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Você encontrará quatro estilos principais de marcação de variáveis de membros da classe no KDE, além de membros não marcados: | Você encontrará quatro estilos principais de marcação de variáveis de membros da classe no KDE, além de membros não marcados: | ||
*'' 'm_variable' '' m minúsculo, sublinhado e o nome da variável começando com uma letra minúscula. Este é o estilo mais comum e o preferido para o código no kdelibs. | * '''m_variable''' m minúsculo, sublinhado e o nome da variável começando com uma letra minúscula. Este é o estilo mais comum e o preferido para o código no kdelibs. | ||
* '' 'mVariable' '' m minúsculo e o nome da variável iniciada com uma letra maiúscula | * '' 'mVariable' '' m minúsculo e o nome da variável iniciada com uma letra maiúscula |
Revision as of 16:36, 3 December 2019
Tutorial Series | Iniciando |
Previous | None |
What's Next | n/a |
Further Reading | APIs to avoid |
Resumo
Este tutorial tem como objetivo combinar a experiência dos desenvolvedores KDE em relação aos prós e contras dos frameworks Qt e KDE. Além de erros reais, ele também cobre coisas que não são necessariamente "bugs", mas que tornam o código mais lento ou menos legível.
C ++ em geral
Esta seção te guia por alguns dos cantos mais empoeirados do C ++ que tende a ser mal utilizado ou que as pessoas também simplesmente erram.
Anonymous namespaces vs statics
Se você possui um método em uma classe que não acessa nenhum membro e, portanto, não precisa de um objeto para operar, torne-o estático. Se, além disso, for uma função auxiliar privada que não é necessária fora do arquivo, torne-a uma função estática do arquivo. Isso esconde o símbolo completamente.
Os símbolos definidos em um anonymous namespace C++ não têm ligação interna. Os anonymous namespaces fornecem apenas um nome exclusivo para essa unidade de tradução e é isso; eles não alteram a ligação do símbolo. A ligação não é alterada naquelas porque a segunda fase da pesquisa de nome em duas fases ignora as funções com ligações internas. Além disso, entidades com ligação interna não podem ser usadas como argumentos de template.
Portanto, dessa vez, ao invés de usar anonymous namespaces, use static se você não quiser que um símbolo seja exportado.
Problemas de ponteiro NULL
Em primeiro lugar: tudo bem excluir um ponteiro nulo. Portanto, construções como esta que verificam se há nulo antes de excluir são simplesmente redundantes:
if ( ptr ) {
delete ptr;
}
Observe, no entanto, que a null check é necessária quando você exclui uma matriz - isso ocorre porque um compilador relativamente recente no Solaris não lida com isso adequadamente.
Ao excluir um ponteiro, certifique-se de defini-lo também como 0, para que futuras tentativas de excluir esse objeto não falhem em uma exclusão dupla. Portanto, a maneira completa e adequada é:
delete ptr;
ptr = 0;
Você pode perceber que ponteiros nulos são variavelmente marcados em uma das quatro maneiras: 0, 0L, NULL e nullptr. Em C, NULL é definido como um ponteiro void. No C ++, é possível maior segurança devido a uma verificação mais rigorosa de tipo. As implementações modernas do C++11 (e todas as implementações do C++14) definem NULL para igual ao valor especial nullptr. Nullptr pode ser convertido automaticamente para booleano false, mas uma conversão para um tipo inteiro falhará. Isso é útil para evitar acidentes. As implementações mais antigas do C++ anteriores ao c++11 simplesmente definiam NULL como 0L ou 0, o que não fornece segurança de tipo adicional - é possível atribuí-lo a uma variável inteira, o que está obviamente errado. Para código que não precisa suportar compiladores desatualizados, a melhor opção é nullptr.
No contexto de ponteiro, a constante inteira zero significa "ponteiro nulo" - independentemente da representação binária real de um ponteiro nulo. Observe, no entanto, que se você deseja passar uma constante de ponteiro nulo para uma função em uma lista de variáveis como argumentos, você *deve* convertê-la explicitamente em um ponteiro - o compilador assume o contexto inteiro por padrão, o que pode ou não corresponder a representação binária de um ponteiro.
Variáveis membro
Você encontrará quatro estilos principais de marcação de variáveis de membros da classe no KDE, além de membros não marcados:
- m_variable m minúsculo, sublinhado e o nome da variável começando com uma letra minúscula. Este é o estilo mais comum e o preferido para o código no kdelibs.
- 'mVariable' m minúsculo e o nome da variável iniciada com uma letra maiúscula
- variable_ variable name starting with a lowercase letter and then an underscore
- _variable underscore and the name of variable starting with a lowercase letter. This style is actually usually frowned upon as this notation is also used in some code for function parameters instead.
Unmarked members are more common in the case of classes that use d-pointers.
As it often happens there is no one correct way of doing it, so remember to always follow the syntax used by the application/library to which you are committing. If you're creating a new file, you may want to follow the coding style of the library or module you're adding the file to.
Note that symbols starting with undercores are reserved to the C library (underscore followed by capital or double underscore are reserved to the compiler), so if you can, avoid using the last type.
Static variables
Try to limit the number of static variables used in your code, especially when committing to a library. Construction and initialization of a large number of static variables really hurts the startup times.
Do not use class-static variables, especially not in libraries and loadable modules though it is even discouraged in applications. Static objects lead to lots of problems such as hard to debug crashes due to undefined order of construction/destruction.
Instead, use a static pointer, together with K_GLOBAL_STATIC which is defined in kglobal.h and is used like this:
class A { ... };
K_GLOBAL_STATIC(A, globalA)
void doSomething()
{
A *a = globalA;
...
}
void doSomethingElse()
{
if (globalA.isDestroyed()) {
return;
}
A *a = globalA;
...
}
void installPostRoutine()
{
qAddPostRoutine(globalA.destroy);
}
See the API documentation for K_GLOBAL_STATIC for more information.
Constant data
If you need some constant data of simple data types in several places, you do good by defining it once at a central place, to avoid a mistype in one of the instances. If the data changes there is also only one place you need to edit.
Even if there is only one instance you do good by defining it elsewhere, to avoid so-called "magic numbers" in the code which are unexplained (cmp. 42). Usually this is done at the top of a file to avoid searching for it.
Define the constant data using the language constructs of C++, not the preprocessor instructions, like you may be used to from plain C. This way the compiler can help you to find mistakes by doing type checking.
// Correct!
static const int AnswerToAllQuestions = 42;
// Wrong!
#define AnswerToAllQuestions 42
If defining a constant array do not use a pointer as data type. Instead use the data type and append the array symbol with undefined length, [], behind the name. Otherwise you also define a variable to some const data. That variable could mistakenly be assigned a new pointer to, without the compiler complaining about. And accessing the array would have one indirection, because first the value of the variable needs to be read.
// Correct!
static const char SomeString[] = "Example";
// Wrong!
static const char* SomeString = "Example";
// Wrong!
#define SomeString "Example"
Forward Declarations
You will reduce compile times by forward declaring classes when possible instead of including their respective headers. The rules for when a type can be used without being defined are a bit subtle, but intuitively, if the only important aspect is the name of the class, not the details of its implementation, a forward declaration is permissible. Two examples are when declaring pointers to the class or using the class as a function argument.
For example:
#include <QWidget> // slow
#include <QStringList> // slow
#include <QString> // slow
#include <QIcon> //slow
class SomeClass
{
public:
virtual void widgetAction( QWidget *widget ) =0;
virtual void stringAction( const QString& str ) =0;
virtual void stringListAction( const QStringList& strList ) =0;
private:
QIcon *icon;
};
The above should instead be written like this:
class QWidget; // fast
class QStringList; // fast
class QString; // fast
class QIcon; // fast
class SomeClass
{
public:
virtual void widgetAction( QWidget *widget ) =0;
virtual void stringAction( const QString& str ) =0;
virtual void stringListAction( const QStringList& strList ) =0;
private:
QIcon *icon;
};
Iterators
Prefer const iterators and cache end()
Prefer to use const_iterators over normal iterators when possible. Containers, which are being implicitly shared often detach when a call to a non-const begin() or end() methods is made (QList is an example of such a container). When using a const_iterator also watch out that you are really calling the const version of begin() and end(). Unless your container is actually const itself this probably will not be the case, possibly causing an unnecessary detach of your container. So basically whenever you use const_iterator initialize them using constBegin()/constEnd() instead, to be on the safe side.
Cache the return of the end() (or constEnd()) method call before doing iteration over large containers. For example:
QList<SomeClass> container;
//code which inserts a large number of elements to the container
QList<SomeClass>::ConstIterator end = container.constEnd();
QList<SomeClass>::ConstIterator itr = container.constBegin();
for ( ; itr != end; ++itr ) {
// use *itr (or itr.value()) here
}
This avoids the unnecessary creation of the temporary end() (or constEnd()) return object on each loop iteration, largely speeding it up.
When using iterators, always use pre-increment and pre-decrement operators (i.e., ++itr) unless you have a specific reason not to. The use of post-increment and post-decrement operators (i.e., itr++) cause the creation of a temporary object.
Take care when erasing elements inside a loop
When you want to erase some elements from the list, you maybe would use code similar to this:
QMap<int, Job *>::iterator it = m_activeTimers.begin();
QMap<int, Job *>::iterator itEnd = m_activeTimers.end();
for( ; it != itEnd ; ++it) {
if(it.value() == job) {
//A timer for this job has been found. Let's stop it.
killTimer(it.key());
m_activeTimers.erase(it);
}
}
This code will potentially crash because it is a dangling iterator after the call to erase(). You have to rewrite the code this way:
QMap<int, Job *>::iterator it = m_activeTimers.begin();
while (it != m_activeTimers.end()) {
if(it.value() == job) {
//A timer for this job has been found. Let's stop it.
killTimer(it.key());
it = m_activeTimers.erase(it);
} else {
++it;
}
}
This problem is also discussed in the Qt documentation for QMap::iterator but applies to all Qt iterators
memory leaks
A very "popular" programming mistake is to do a new without a delete like in this program: mem_gourmet.cpp
class t
{
public:
t() {}
};
void pollute()
{
t* polluter = new t();
}
int main()
{
while (true) pollute();
}
You see, pollute() instantiates a new object polluter of the class t. Then, the variable polluter is lost because it is local, but the content (the object) stays on the heap. I could use this program to render my computer unusable within 10 seconds.
To solve this, there are the following approaches:
- keep the variable on the stack instead of the heap:
t* polluter = new t();
would become
t polluter;
- delete polluter using the complementing function to new:
delete polluter;
- stop the polluter in an [1] (which will automatically delete the polluter when returning from the method)
std::unique_ptr<t> polluter = new t();
There's also std::shared_ptr and QSharedPointer. This is the generally preferred way to do it in modern C++; explicit memory management should be avoided when possible.
Qt code involving QObject generally uses parent/child relations to free allocated memory; when constructing a QObject (e.g. a widget) it can be given a parent, and when the parent is deleted it deletes all its children. The parent is also set when you add a widget to a layout, for example.
A tool to detect memory leaks like this is Valgrind.
dynamic_cast
You can only dynamic_cast to type T from type T2 provided that:
- T is defined in a library you link to (you'd get a linker error if this isn't the case, since it won't find the vtable or RTTI info)
- T is "well-anchored" in that library. By "well-anchored" I mean that the vtable is not a COMMON symbol subject to merging at run-time by the dynamic linker. In other words, the first virtual member in the class definition must exist and not be inlined: it must be in a .cpp file.
- T and T2 are exported
For instance, we've seen some hard-to-track problems in non-KDE C++ code we're linking with (I think NMM) because of that. It happened that:
- libphonon loads the NMM plugin
- NMM plugin links to NMM
- NMM loads its own plugins
- NMM's own plugins link to NMM
Some classes in the NMM library did not have well-anchored vtables, so dynamic_casting failed inside the Phonon NMM plugin for objects created in the NMM's own plugins.
Program Design
In this section we will go over some common problems related to the design of Qt/KDE applications.
Delayed Initialization
Although the design of modern C++ applications can be very complex, application windows can be loaded and displayed to the user very quickly through the technique of delayed initialization. This technique is relatively straightforward and useful at all stages of an interactive program.
First, let us look at the standard way of initializing a KDE application:
int main( int argc, char **argv )
{
....
KApplication a;
KCmdLineArgs *args = KCmdLineArgs::parsedArgs();
MainWindow *window = new MainWindow( args );
a.setMainWidget( window );
window->show();
return a.exec();
}
Notice that window is created before the a.exec() call that starts the event loop. This implies that we want to avoid doing anything non-trivial in the top-level constructor, since it runs before we can even show the window.
The solution is simple: we need to delay the construction of anything besides the GUI until after the event loop has started. Here is how the example class MainWindow's constructor could look to achieve this:
MainWindow::MainWindow()
{
initGUI();
QTimer::singleShot( 0, this, SLOT(initObject()) );
}
void MainWindow::initGUI()
{
/* Construct your widgets here. Note that the widgets you
* construct here shouldn't require complex initialization
* either, or you've defeated the purpose.
* All you want to do is create your GUI objects and
* QObject::connect
* the appropriate signals to their slots.
*/
}
void MainWindow::initObject()
{
/* This slot will be called as soon as the event loop starts.
* Put everything else that needs to be done, including
* restoring values, reading files, session restoring, etc here.
* It will still take time, but at least your window will be
* on the screen, making your app look active.
*/
}
Using this technique may not buy you any overall time, but it makes your app seem quicker to the user who is starting it. This increased perceived responsiveness is reassuring for the user as they get quick feedback that the action of launching the app has succeeded.
When (and only when) the start up can not be made reasonably fast enough, consider using a KSplashScreen.
Data Structures
In this section we will go over some of our most common pet-peeves which affect data structures very commonly seen in Qt/KDE applications.
Passing non-POD types
Non-POD ("plain old data") types should be passed by const reference if at all possible. This includes anything other than the basic types such as char and int.
Take, for instance, QString. They should always be passed into methods as const QString&. Even though QString is implicitly shared it is still more efficient (and safer) to pass const references as opposed to objects by value.
So the canonical signature of a method taking QString arguments is:
void myMethod( const QString & foo, const QString & bar );
QObject
If you ever need to delete a QObject derived class from within one of its own methods, do not ever delete it this way:
delete this;
This will sooner or later cause a crash because a method on that object might be invoked from the Qt event loop via slots/signals after you deleted it.
Instead always use QObject::deleteLater() which tries to do the same thing as delete this but in a safer way.
Empty QStrings
It is common to want to see if a QString is empty. Here are three ways of doing it, the first two of which are correct:
// Correct
if ( mystring.isEmpty() ) {
}
// Correct
if ( mystring == QString() ) {
}
// Wrong! ""
if ( mystring == "" ) {
}
While there is a distinction between "null" QStrings and empty ones, this is a purely historical artifact and new code is discouraged from making use of it.
QString and reading files
If you are reading in a file, it is faster to convert it from the local encoding to Unicode (QString) in one go, rather than line by line. This means that methods like QIODevice::readAll() are often a good solution, followed by a single QString instantiation.
For larger files, consider reading a block of lines and then performing the conversion. That way you get the opportunity to update your GUI. This can be accomplished by reentering the event loop normally, along with using a timer to read in the blocks in the background, or by creating a local event loop.
While one can also use qApp->processEvents(), it is discouraged as it easily leads to subtle yet often fatal problems.
Reading QString from a KProcess
KProcess emits the signals readyReadStandard{Output|Error} as data comes in. A common mistake is reading all available data in the connected slot and converting it to QString right away: the data comes in arbitrarily segmented chunks, so multi-byte characters might be cut into pieces and thus invalidated. Several approaches to this problem exist:
- Do you really need to process the data as it comes in? If not, just use readAllStandard{Output|Error} after the process has exited. Unlike in KDE3, KProcess is now able to accumulate the data for you.
- Wrap the process into a QTextStream and read line-wise. This should work starting with Qt 4.4.
- Accumulate data chunks in the slots and process them each time a newline arrives or after some timeout passes. Example code
QString and QByteArray
While QString is the tool of choice for many string handling situations, there is one where it is particularly inefficient. If you are pushing about and working on data in QByteArrays, take care not to pass it through methods which take QString parameters; then make QByteArrays from them again.
For example:
QByteArray myData;
QString myNewData = mangleData( myData );
QString mangleData( const QString& data ) {
QByteArray str = data.toLatin1();
// mangle
return QString(str);
}
The expensive thing happening here is the conversion to QString, which does a conversion to Unicode internally. This is unnecessary because, the first thing the method does is convert it back using toLatin1(). So if you are sure that the Unicode conversion is not needed, try to avoid inadvertently using QString along the way.
The above example should instead be written as:
QByteArray myData;
QByteArray myNewData = mangleData( myData );
QByteArray mangleData( const QByteArray& data )
QDomElement
When parsing XML documents, one often needs to iterate over all the elements. You may be tempted to use the following code for that:
for ( QDomElement e = baseElement.firstChild().toElement();
!e.isNull();
e = e.nextSibling().toElement() ) {
...
}
That is not correct though: the above loop will stop prematurely when it encounters a QDomNode that is something other than an element such as a comment.
The correct loop looks like:
for ( QDomNode n = baseElement.firstChild(); !n.isNull();
n = n.nextSibling() ) {
QDomElement e = n.toElement();
if ( e.isNull() ) {
continue;
}
...
}