;
// CheckType f basic::func_t.
// Continue.
// Check there's a valid display for f.
dummyStatement(&f, &a);
}
void testMemberPointer()
{
Class x;
typedef int (Class::*member_t);
member_t m = &Class::a;
int a = x.*m;
BREAK_HERE;
// CheckType m basic::member_t.
// Continue.
// Check there's a valid display for m.
dummyStatement(&m, &a);
}
void testPassByReferenceHelper(Foo &f)
{
BREAK_HERE;
// Expand f.
// CheckType f Foo &.
// Check f.a 12 int.
// Continue.
++f.a;
BREAK_HERE;
// Expand f.
// CheckType f Foo &.
// Check f.a 13 int.
// Continue.
}
void testPassByReference()
{
Foo f(12);
testPassByReferenceHelper(f);
dummyStatement(&f);
}
void testBigInt()
{
qint64 a = Q_INT64_C(0xF020304050607080);
quint64 b = Q_UINT64_C(0xF020304050607080);
quint64 c = std::numeric_limits<quint64>::max() - quint64(1);
BREAK_HERE;
// Check a -1143861252567568256 qint64.
// Check b -1143861252567568256 quint64.
// Check c -2 quint64.
// Continue.
dummyStatement(&a, &b, &c);
}
void testHidden()
{
int n = 1;
n = 2;
BREAK_HERE;
// Check n 2 int.
// Continue.
n = 3;
BREAK_HERE;
// Check n 3 int.
// Continue.
{
QString n = "2";
BREAK_HERE;
// Check n "2" QString.
// Check n@1 3 int.
// Continue.
n = "3";
BREAK_HERE;
// Check n "3" QString.
// Check n@1 3 int.
// Continue.
{
double n = 3.5;
BREAK_HERE;
// Check n 3.5 double.
// Check n@1 "3" QString.
// Check n@2 3 int.
// Continue.
++n;
BREAK_HERE;
// Check n 4.5 double.
// Check n@1 "3" QString.
// Check n@2 3 int.
// Continue.
dummyStatement(&n);
}
BREAK_HERE;
// Check n "3" QString.
// Check n@1 3 int.
// Continue.
n = "3";
n = "4";
BREAK_HERE;
// Check n "4" QString.
// Check n@1 3 int.
// Continue.
dummyStatement(&n);
}
++n;
dummyStatement(&n);
}
int testReturnInt()
{
return 1;
}
bool testReturnBool()
{
return true;
}
QString testReturnQString()
{
return "string";
}
void testReturn()
{
bool b = testReturnBool();
BREAK_HERE;
// Check b true bool.
// Continue.
int i = testReturnInt();
BREAK_HERE;
// Check i 1 int.
// Continue.
QString s = testReturnQString();
BREAK_HERE;
// Check s "string" QString.
// Continue.
dummyStatement(&i, &b, &s);
}
#ifdef Q_COMPILER_RVALUE_REFS
struct X { X() : a(2), b(3) {} int a, b; };
X testRValueReferenceHelper1()
{
return X();
}
X testRValueReferenceHelper2(X &&x)
{
return x;
}
void testRValueReference()
{
X &&x1 = testRValueReferenceHelper1();
X &&x2 = testRValueReferenceHelper2(std::move(x1));
X &&x3 = testRValueReferenceHelper2(testRValueReferenceHelper1());
X y1 = testRValueReferenceHelper1();
X y2 = testRValueReferenceHelper2(std::move(y1));
X y3 = testRValueReferenceHelper2(testRValueReferenceHelper1());
BREAK_HERE;
// Continue.
dummyStatement(&x1, &x2, &x3, &y1, &y2, &y3);
}
#else
void testRValueReference() {}
#endif
void testBasic()
{
testInheritance();
testInt();
testStdInt();
testReference1();
testReference2();
testReference3("hello");
testRValueReference();
testDynamicReference();
testReturn();
testArray1();
testArray2();
testArray3();
testArray4();
testArray5();
testChar();
testCharStar();
testBitfields();
testFunction();
testAlphabeticSorting();
testTypedef();
testPointer();
testPointerTypedef();
testStruct();
testUnion();
testUninitialized();
testTypeFormats();
testStringWithNewline();
testMemoryView();
testColoredMemoryView();
testLongEvaluation1();
testLongEvaluation2();
// testFork();
testFunctionPointer();
testMemberPointer();
testMemberFunctionPointer();
testPassByReference();
testBigInt();
testHidden();
}
} // namespace basic
namespace io {
void testWCout()
{
using namespace std;
wstring x = L"xxxxx";
wstring::iterator i = x.begin();
// Break here.
// Step.
while (i != x.end()) {
wcout << *i;
i++;
}
wcout.flush();
string y = "yyyyy";
string::iterator j = y.begin();
while (j != y.end()) {
cout << *j;
j++;
}
cout.flush();
}
void testWCout0()
{
// Mixing cout and wcout does not work with gcc.
// See http://gcc.gnu.org/ml/gcc-bugs/2006-05/msg01193.html
// which also says "you can obtain something close to your
// expectations by calling std::ios::sync_with_stdio(false);
// at the beginning of your program."
using namespace std;
//std::ios::sync_with_stdio(false);
// Break here.
// Step.
wcout << L"WWWWWW" << endl;
wcerr << L"YYYYYY" << endl;
cout << "CCCCCC" << endl;
cerr << "EEEEEE" << endl;
wcout << L"WWWWWW" << endl;
wcerr << L"YYYYYY" << endl;
cout << "CCCCCC" << endl;
cerr << "EEEEEE" << endl;
wcout << L"WWWWWW" << endl;
wcerr << L"YYYYYY" << endl;
cout << "CCCCCC" << endl;
cerr << "EEEEEE" << endl;
}
void testOutput()
{
qDebug() << "qDebug() 1";
qDebug() << "qDebug() 2";
qDebug() << "qDebug() 3";
qDebug() << "qDebug <foo & bar>";
std::cout << "std::cout @@ 1" << std::endl;
std::cout << "std::cout @@ 2\n";
std::cout << "std::cout @@ 3" << std::endl;
std::cout << "std::cout <foo & bar>\n";
std::cerr << "std::cerr 1\n";
std::cerr << "std::cerr 2\n";
std::cerr << "std::cerr 3\n";
std::cerr << "std::cerr <foo & bar>\n";
}
void testInput()
{
// This works only when "Run in terminal" is selected
// in the Run Configuration.
int i;
std::cin >> i;
int j;
std::cin >> j;
std::cout << "Values are " << i << " and " << j << "." << std::endl;
}
void testIO()
{
testOutput();
//testInput();
//testWCout();
//testWCout0();
}
} // namespace io
namespace sse {
void testSSE()
{
#if USE_SSE
float a[4];
float b[4];
int i;
for (i = 0; i < 4; i++) {
a[i] = 2 * i;
b[i] = 2 * i;
}
__m128 sseA, sseB;
sseA = _mm_loadu_ps(a);
sseB = _mm_loadu_ps(b);
__m128i sseAi;
sseAi = _mm_set_epi32(1, 3, 5, 7);
BREAK_HERE;
// Expand a b.
// CheckType sseA __m128.
// CheckType sseB __m128.
// Continue.
dummyStatement(&i, &sseA, &sseB);
#endif
}
} // namespace sse
namespace qscript {
void testQScript()
{
#if USE_SCRIPTLIB
BREAK_UNINITIALIZED_HERE;
QScriptEngine engine;
QDateTime date = QDateTime::currentDateTime();
QScriptValue s;
BREAK_HERE;
// Check engine QScriptEngine.
// Check s (invalid) QScriptValue.
// Check x1 <not accessible> QString.
// Continue.
s = QScriptValue(33);
int x = s.toInt32();
s = QScriptValue(QString("34"));
QString x1 = s.toString();
s = engine.newVariant(QVariant(43));
QVariant v = s.toVariant();
s = engine.newVariant(QVariant(43.0));
s = engine.newVariant(QVariant(QString("sss")));
s = engine.newDate(date);
date = s.toDateTime();
s.setProperty("a", QScriptValue());
QScriptValue d = s.data();
BREAK_HERE;
// Check d (invalid) QScriptValue.
// Check v 43 QVariant (int).
// Check x 33 int.
// Check x1 "34" QString.
// Continue.
dummyStatement(&x1, &v, &s, &d, &x);
#else
dummyStatement();
#endif
}
} // namespace script
namespace webkit {
void testWTFString()
{
#if USE_WEBKITLIB
BREAK_UNINITIALIZED_HERE;
QWebPage p;
BREAK_HERE;
// CheckType p QWebPage.
// Continue.
dummyStatement(&p);
#else
dummyStatement();
#endif
}
void testWebKit()
{
testWTFString();
}
} // namespace webkit
namespace boost {
#if USE_BOOST
void testBoostOptional1()
{
boost::optional<int> i;
BREAK_HERE;
// Check i <uninitialized> boost::optional<int>.
// Continue.
i = 1;
BREAK_HERE;
// Check i 1 boost::optional<int>.
// Continue.
dummyStatement(&i);
}
void testBoostOptional2()
{
boost::optional<QStringList> sl;
BREAK_HERE;
// Check sl <uninitialized> boost::optional<QStringList>.
// Continue.
sl = (QStringList() << "xxx" << "yyy");
sl.get().append("zzz");
BREAK_HERE;
// Check sl <3 items> boost::optional<QStringList>.
// Continue.
dummyStatement(&sl);
}
void testBoostSharedPtr()
{
boost::shared_ptr<int> s;
boost::shared_ptr<int> i(new int(43));
boost::shared_ptr<int> j = i;
boost::shared_ptr<QStringList> sl(new QStringList(QStringList() << "HUH!"));
BREAK_HERE;
// Expand sl.
// Check s (null) boost::shared_ptr<int>.
// Check i 43 boost::shared_ptr<int>.
// Check j 43 boost::shared_ptr<int>.
// Check sl boost::shared_ptr<QStringList>.
// Check sl.data <1 items> QStringList
// Continue.
dummyStatement(&s, &j, &sl);
}
void testBoostGregorianDate()
{
using namespace boost;
using namespace gregorian;
date d(2005, Nov, 29);
BREAK_HERE;
// Check d Tue Nov 29 2005 boost::gregorian::date.
// Continue
d += months(1);
BREAK_HERE;
// Check d Thu Dec 29 2005 boost::gregorian::date.
// Continue
d += months(1);
BREAK_HERE;
// Check d Sun Jan 29 2006 boost::gregorian::date.
// Continue
// snap-to-end-of-month behavior kicks in:
d += months(1);
BREAK_HERE;
// Check d Tue Feb 28 2006 boost::gregorian::date.
// Continue.
// Also end of the month (expected in boost)
d += months(1);
BREAK_HERE;
// Check d Fri Mar 31 2006 boost::gregorian::date.
// Continue.
// Not where we started (expected in boost)
d -= months(4);
BREAK_HERE;
// Check d Wed Nov 30 2005 boost::gregorian::date.
// Continue.
dummyStatement(&d);
}
void testBoostPosixTimeTimeDuration()
{
using namespace boost;
using namespace posix_time;
time_duration d1(1, 0, 0);
BREAK_HERE;
// Check d1 01:00:00 boost::posix_time::time_duration.
// Continue.
time_duration d2(0, 1, 0);
BREAK_HERE;
// Check d2 00:01:00 boost::posix_time::time_duration.
// Continue.
time_duration d3(0, 0, 1);
BREAK_HERE;
// Check d3 00:00:01 boost::posix_time::time_duration.
// Continue.
dummyStatement(&d1, &d2, &d3);
}
void testBoostBimap()
{
typedef boost::bimap<int, int> B;
B b;
BREAK_HERE;
// Check b <0 items> boost::B.
// Continue.
b.left.insert(B::left_value_type(1, 2));
BREAK_HERE;
// Check b <1 items> boost::B.
// Continue.
B::left_const_iterator it = b.left.begin();
int l = it->first;
int r = it->second;
// Continue.
dummyStatement(&b, &l, &r);
}
void testBoostPosixTimePtime()
{
using namespace boost;
using namespace gregorian;
using namespace posix_time;
ptime p1(date(2002, 1, 10), time_duration(1, 0, 0));
BREAK_HERE;
// Check p1 Thu Jan 10 01:00:00 2002 boost::posix_time::ptime.
// Continue.
ptime p2(date(2002, 1, 10), time_duration(0, 0, 0));
BREAK_HERE;
// Check p2 Thu Jan 10 00:00:00 2002 boost::posix_time::ptime.
// Continue.
ptime p3(date(1970, 1, 1), time_duration(0, 0, 0));
BREAK_HERE;
// Check p3 Thu Jan 1 00:00:00 1970 boost::posix_time::ptime.
// Continue.
dummyStatement(&p1, &p2, &p3);
}
void testBoost()
{
testBoostOptional1();
testBoostOptional2();
testBoostSharedPtr();
testBoostPosixTimeTimeDuration();
testBoostPosixTimePtime();
testBoostGregorianDate();
testBoostBimap();
}
#else
void testBoost() {}
#endif
} // namespace boost
namespace mpi {
struct structdata
{
int ints[8];
char chars[32];
double doubles[5];
};
enum type_t { MPI_LB, MPI_INT, MPI_CHAR, MPI_DOUBLE, MPI_UB };
struct tree_entry
{
tree_entry() {}
tree_entry(int l, int o, type_t t)
: blocklength(l), offset(o), type(t)
{}
int blocklength;
int offset;
type_t type;
};
struct tree
{
enum kind_t { STRUCT };
void *base;
kind_t kind;
int count;
tree_entry entries[20];
};
void testMPI()
{
structdata buffer = {
//{MPI_LB},
{0, 1024, 2048, 3072, 4096, 5120, 6144 },
{"message to 1 of 2: hello"},
{0, 3.14, 6.2831853071795862, 9.4247779607693793, 13},
//{MPI_UB}
};
tree x;
x.base = &buffer;
x.kind = tree::STRUCT;
x.count = 5;
x.entries[0] = tree_entry(1, -4, MPI_LB);
x.entries[1] = tree_entry(5, 0, MPI_INT);
x.entries[2] = tree_entry(7, 47, MPI_CHAR);
x.entries[3] = tree_entry(2, 76, MPI_DOUBLE);
x.entries[4] = tree_entry(1, 100, MPI_UB);
int i = x.count;
i = buffer.ints[0];
i = buffer.ints[1];
i = buffer.ints[2];
i = buffer.ints[3];
/*
gdb) print datatype
> $3 = {
> kind = STRUCT,
> count = 5,
> entries = {{
> blocklength = 1,
> offset = -4,
> type = MPI_LB
> }, {
> blocklength = 5,
> offset = 0,
> type = MPI_INT
> }, {
> blocklength = 7,
> offset = 47,
> type = MPI_CHAR
> }, {
> blocklength = 2,
> offset = 76,
> type = MPI_DOUBLE
> }, {
> blocklength = 1,
> offset = 100,
> type = MPI_UB
> }}
> }
*/
dummyStatement(&i);
}
} // namespace mpi
//namespace kr {
// FIXME: put in namespace kr, adjust qdump__KRBase in dumpers/qttypes.py
struct KRBase
{
enum Type { TYPE_A, TYPE_B } type;
KRBase(Type _type) : type(_type) {}
};
struct KRA : KRBase { int x; int y; KRA():KRBase(TYPE_A), x(1), y(32) {} };
struct KRB : KRBase { KRB():KRBase(TYPE_B) {} };
//} // namespace kr
namespace kr {
// Only with python.
// This tests qdump__KRBase in dumpers/qttypes.py which uses
// a static typeflag to dispatch to subclasses.
void testKR()
{
KRBase *ptr1 = new KRA;
KRBase *ptr2 = new KRB;
ptr2 = new KRB;
BREAK_HERE;
// Expand ptr1 ptr2.
// CheckType ptr1 KRBase.
// Check ptr1.type KRBase::TYPE_A (0) KRBase::Type.
// CheckType ptr2 KRBase.
// Check ptr2.type KRBase::TYPE_B (1) KRBase::Type.
// Continue.
dummyStatement(&ptr1, &ptr2);
}
} // namspace kr
namespace eigen {
void testEigen()
{
#if USE_EIGEN
using namespace Eigen;
Vector3d test = Vector3d::Zero();
Matrix3d myMatrix = Matrix3d::Constant(5);
MatrixXd myDynamicMatrix(30, 10);
myDynamicMatrix(0, 0) = 0;
myDynamicMatrix(1, 0) = 1;
myDynamicMatrix(2, 0) = 2;
Matrix<double, 12, 15, ColMajor> colMajorMatrix;
Matrix<double, 12, 15, RowMajor> rowMajorMatrix;
int k = 0;
for (int i = 0; i != 12; ++i) {
for (int j = 0; j != 15; ++j) {
colMajorMatrix(i, j) = k;
rowMajorMatrix(i, j) = k;
++k;
}
}
BREAK_HERE;
// Continue.
dummyStatement(&colMajorMatrix, &rowMajorMatrix, &test,
&myMatrix, &myDynamicMatrix);
#endif
}
}
namespace bug842 {
void test842()
{
// https://bugreports.qt.io/browse/QTCREATORBUG-842
qWarning("Test");
BREAK_HERE;
// Continue.
// Manual: Check that Application Output pane contains string "Test".
dummyStatement();
}
} // namespace bug842
namespace bug3611 {
void test3611()
{
// https://bugreports.qt.io/browse/QTCREATORBUG-3611
typedef unsigned char byte;
byte f = '2';
int *x = (int*)&f;
BREAK_HERE;
// Check f 50 '2' bug3611::byte.
// Continue.
// Step.
f += 1;
f += 1;
f += 1;
BREAK_HERE;
// Check f 53 '5' bug3611::byte.
// Continue.
dummyStatement(&f, &x);
}
} // namespace bug3611
namespace bug4019 {
// https://bugreports.qt.io/browse/QTCREATORBUG-4019
class A4019
{
public:
A4019() : test(7) {}
int test;
void doSomething() const;
};
void A4019::doSomething() const
{
std::cout << test << std::endl;
}
void test4019()
{
A4019 a;
a.doSomething();
}
} // namespave bug4019
namespace bug4997 {
// https://bugreports.qt.io/browse/QTCREATORBUG-4997
void test4997()
{
using namespace std;
// cin.get(); // if commented out, the debugger doesn't stop at the breakpoint
// in the next line on Windows when "Run in Terminal" is used.^
dummyStatement();
}
}
namespace bug4904 {
// https://bugreports.qt.io/browse/QTCREATORBUG-4904
struct CustomStruct {
int id;
double dvalue;
};
void test4904()
{
QMap<int, CustomStruct> map;
CustomStruct cs1;
cs1.id = 1;
cs1.dvalue = 3.14;
CustomStruct cs2 = cs1;
cs2.id = -1;
map.insert(cs1.id, cs1);
map.insert(cs2.id, cs2);
QMap<int, CustomStruct>::iterator it = map.begin();
BREAK_HERE;
// Expand map map.0 map.0.value.
// Check map <2 items> QMap<int, bug4904::CustomStruct>.
// Check map.0 QMapNode<int, bug4904::CustomStruct>.
// Check map.0.key -1 int.
// CheckType map.0.value bug4904::CustomStruct.
// Check map.0.value.dvalue 3.1400000000000001 double.
// Check map.0.value.id -1 int.
// Continue.
dummyStatement(&it);
}
} // namespace bug4904
namespace bug5046 {
// https://bugreports.qt.io/browse/QTCREATORBUG-5046
struct Foo { int a, b, c; };
void test5046()
{
Foo f;
f.a = 1;
f.b = 2;
f.c = 3;
f.a = 4;
BREAK_HERE;
// Expand f.
// CheckType f bug5046::Foo.
// Check f.a 4 int.
// Check f.b 2 int.
// Check f.c 3 int.
// Continue.
// Manual: pop up main editor tooltip over 'f'
// Manual: verify that the entry is expandable, and expansion works
dummyStatement(&f);
}
} // namespace bug5046
namespace bug5106 {
// https://bugreports.qt.io/browse/QTCREATORBUG-5106
class A5106
{
public:
A5106(int a, int b) : m_a(a), m_b(b) {Q_UNUSED(m_a);Q_UNUSED(m_b);}
virtual int test() { return 5; }
private:
int m_a, m_b;
};
class B5106 : public A5106
{
public:
B5106(int c, int a, int b) : A5106(a, b), m_c(c) {Q_UNUSED(m_c);}
virtual int test() { return 4; BREAK_HERE; }
private:
int m_c;
};
void test5106()
{
B5106 b(1,2,3);
b.test();
b.A5106::test();
}
} // namespace bug5106
namespace bug5184 {
// https://bugreports.qt.io/browse/QTCREATORBUG-5184
// Note: The report there shows type field "QUrl &" instead of QUrl.
// It's unclear how this can happen. It should never have been like
// that with a stock 7.2 and any version of Creator.
void helper(const QUrl &url)
{
QNetworkRequest request(url);
QList<QByteArray> raw = request.rawHeaderList();
BREAK_HERE;
// Check raw <0 items> QList<QByteArray>.
// CheckType request QNetworkRequest.
// Check url "http://127.0.0.1/" QUrl &.
// Continue.
dummyStatement(&request, &raw);
}
void test5184()
{
QUrl url(QString("http://127.0.0.1/"));
helper(url);
}
} // namespace bug5184
namespace qc42170 {
// http://www.qtcentre.org/threads/42170-How-to-watch-data-of-actual-type-in-debugger
struct Object
{
Object(int id_) : id(id_) {}
virtual ~Object() {}
int id;
};
struct Point : Object
{
Point(double x_, double y_) : Object(1), x(x_), y(y_) {}
double x, y;
};
struct Circle : Point
{
Circle(double x_, double y_, double r_) : Point(x_, y_), r(r_) { id = 2; }
double r;
};
void helper(Object *obj)
{
BREAK_HERE;
// CheckType obj qc42170::Circle.
// Continue.
// Check that obj is shown as a 'Circle' object.
dummyStatement(obj);
}
void test42170()
{
Circle *circle = new Circle(1.5, -2.5, 3.0);
Object *obj = circle;
helper(circle);
helper(obj);
}
} // namespace qc42170
namespace bug5799 {
// https://bugreports.qt.io/browse/QTCREATORBUG-5799
typedef struct { int m1; int m2; } S1;
struct S2 : S1 { };
typedef struct S3 { int m1; int m2; } S3;
struct S4 : S3 { };
void test5799()
{
S2 s2;
s2.m1 = 5;
S4 s4;
s4.m1 = 5;
S1 a1[10];
typedef S1 Array[10];
Array a2;
BREAK_HERE;
// Expand s2 s2.@1 s4 s4.@1
// CheckType a1 bug5799::S1 [10].
// CheckType a2 bug5799::Array.
// CheckType s2 bug5799::S2.
// CheckType s2.@1 bug5799::S1.
// Check s2.@1.m1 5 int.
// CheckType s2.@1.m2 int.
// CheckType s4 bug5799::S4.
// CheckType s4.@1 bug5799::S3.
// Check s4.@1.m1 5 int.
// CheckType s4.@1.m2 int.
// Continue.
dummyStatement(&s2, &s4, &a1, &a2);
}
} // namespace bug5799
namespace bug6813 {
// https://bugreports.qt.io/browse/QTCREATORBUG-6813
void test6813()
{
int foo = 0;
int *bar = &foo;
//std::cout << "&foo: " << &foo << "; bar: " << bar << "; &bar: " << &bar;
dummyStatement(&foo, &bar);
}
} // namespace bug6813
namespace qc41700 {
// http://www.qtcentre.org/threads/41700-How-to-watch-STL-containers-iterators-during-debugging
void test41700()
{
using namespace std;
typedef map<string, list<string> > map_t;
map_t m;
m["one"].push_back("a");
m["one"].push_back("b");
m["one"].push_back("c");
m["two"].push_back("1");
m["two"].push_back("2");
m["two"].push_back("3");
map_t::const_iterator it = m.begin();
BREAK_HERE;
// Expand m m.0 m.0.second m.1 m.1.second.
// Check m <2 items> qc41700::map_t.
// Check m.0 std::pair<std::string const, std::list<std::string>>.
// Check m.0.first "one" std::string.
// Check m.0.second <3 items> std::list<std::string>.
// Check m.0.second.0 "a" std::string.
// Check m.0.second.1 "b" std::string.
// Check m.0.second.2 "c" std::string.
// Check m.1 std::pair<std::string const, std::list<std::string>>.
// Check m.1.first "two" std::string.
// Check m.1.second <3 items> std::list<std::string>.
// Check m.1.second.0 "1" std::string.
// Check m.1.second.1 "2" std::string.
// Check m.1.second.2 "3" std::string.
// Continue.
dummyStatement(&it);
}
} // namespace qc41700
namespace cp42895 {
void g(int c, int d)
{
qDebug() << c << d;
BREAK_HERE;
// Check c 3 int.
// Check d 4 int.
// Continue.
// Check there are frames for g and f in the stack view.
dummyStatement(&c, &d);
}
void f(int a, int b)
{
g(a, b);
}
void test42895()
{
f(3, 4);
}
} // namespace cp
namespace bug6465 {
// https://bugreports.qt.io/browse/QTCREATORBUG-6465
void test6465()
{
typedef char Foo[20];
Foo foo = "foo";
char bar[20] = "baz";
// BREAK HERE
dummyStatement(&foo, &bar);
}
} // namespace bug6465
namespace bug6857 {
class MyFile : public QFile
{
public:
MyFile(const QString &fileName)
: QFile(fileName) {}
};
void test6857()
{
MyFile file("/tmp/tt");
file.setObjectName("A file");
BREAK_HERE;
// Expand file.
// Expand file.@1.
// Expand file.@1.@1.
// Check file bug6857::MyFile.
// Check file.@1 "/tmp/tt" QFile.
// Check file.@1.@1.@1 "A file" QObject.
// Continue.
dummyStatement(&file);
}
}
namespace bug6858 {
class MyFile : public QFile
{
public:
MyFile(const QString &fileName)
: QFile(fileName) {}
};
void test6858()
{
MyFile file("/tmp/tt");
file.setObjectName("Another file");
QFile *pfile = &file;
BREAK_HERE;
// Expand pfile.
// Expand pfile.@1.
// Expand pfile.@1.@1.
// Check pfile bug6858::MyFile.
// Check pfile.@1 "/tmp/tt" QFile.
// Check pfile.@1.@1.@1 "Another file" QObject.
// Continue.
dummyStatement(&file, pfile);
}
}
namespace bug6863 {
class MyObject : public QObject
{
Q_OBJECT
public:
MyObject() {}
};
void setProp(QObject *obj)
{
obj->setProperty("foo", "bar");
BREAK_HERE;
// Expand obj.
// Check obj.[QObject].properties <2 items>.
// Continue.
dummyStatement(&obj);
}
void test6863()
{
QFile file("/tmp/tt");
setProp(&file);
MyObject obj;
setProp(&obj);
}
}
namespace bug6933 {
class Base
{
public:
Base() : a(21) {}
virtual ~Base() {}
int a;
};
class Derived : public Base
{
public:
Derived() : b(42) {}
int b;
};
void test6933()
{
Derived d;
Base *b = &d;
BREAK_HERE;
// Expand b b.bug6933::Base
// Check b.[bug6933::Base].[vptr]
// Check b.b 42 int.
// Continue.
dummyStatement(&d, b);
}
}
namespace varargs {
void test(const char *format, ...)
{
va_list arg;
va_start(arg, format);
int i = va_arg(arg, int);
double f = va_arg(arg, double);
va_end(arg);
dummyStatement(&i, &f);
}
void testVaList()
{
test("abc", 1, 2.0);
}
} // namespace varargs
namespace gdb13393 {
struct Base {
Base() : a(1) {}
virtual ~Base() {} // Enforce type to have RTTI
int a;
};
struct Derived : public Base {
Derived() : b(2) {}
int b;
};
struct S
{
Base *ptr;
const Base *ptrConst;
Base &ref;
const Base &refConst;
S(Derived &d)
: ptr(&d), ptrConst(&d), ref(d), refConst(d)
{}
};
void test13393()
{
Derived d;
S s(d);
Base *ptr = &d;
const Base *ptrConst = &d;
Base &ref = d;
const Base &refConst = d;
Base **ptrToPtr = &ptr;
#if USE_BOOST
boost::shared_ptr<Base> sharedPtr(new Derived());
#else
int sharedPtr = 1;
#endif
BREAK_HERE;
// Expand d ptr ptr.@1 ptrConst ptrToPtr ref refConst s.
// CheckType d gdb13393::Derived.
// CheckType d.@1 gdb13393::Base.
// Check d.b 2 int.
// CheckType ptr gdb13393::Derived.
// CheckType ptr.@1 gdb13393::Base.
// Check ptr.@1.a 1 int.
// CheckType ptrConst gdb13393::Derived.
// CheckType ptrConst.@1 gdb13393::Base.
// Check ptrConst.b 2 int.
// CheckType ptrToPtr gdb13393::Derived.
// CheckType ptrToPtr.[vptr] .
// Check ptrToPtr.@1.a 1 int.
// CheckType ref gdb13393::Derived.
// CheckType ref.[vptr] .
// Check ref.@1.a 1 int.
// CheckType refConst gdb13393::Derived.
// CheckType refConst.[vptr] .
// Check refConst.@1.a 1 int.
// CheckType s gdb13393::S.
// CheckType s.ptr gdb13393::Derived.
// CheckType s.ptrConst gdb13393::Derived.
// CheckType s.ref gdb13393::Derived.
// CheckType s.refConst gdb13393::Derived.
// Check sharedPtr 1 int.
// Continue.
dummyStatement(&d, &s, &ptrToPtr, &sharedPtr, &ptrConst, &refConst, &ref);
}
} // namespace gdb13393
namespace gdb10586 {
// http://sourceware.org/bugzilla/show_bug.cgi?id=10586. fsf/MI errors out
// on -var-list-children on an anonymous union. mac/MI was fixed in 2006.
// The proposed fix has been reported to crash gdb steered from eclipse.
// http://sourceware.org/ml/gdb-patches/2011-12/msg00420.html
// Check we are not harmed by either version.
void testmi()
{
struct test {
struct { int a; float b; };
struct { int c; float d; };
} v = {{1, 2}, {3, 4}};
BREAK_HERE;
// Expand v.
// Check v gdb10586::test.
// Check v.a 1 int.
// Continue.
dummyStatement(&v);
}
void testeclipse()
{
struct { int x; struct { int a; }; struct { int b; }; } v = {1, {2}, {3}};
struct s { int x, y; } n = {10, 20};
BREAK_HERE;
// Expand v.
// Expand n.
// CheckType v {...}.
// CheckType n gdb10586::s.
// Check v.a 2 int.
// Check v.b 3 int.
// Check v.x 1 int.
// Check n.x 10 int.
// Check n.y 20 int.
// Continue.
dummyStatement(&v, &n);
}
void test10586()
{
testmi();
testeclipse();
}
} // namespace gdb10586
namespace valgrind {
void testLeak()
{
new int[100]; // Leaks intentionally.
}
void testValgrind()
{
testLeak();
}
} // namespace valgrind
namespace tmplate {
template<typename T> struct Template
{
Template() : t() {}
// This serves as a manual test that multiple breakpoints work.
// Each of the two '// BREAK_HERE' below is in a function that
// is instantiated three times, so both should be reported as
// breakpoints with three subbreakpoints each.
template <typename S> void fooS(S s)
{
t = s;
// BREAK_HERE;
}
template <int N> void fooN()
{
t = N;
// BREAK_HERE;
}
T t;
};
void testTemplate()
{
Template<double> t;
t.fooS(1);
t.fooS(1.);
t.fooS('a');
t.fooN<2>();
t.fooN<3>();
t.fooN<4>();
dummyStatement(&t, &t.t);
}
} // namespace tmplate
namespace sanity {
// A very quick check.
void testSanity()
{
std::string s;
s = "hallo";
s += "hallo";
QVector<int> qv;
qv.push_back(2);
std::vector<int> v;
v.push_back(2);
QStringList list;
list << "aaa" << "bbb" << "cc";
QList<const char *> list2;
list2 << "foo";
list2 << "bar";
list2 << 0;
list2 << "baz";
list2 << 0;
QObject obj;
obj.setObjectName("An Object");
BREAK_HERE;
// Check list <3 items> QStringList
// Check list2 <5 items> QList<char const*>
// Check obj "An Object" QObject
// Check qv <1 items> QVector<int>
// Check s "hallohallo" std::string
// Check v <1 items> std::vector<int>
// Continue
dummyStatement(&s, &qv, &v, &list, &list2, &obj);
}
} // namespace sanity
template <class X> int ffff(X)
{
return sizeof(X);
}
int main(int argc, char *argv[])
{
int z = ffff(3) + ffff(2.0);
Q_UNUSED(z);
#if USE_GUILIB
QApplication app(argc, argv);
#else
QCoreApplication app(argc, argv);
#endif
QChar c(0x1E9E);
bool b = c.isPrint();
qDebug() << c << b;
// Notify Creator about auto run intention.
if (USE_AUTORUN)
qWarning("Creator: Switch on magic autorun.");
else
qWarning("Creator: Switch off magic autorun.");
// For a very quick check, step into this one.
sanity::testSanity();
// Check for normal dumpers.
basic::testBasic();
gccextensions::testGccExtensions();
qhostaddress::testQHostAddress();
varargs::testVaList();
formats::testFormats();
breakpoints::testBreakpoints();
peekandpoke::testPeekAndPoke3();
anon::testAnonymous();
itemmodel::testItemModel();
noargs::testNoArgumentName(1, 2, 3);
text::testText();
io::testIO();
catchthrow::testCatchThrow();
undefined::testUndefined();
plugin::testPlugin();
valgrind::testValgrind();
namespc::testNamespace();
tmplate::testTemplate();
painting::testPainting();
webkit::testWebKit();
stdarray::testStdArray();
stdcomplex::testStdComplex();
stddeque::testStdDeque();
stdlist::testStdList();
stdhashset::testStdHashSet();
stdmap::testStdMap();
stdunorderedmap::testStdUnorderedMap();
stdset::testStdSet();
stdstack::testStdStack();
stdstream::testStdStream();
stdstring::testStdString();
stdvector::testStdVector();
stdptr::testStdPtr();
lambda::testLambda();
qbytearray::testQByteArray();
qdatetime::testDateTime();
qdir::testQDir();
qfileinfo::testQFileInfo();
qhash::testQHash();
qlinkedlist::testQLinkedList();
qlist::testQList();
qlocale::testQLocale();
qmap::testQMap();
qobject::testQObject();
qrect::testGeometry();
qregexp::testQRegExp();
qregion::testQRegion();
qscript::testQScript();
qset::testQSet();
qsharedpointer::testQSharedPointer();
qstack::testQStack();
qstringlist::testQStringList();
qstring::testQString();
qthread::testQThread();
qprocess::testQProcess();
qurl::testQUrl();
qvariant::testQVariant();
qvector::testQVector();
qxml::testQXmlAttributes();
// Third party data types.
boost::testBoost();
eigen::testEigen();
kr::testKR();
mpi::testMPI();
sse::testSSE();
// The following tests are specific to certain bugs.
// They need not to be checked during a normal release check.
cp42895::test42895();
bug5046::test5046();
bug4904::test4904();
qc41700::test41700();
qc42170::test42170();
multibp::testMultiBp();
bug842::test842();
bug3611::test3611();
bug4019::test4019();
bug4997::test4997();
bug5106::test5106();
bug5184::test5184();
bug5799::test5799();
bug6813::test6813();
bug6465::test6465();
bug6857::test6857();
bug6858::test6858();
bug6863::test6863();
bug6933::test6933();
gdb13393::test13393();
gdb10586::test10586();
final::testFinal(&app);
return 0;
}
#include "simple_test_app.moc"
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