QVariant实质 (类似 C#中的装箱拆箱)
QVariant是一种可以存储不同类型的数据结构,在很多场合这是很有用得
为了达到这种目的,可以想象,该对象应该存储对象的类型信息,数据信息以及其他辅助详细
考虑用途,这种对象必须支持对不同对象的存储,对存储类型的检测以及取对象三个功能
1.对象的存储
代码见下:
QVariant(Type type);
QVariant(int typeOrUserType, const void *copy);
QVariant(int typeOrUserType, const void *copy, uint flags);
QVariant(const QVariant &other);
#ifndef QT_NO_DATASTREAM
QVariant(QDataStream &s);
#endif
QVariant(int i);
QVariant(uint ui);
QVariant(qlonglong ll);
QVariant(qulonglong ull);
QVariant(bool b);
QVariant(double d);
QVariant(float f) { d.is_null = false; d.type = QMetaType::Float; d.data.f =f; }
#ifndef QT_NO_CAST_FROM_ASCII
QT_ASCII_CAST_WARN_CONSTRUCTOR QVariant(const char *str);
#endif
QVariant(const QByteArray &bytearray);
QVariant(const QBitArray &bitarray);
QVariant(const QString &string);
QVariant(const QLatin1String &string);
QVariant(const QStringList &stringlist);
QVariant(const QChar &qchar);
QVariant(const QDate &date);
QVariant(const QTime &time);
QVariant(const QDateTime &datetime);
QVariant(const QList<</SPAN>QVariant> &list);
QVariant(const QMap<</SPAN>QString,QVariant> &map);
QVariant(const QHash<</SPAN>QString,QVariant> &hash);
#ifndef QT_NO_GEOM_VARIANT
QVariant(const QSize &size);
QVariant(const QSizeF &size);
QVariant(const QPoint &pt);
QVariant(const QPointF &pt);
QVariant(const QLine &line);
QVariant(const QLineF &line);
QVariant(const QRect &rect);
QVariant(const QRectF &rect);
#endif
QVariant(const QUrl &url);
QVariant(const QLocale &locale);
#ifndef QT_NO_REGEXP
QVariant(const QRegExp ®Exp);
#endif
#ifndef QT_BOOTSTRAPPED
QVariant(const QEasingCurve &easing);
#endif
QVariant(Qt::GlobalColor color);
为了达到这种目的,可以想象,该对象应该存储对象的类型信息,数据信息以及其他辅助详细
考虑用途,这种对象必须支持对不同对象的存储,对存储类型的检测以及取对象三个功能
1.对象的存储
代码见下:
QVariant(Type type);
QVariant(int typeOrUserType, const void *copy);
QVariant(int typeOrUserType, const void *copy, uint flags);
QVariant(const QVariant &other);
#ifndef QT_NO_DATASTREAM
QVariant(QDataStream &s);
#endif
QVariant(int i);
QVariant(uint ui);
QVariant(qlonglong ll);
QVariant(qulonglong ull);
QVariant(bool b);
QVariant(double d);
QVariant(float f) { d.is_null = false; d.type = QMetaType::Float; d.data.f =f; }
#ifndef QT_NO_CAST_FROM_ASCII
QT_ASCII_CAST_WARN_CONSTRUCTOR QVariant(const char *str);
#endif
QVariant(const QByteArray &bytearray);
QVariant(const QBitArray &bitarray);
QVariant(const QString &string);
QVariant(const QLatin1String &string);
QVariant(const QStringList &stringlist);
QVariant(const QChar &qchar);
QVariant(const QDate &date);
QVariant(const QTime &time);
QVariant(const QDateTime &datetime);
QVariant(const QList<</SPAN>QVariant> &list);
QVariant(const QMap<</SPAN>QString,QVariant> &map);
QVariant(const QHash<</SPAN>QString,QVariant> &hash);
#ifndef QT_NO_GEOM_VARIANT
QVariant(const QSize &size);
QVariant(const QSizeF &size);
QVariant(const QPoint &pt);
QVariant(const QPointF &pt);
QVariant(const QLine &line);
QVariant(const QLineF &line);
QVariant(const QRect &rect);
QVariant(const QRectF &rect);
#endif
QVariant(const QUrl &url);
QVariant(const QLocale &locale);
#ifndef QT_NO_REGEXP
QVariant(const QRegExp ®Exp);
#endif
#ifndef QT_BOOTSTRAPPED
QVariant(const QEasingCurve &easing);
#endif
QVariant(Qt::GlobalColor color);
2.QVariant Type
在该对象中type负责记录对象的类型,这对于正确取出对象是很用得
3.成员函数
Type type() const;
int userType() const;
const char *typeName() const;
bool canConvert(Type t) const;
bool convert(Type t);
#ifdef QT3_SUPPORT
inline QT3_SUPPORT bool canCast(Type t) const
{ return canConvert(t); }
inline QT3_SUPPORT bool cast(Type t)
{ return convert(t); }
#endif
在该对象中type负责记录对象的类型,这对于正确取出对象是很用得
3.成员函数
Type type() const;
int userType() const;
const char *typeName() const;
bool canConvert(Type t) const;
bool convert(Type t);
#ifdef QT3_SUPPORT
inline QT3_SUPPORT bool canCast(Type t) const
{ return canConvert(t); }
inline QT3_SUPPORT bool cast(Type t)
{ return convert(t); }
#endif
这几个函数的用途很显然,看看其中一个的实现吧
bool QVariant::canConvert(Type t) const
{
//we can treat floats as double
//the reason for not doing it the "proper" way is that QMetaType::Float's value is 135,
//which can't be handled by qCanConvertMatrix
//In addition QVariant::Type doesn't have a Float value, so we're using QMetaType::Float
const uint currentType = ((d.type == QMetaType::Float) ? QVariant::Double : d.type);
if (uint(t) == uint(QMetaType::Float)) t = QVariant::Double;
if (currentType == uint(t))
return true;
if (currentType > QVariant::LastCoreType || t > QVariant::LastCoreType) {
switch (uint(t)) {
case QVariant::Int:
return currentType == QVariant::KeySequence
|| currentType == QMetaType::ULong
|| currentType == QMetaType::Long
|| currentType == QMetaType::UShort
|| currentType == QMetaType::UChar
|| currentType == QMetaType::Char
|| currentType == QMetaType::Short;
case QVariant::Image:
return currentType == QVariant::Pixmap || currentType == QVariant::Bitmap;
case QVariant::Pixmap:
return currentType == QVariant::Image || currentType == QVariant::Bitmap
|| currentType == QVariant::Brush;
case QVariant::Bitmap:
return currentType == QVariant::Pixmap || currentType == QVariant::Image;
case QVariant::ByteArray:
return currentType == QVariant::Color;
case QVariant::String:
return currentType == QVariant::KeySequence || currentType == QVariant::Font
|| currentType == QVariant::Color;
case QVariant::KeySequence:
return currentType == QVariant::String || currentType == QVariant::Int;
case QVariant::Font:
return currentType == QVariant::String;
case QVariant::Color:
return currentType == QVariant::String || currentType == QVariant::ByteArray
|| currentType == QVariant::Brush;
case QVariant::Brush:
return currentType == QVariant::Color || currentType == QVariant::Pixmap;
case QMetaType::Long:
case QMetaType::Char:
case QMetaType::UChar:
case QMetaType::ULong:
case QMetaType::Short:
case QMetaType::UShort:
return qCanConvertMatrix[QVariant::Int] & (1 << currentType) || currentType== QVariant::Int;
default:
return false;
}
}
if(t == String && currentType == StringList)
return v_cast<</SPAN>QStringList>(&d)->count() == 1;
else
return qCanConvertMatrix[t] & (1 << currentType);
}
bool QVariant::canConvert(Type t) const
{
//we can treat floats as double
//the reason for not doing it the "proper" way is that QMetaType::Float's value is 135,
//which can't be handled by qCanConvertMatrix
//In addition QVariant::Type doesn't have a Float value, so we're using QMetaType::Float
const uint currentType = ((d.type == QMetaType::Float) ? QVariant::Double : d.type);
if (uint(t) == uint(QMetaType::Float)) t = QVariant::Double;
if (currentType == uint(t))
return true;
if (currentType > QVariant::LastCoreType || t > QVariant::LastCoreType) {
switch (uint(t)) {
case QVariant::Int:
return currentType == QVariant::KeySequence
|| currentType == QMetaType::ULong
|| currentType == QMetaType::Long
|| currentType == QMetaType::UShort
|| currentType == QMetaType::UChar
|| currentType == QMetaType::Char
|| currentType == QMetaType::Short;
case QVariant::Image:
return currentType == QVariant::Pixmap || currentType == QVariant::Bitmap;
case QVariant::Pixmap:
return currentType == QVariant::Image || currentType == QVariant::Bitmap
|| currentType == QVariant::Brush;
case QVariant::Bitmap:
return currentType == QVariant::Pixmap || currentType == QVariant::Image;
case QVariant::ByteArray:
return currentType == QVariant::Color;
case QVariant::String:
return currentType == QVariant::KeySequence || currentType == QVariant::Font
|| currentType == QVariant::Color;
case QVariant::KeySequence:
return currentType == QVariant::String || currentType == QVariant::Int;
case QVariant::Font:
return currentType == QVariant::String;
case QVariant::Color:
return currentType == QVariant::String || currentType == QVariant::ByteArray
|| currentType == QVariant::Brush;
case QVariant::Brush:
return currentType == QVariant::Color || currentType == QVariant::Pixmap;
case QMetaType::Long:
case QMetaType::Char:
case QMetaType::UChar:
case QMetaType::ULong:
case QMetaType::Short:
case QMetaType::UShort:
return qCanConvertMatrix[QVariant::Int] & (1 << currentType) || currentType== QVariant::Int;
default:
return false;
}
}
if(t == String && currentType == StringList)
return v_cast<</SPAN>QStringList>(&d)->count() == 1;
else
return qCanConvertMatrix[t] & (1 << currentType);
}
该函数作用是检测存储对象是否可以转换为输入类型,具体实现很明了
4.QVariant对象的最后一个主要的功能就是到给定类型的转换
函数簇如下:
int toInt(bool *ok = 0) const;
uint toUInt(bool *ok = 0) const;
qlonglong toLongLong(bool *ok = 0) const;
qulonglong toULongLong(bool *ok = 0) const;
bool toBool() const;
double toDouble(bool *ok = 0) const;
float toFloat(bool *ok = 0) const;
qreal toReal(bool *ok = 0) const;
QByteArray toByteArray() const;
QBitArray toBitArray() const;
QString toString() const;
QStringList toStringList() const;
QChar toChar() const;
QDate toDate() const;
QTime toTime() const;
QDateTime toDateTime() const;
QList<</SPAN>QVariant> toList() const;
QMap<</SPAN>QString, QVariant> toMap() const;
QHash<</SPAN>QString, QVariant> toHash() const;
4.QVariant对象的最后一个主要的功能就是到给定类型的转换
函数簇如下:
int toInt(bool *ok = 0) const;
uint toUInt(bool *ok = 0) const;
qlonglong toLongLong(bool *ok = 0) const;
qulonglong toULongLong(bool *ok = 0) const;
bool toBool() const;
double toDouble(bool *ok = 0) const;
float toFloat(bool *ok = 0) const;
qreal toReal(bool *ok = 0) const;
QByteArray toByteArray() const;
QBitArray toBitArray() const;
QString toString() const;
QStringList toStringList() const;
QChar toChar() const;
QDate toDate() const;
QTime toTime() const;
QDateTime toDateTime() const;
QList<</SPAN>QVariant> toList() const;
QMap<</SPAN>QString, QVariant> toMap() const;
QHash<</SPAN>QString, QVariant> toHash() const;
其一个实现如下:
QTime QVariant::toTime() const
{
return qVariantToHelper<</SPAN>QTime>(d, Time, handler);
}
使用了模板函数:qVariantToHelper
5.关于qVariantToHelper
QTime QVariant::toTime() const
{
return qVariantToHelper<</SPAN>QTime>(d, Time, handler);
}
使用了模板函数:qVariantToHelper
5.关于qVariantToHelper
template <</SPAN>typename T>
inline T qVariantToHelper(const QVariant::Private &d, QVariant::Type t,
const QVariant::Handler *handler, T * = 0)
{
if (d.type == t)
return *v_cast<</SPAN>T>(&d);
T ret;
handler->convert(&d, t, &ret, 0);
return ret;
}
该函数根据对象信息和目标类型做转换工作,如果二者类型一致,则直接做转换,否则交给函数handler->convert处理
6.关于Handler对象
struct Handler {
f_construct construct;
f_clear clear;
f_null isNull;
#ifndef QT_NO_DATASTREAM
f_load load;
f_save save;
#endif
f_compare compare;
f_convert convert;
f_canConvert canConvert;
f_debugStream debugStream;
};
不过好像没看出什么门道,那就继续看看
其实际结构为:
const QVariant::Handler qt_kernel_variant_handler = {
construct,
clear,
isNull,
#ifndef QT_NO_DATASTREAM
0,
0,
#endif
compare,
convert,
0,
#if !defined(QT_NO_DEBUG_STREAM) && !defined(Q_BROKEN_DEBUG_STREAM)
streamDebug
#else
0
#endif
};
其实际结构为:
const QVariant::Handler qt_kernel_variant_handler = {
construct,
clear,
isNull,
#ifndef QT_NO_DATASTREAM
0,
0,
#endif
compare,
convert,
0,
#if !defined(QT_NO_DEBUG_STREAM) && !defined(Q_BROKEN_DEBUG_STREAM)
streamDebug
#else
0
#endif
};
再看其中 一个函数实现constuct
static void construct(QVariant::Private *x, const void *copy)
{
x->is_shared = false;
switch (x->type) {
case QVariant::String:
v_construct<</SPAN>QString>(x, copy);
break;
case QVariant::Char:
v_construct<</SPAN>QChar>(x, copy);
break;
case QVariant::StringList:
v_construct<</SPAN>QStringList>(x, copy);
break;
case QVariant::Map:
v_construct<</SPAN>QVariantMap>(x, copy);
break;
case QVariant::Hash:
v_construct<</SPAN>QVariantHash>(x, copy);
break;
case QVariant::List:
v_construct<</SPAN>QVariantList>(x, copy);
break;
case QVariant::Date:
v_construct<</SPAN>QDate>(x, copy);
break;
case QVariant::Time:
v_construct<</SPAN>QTime>(x, copy);
break;
case QVariant::DateTime:
v_construct<</SPAN>QDateTime>(x, copy);
break;
case QVariant::ByteArray:
v_construct<</SPAN>QByteArray>(x, copy);
break;
case QVariant::BitArray:
v_construct<</SPAN>QBitArray>(x, copy);
break;
#ifndef QT_NO_GEOM_VARIANT
case QVariant::Size:
v_construct<</SPAN>QSize>(x, copy);
break;
case QVariant::SizeF:
v_construct<</SPAN>QSizeF>(x, copy);
break;
case QVariant::Rect:
v_construct<</SPAN>QRect>(x, copy);
break;
case QVariant::LineF:
v_construct<</SPAN>QLineF>(x, copy);
break;
case QVariant::Line:
v_construct<</SPAN>QLine>(x, copy);
break;
case QVariant::RectF:
v_construct<</SPAN>QRectF>(x, copy);
break;
case QVariant::Point:
v_construct<</SPAN>QPoint>(x, copy);
break;
case QVariant::PointF:
v_construct<</SPAN>QPointF>(x, copy);
break;
#endif
case QVariant::Url:
v_construct<</SPAN>QUrl>(x, copy);
break;
case QVariant::Locale:
v_construct<</SPAN>QLocale>(x, copy);
break;
#ifndef QT_NO_REGEXP
case QVariant::RegExp:
v_construct<</SPAN>QRegExp>(x, copy);
break;
#endif
#ifndef QT_BOOTSTRAPPED
case QVariant::EasingCurve:
v_construct<</SPAN>QEasingCurve>(x, copy);
break;
#endif
case QVariant::Int:
x->data.i = copy ? *static_cast<</SPAN>const int *>(copy) : 0;
break;
case QVariant::UInt:
x->data.u = copy ? *static_cast<</SPAN>const uint *>(copy) : 0u;
break;
case QVariant::Bool:
x->data.b = copy ? *static_cast<</SPAN>const bool *>(copy) : false;
break;
case QVariant::Double:
x->data.d = copy ? *static_cast<</SPAN>const double*>(copy) : 0.0;
break;
case QMetaType::Float:
x->data.f = copy ? *static_cast<</SPAN>const float*>(copy) : 0.0f;
break;
case QMetaType::QObjectStar:
x->data.o = copy ? *static_cast<</SPAN>QObject *const*>(copy) : 0;
break;
case QVariant::LongLong:
x->data.ll = copy ? *static_cast<</SPAN>const qlonglong *>(copy) : Q_INT64_C(0);
break;
case QVariant::ULongLong:
x->data.ull = copy ? *static_cast<</SPAN>const qulonglong *>(copy) : Q_UINT64_C(0);
break;
case QVariant::Invalid:
case QVariant::UserType:
break;
default:
void *ptr = QMetaType::construct(x->type, copy);
if (!ptr) {
x->type = QVariant::Invalid;
} else {
x->is_shared = true;
x->data.shared = new QVariant::PrivateShared(ptr);
}
break;
}
x->is_null = !copy;
}
static void construct(QVariant::Private *x, const void *copy)
{
x->is_shared = false;
switch (x->type) {
case QVariant::String:
v_construct<</SPAN>QString>(x, copy);
break;
case QVariant::Char:
v_construct<</SPAN>QChar>(x, copy);
break;
case QVariant::StringList:
v_construct<</SPAN>QStringList>(x, copy);
break;
case QVariant::Map:
v_construct<</SPAN>QVariantMap>(x, copy);
break;
case QVariant::Hash:
v_construct<</SPAN>QVariantHash>(x, copy);
break;
case QVariant::List:
v_construct<</SPAN>QVariantList>(x, copy);
break;
case QVariant::Date:
v_construct<</SPAN>QDate>(x, copy);
break;
case QVariant::Time:
v_construct<</SPAN>QTime>(x, copy);
break;
case QVariant::DateTime:
v_construct<</SPAN>QDateTime>(x, copy);
break;
case QVariant::ByteArray:
v_construct<</SPAN>QByteArray>(x, copy);
break;
case QVariant::BitArray:
v_construct<</SPAN>QBitArray>(x, copy);
break;
#ifndef QT_NO_GEOM_VARIANT
case QVariant::Size:
v_construct<</SPAN>QSize>(x, copy);
break;
case QVariant::SizeF:
v_construct<</SPAN>QSizeF>(x, copy);
break;
case QVariant::Rect:
v_construct<</SPAN>QRect>(x, copy);
break;
case QVariant::LineF:
v_construct<</SPAN>QLineF>(x, copy);
break;
case QVariant::Line:
v_construct<</SPAN>QLine>(x, copy);
break;
case QVariant::RectF:
v_construct<</SPAN>QRectF>(x, copy);
break;
case QVariant::Point:
v_construct<</SPAN>QPoint>(x, copy);
break;
case QVariant::PointF:
v_construct<</SPAN>QPointF>(x, copy);
break;
#endif
case QVariant::Url:
v_construct<</SPAN>QUrl>(x, copy);
break;
case QVariant::Locale:
v_construct<</SPAN>QLocale>(x, copy);
break;
#ifndef QT_NO_REGEXP
case QVariant::RegExp:
v_construct<</SPAN>QRegExp>(x, copy);
break;
#endif
#ifndef QT_BOOTSTRAPPED
case QVariant::EasingCurve:
v_construct<</SPAN>QEasingCurve>(x, copy);
break;
#endif
case QVariant::Int:
x->data.i = copy ? *static_cast<</SPAN>const int *>(copy) : 0;
break;
case QVariant::UInt:
x->data.u = copy ? *static_cast<</SPAN>const uint *>(copy) : 0u;
break;
case QVariant::Bool:
x->data.b = copy ? *static_cast<</SPAN>const bool *>(copy) : false;
break;
case QVariant::Double:
x->data.d = copy ? *static_cast<</SPAN>const double*>(copy) : 0.0;
break;
case QMetaType::Float:
x->data.f = copy ? *static_cast<</SPAN>const float*>(copy) : 0.0f;
break;
case QMetaType::QObjectStar:
x->data.o = copy ? *static_cast<</SPAN>QObject *const*>(copy) : 0;
break;
case QVariant::LongLong:
x->data.ll = copy ? *static_cast<</SPAN>const qlonglong *>(copy) : Q_INT64_C(0);
break;
case QVariant::ULongLong:
x->data.ull = copy ? *static_cast<</SPAN>const qulonglong *>(copy) : Q_UINT64_C(0);
break;
case QVariant::Invalid:
case QVariant::UserType:
break;
default:
void *ptr = QMetaType::construct(x->type, copy);
if (!ptr) {
x->type = QVariant::Invalid;
} else {
x->is_shared = true;
x->data.shared = new QVariant::PrivateShared(ptr);
}
break;
}
x->is_null = !copy;
}
继续看v_construct
该函数模板实现和平台有关,其中一个平台的实现如下:
template <</SPAN>class T>
inline void v_construct(QVariant::Private *x, const void *copy, T * = 0)
{
if (sizeof(T) > sizeof(QVariant::Private::Data)) {
x->data.shared = copy ? new QVariantPrivateSharedEx<</SPAN>T>(*static_cast<</SPAN>const T *>(copy))
: new QVariantPrivateSharedEx<</SPAN>T>;
x->is_shared = true;
} else {
if (copy)
new (&x->data.ptr) T(*static_cast<</SPAN>const T *>(copy));
else
new (&x->data.ptr) T;
}
}
该函数模板实现和平台有关,其中一个平台的实现如下:
template <</SPAN>class T>
inline void v_construct(QVariant::Private *x, const void *copy, T * = 0)
{
if (sizeof(T) > sizeof(QVariant::Private::Data)) {
x->data.shared = copy ? new QVariantPrivateSharedEx<</SPAN>T>(*static_cast<</SPAN>const T *>(copy))
: new QVariantPrivateSharedEx<</SPAN>T>;
x->is_shared = true;
} else {
if (copy)
new (&x->data.ptr) T(*static_cast<</SPAN>const T *>(copy));
else
new (&x->data.ptr) T;
}
}
这里主要是把传入对象指针导入为本身的数据指针data.ptr
QVariant大致就这个样子
QVariant大致就这个样子
http://blog.sina.com.cn/s/blog_a401a1ea0101i8k9.html
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有时需要用同一个变量来保存不同类型的数据。一种方法是将数据编码为QByteArray 或QString。如串既可保存文本也可保存数字。Qt提供了一种更好的方式使用QVariant.
QVariant类可以保存许多Qt类型的值,包括QBrush, QColor, QCursor, QDateTime, QFont,QKeySequence, QPalette, QPen, QPixmap, QPoint, QRect, QRegion, QSize, 和QString,也包括基本的C++数字类型,如double和 int.还可保存容器如QMap, QStringList, 和 QList。
使用QVariant通过嵌套容器类型值,可以创建任意复杂的数据结构:
QMap pearMap;
pearMap["Standard"] = 1.95;
pearMap["Organic"] = 2.25;
QMap fruitMap;
fruitMap["Orange"] = 2.10;
fruitMap["Pineapple"] = 3.85;
fruitMap["Pear"] = pearMap;
此处我们创建了一个map,拥有string键(产品名),值要么是浮点数(价格)或要么是map。顶层map有三个键:"Orange", "Pear", 和 "Pineapple"。与"Pear"键相对应的值是一个map,含有两个键("Standard" and "Organic").当遍历保存可变值的map时,需要用type()来检查类型。
创建这样的数据结构看起来很好,但QVariant以牺牲效率和可读性为代价。所以通常定义一个恰当的C++类来保存数据。
QIcon icon("open.png");
QVariant variant = icon;
为获得来自QVariant的GUI-related类型的值,可使用QVariant::value()模板函数:
QIcon icon = variant.value();
value()函数也用于非GUI数据类型与QVariant之间的转换,但实际上我们经常使用to...()转换函数(如,toString())。
QVariant也能用于保存自定义的数据类型,假设这些类型能提供一个默认构造函数和拷贝构造函数。因此,首先要用Q_DECLARE_METATYPE()宏注册该类型,特别是在头文件中类定义的下面:
Q_DECLARE_METATYPE(BusinessCard)
代码如下:
BusinessCard businessCard;
QVariant variant = QVariant::fromValue(businessCard);
...
if (variant.canConvert()) {
BusinessCard card = variant.value();
...
}
因受编译器的限制,MSVC 6不能获得这些模板函数。如果想用这种编译器,使用qVariantFromValue(), qVariantValue(), 和 qVariantCanConvert()全局函数。
如果自定义数据类型有<< 和 >>运算符用于QDataStream的写和读,可以使用qRegisterMetaTypeStreamOperators()注册这些运算符。这样就可以使用QSettings来保存自定义类型的参数。如:
qRegisterMetaTypeStreamOperators("BusinessCard");
Qt还提供其它的一些容器。QPair只保存两个值,类似于std::pair. QBitArray会在第十九章中使用。QVarLengthArray是一个对QVector的低级替代,因为它在栈上分配内存不能implicitly shared,它的overhead比QVector的少,所以它更适合紧循环(tight loops)。
http://blog.sina.com.cn/s/blog_a401a1ea0101f8nv.html
