Multiple-item widgets inherit from Gtk::Container
; just
as with Gtk::Bin
, you use the add()
and remove()
methods to add and remove contained widgets.
Unlike Gtk::Bin::remove()
, however, the
remove()
method for Gtk::Container
takes an argument, specifiying which widget to remove.
You've probably noticed that gtkmm windows seem "elastic" - they can usually be stretched in many different ways. This is due to the widget packing system.
Many GUI toolkits require you to precisely place widgets in a window, using absolute positioning, often using a visual editor. This leads to several problems:
The widgets don't rearrange themselves when the window is resized. Some widgets are hidden when the window is made smaller, and lots of useless space appears when the window is made larger.
It's impossible to predict the amount of space necessary for text after it has been translated to other languages, or displayed in a different font. On Unix it is also impossible to anticipate the effects of every theme and window manager.
Changing the layout of a window "on the fly", to make some extra widgets appear, for instance, is complex. It requires tedious recalculation of every widget's position.
gtkmm uses the packing system to solve these problems. Rather than specifying the position and size of each widget in the window, you can arrange your widgets in rows, columns, and/or grids. gtkmm can size your window automatically, based on the sizes of the widgets it contains. And the sizes of the widgets are, in turn, determined by the amount of text they contain, or the minimum and maximum sizes that you specify, and/or how you have requested that the available space should be shared between sets of widgets. You can perfect your layout by specifying padding distance and centering values for each of your widgets. gtkmm then uses all this information to resize and reposition everything sensibly and smoothly when the user manipulates the window.
gtkmm arranges widgets hierarchically, using containers.
A Container widget contains other widgets. Most gtkmm widgets are
containers. Windows, Notebook tabs, and Buttons are all container widgets.
There are two flavours of containers: single-child containers, which are all
descendants of Gtk::Bin
, and multiple-child containers,
which are descendants of Gtk::Container
. Most widgets
in gtkmm are descendants of Gtk::Bin
, including
Gtk::Window
.
Yes, that's correct: a Window can contain at most one widget. How, then, can
we use a window for anything useful? By placing a multiple-child container in
the window. The most useful container widgets are
Gtk::Grid
and Gtk::Box
.
Gtk::Grid
arranges its child widgets in rows and
columns. Use attach()
,
attach_next_to()
and add()
to
insert child widgets.
Gtk::Box
arranges its child widgets vertically or horizontally. Use
pack_start()
and pack_end()
to insert
child widgets.
There are several other containers, which we will also discuss.
If you've never used a packing toolkit before, it can take some getting used to. You'll probably find, however, that you don't need to rely on visual form editors quite as much as you might with other toolkits.
Let's take a look at a slightly improved helloworld
, showing what we've learnt.
File: helloworld.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLE_HELLOWORLD_H #define GTKMM_EXAMPLE_HELLOWORLD_H #include <gtkmm/box.h> #include <gtkmm/button.h> #include <gtkmm/window.h> class HelloWorld : public Gtk::Window { public: HelloWorld(); virtual ~HelloWorld(); protected: // Signal handlers: // Our new improved on_button_clicked(). (see below) void on_button_clicked(Glib::ustring data); // Child widgets: Gtk::Box m_box1; Gtk::Button m_button1, m_button2; }; #endif // GTKMM_EXAMPLE_HELLOWORLD_H
File: helloworld.cc
(For use with gtkmm 3, not gtkmm 2)
#include "helloworld.h" #include <iostream> HelloWorld::HelloWorld() : m_button1("Button 1"), m_button2("Button 2") { // This just sets the title of our new window. set_title("Hello Buttons!"); // sets the border width of the window. set_border_width(10); // put the box into the main window. add(m_box1); // Now when the button is clicked, we call the "on_button_clicked" function // with a pointer to "button 1" as it's argument m_button1.signal_clicked().connect(sigc::bind<Glib::ustring>( sigc::mem_fun(*this, &HelloWorld::on_button_clicked), "button 1")); // instead of gtk_container_add, we pack this button into the invisible // box, which has been packed into the window. // note that the pack_start default arguments are Gtk::EXPAND | Gtk::FILL, 0 m_box1.pack_start(m_button1); // always remember this step, this tells GTK that our preparation // for this button is complete, and it can be displayed now. m_button1.show(); // call the same signal handler with a different argument, // passing a pointer to "button 2" instead. m_button2.signal_clicked().connect(sigc::bind<-1, Glib::ustring>( sigc::mem_fun(*this, &HelloWorld::on_button_clicked), "button 2")); m_box1.pack_start(m_button2); // Show the widgets. // They will not really be shown until this Window is shown. m_button2.show(); m_box1.show(); } HelloWorld::~HelloWorld() { } // Our new improved signal handler. The data passed to this method is // printed to stdout. void HelloWorld::on_button_clicked(Glib::ustring data) { std::cout << "Hello World - " << data << " was pressed" << std::endl; }
File: main.cc
(For use with gtkmm 3, not gtkmm 2)
#include "helloworld.h" #include <gtkmm/application.h> int main (int argc, char *argv[]) { auto app = Gtk::Application::create(argc, argv, "org.gtkmm.example"); HelloWorld helloworld; //Shows the window and returns when it is closed. return app->run(helloworld); }
After building and running this program, try resizing the window to see the
behaviour. Also, try playing with the options to
pack_start()
while reading the Boxes section.
Most packing uses boxes as in the above example. These
are invisible containers into which we can pack our widgets. When
packing widgets into a horizontal box, the objects are inserted
horizontally from left to right or right to left depending on whether
pack_start()
or pack_end()
is used.
In a vertical box, widgets are packed from top to bottom or vice
versa. You may use any combination of boxes inside or beside other
boxes to create the desired effect.
The pack_start()
and
pack_end()
methods place widgets inside these
containers. The pack_start()
method will start at
the top and work its way down in a Box
with vertical
orientation, or pack left to right in a Box
with horizontal
orientation. pack_end()
will do the opposite, packing from
bottom to top or from right to left. Using these methods allows us to right justify or
left justify our widgets. We will use pack_start()
in most of our examples.
There are several options governing how widgets are to be packed, and this can be confusing at first. If you have difficulties then it is sometimes a good idea to play with the glade GUI designer to see what is possible. You might even decide to use the Gtk::Builder API to load your GUI at runtime.
There are basically five different styles, as shown in this picture:
Each line contains one horizontal Box
with
several buttons. Each of the buttons on a line is packed into the
Box
with the same arguments to the
pack_start()
method.
This is the declaration of the pack_start()
method:
void pack_start(Gtk::Widget& child, Gtk::PackOptions options = Gtk::PACK_EXPAND_WIDGET, guint padding = 0);
The first argument is the widget you're packing. In our example these are all Button
s.
The options
argument can take one of these three options:
Gtk::PACK_SHRINK
: Space is contracted to the child widget size. The widget will take up just-enough space and never expand.
Gtk::PACK_EXPAND_PADDING
: Extra space is filled with padding. The widgets will be spaced out evenly, but their sizes won't change - there will be empty space between the widgets instead.
Gtk::PACK_EXPAND_WIDGET
: Extra space is taken up by increasing the child widget size, without changing the amount of space between widgets.
The padding
argument specifies the width of an extra
border area to leave around the packed widget.
Here's the constructor for the Box
widget,
and methods that set per-container packing options:
Gtk::Box(Gtk::Orientation orientation = Gtk::ORIENTATION_HORIZONTAL, int spacing = 0); void set_spacing(int spacing); void set_homogeneous(bool homogeneous = true);
Passing true
to set_homogeneous()
will
cause all of the contained widgets to be the same size.
spacing
is a (minimum) number of pixels to leave between
each widget.
What's the difference between spacing (set when the box is created) and padding (set when elements are packed)? Spacing is added between objects, and padding is added on either side of a widget. The following figure should make it clearer:
The following example program requires a command-line option.
The source code shows two ways of handling command-line options in combination
with Gtk::Application
.
Handle the options in main()
and hide them from
Gtk::Application
by setting argc = 1
in the call to Gtk::Application::create()
.
Give all command-line options to Gtk::Application::create()
and add the flag Gio::APPLICATION_HANDLES_COMMAND_LINE
.
Connect a signal handler to the command_line
signal, and
handle the command-line options in the signal handler.
You must set the optional parameter after = false
in
the call to signal_command_line().connect()
, because your signal
handler must be called before the default signal handler. You must also call
Gio::Application::activate()
in the signal handler,
unless you want your application to exit without showing its main window.
(Gio::Application
is a base class of
Gtk::Application
.)
Here is the source code for the example that produced the screenshots above. When you run this example, provide a number between 1 and 3 as a command-line option, to see different packing options in use.
File: examplewindow.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLEWINDOW_H #define GTKMM_EXAMPLEWINDOW_H #include <gtkmm.h> class ExampleWindow : public Gtk::Window { public: ExampleWindow(int which); virtual ~ExampleWindow(); protected: //Signal handlers: void on_button_quit_clicked(); //Child widgets: Gtk::Button m_button; Gtk::Box m_box1; Gtk::Box m_boxQuit; Gtk::Button m_buttonQuit; Gtk::Label m_Label1, m_Label2; Gtk::Separator m_separator1, m_separator2; }; #endif //GTKMM_EXAMPLEWINDOW_H
File: packbox.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLE_PACKBOX_H #define GTKMM_EXAMPLE_PACKBOX_H #include <gtkmm.h> class PackBox : public Gtk::Box { public: PackBox(bool homogeneous, int spacing, Gtk::PackOptions options, int padding = 0); virtual ~PackBox(); protected: Gtk::Button m_button1, m_button2, m_button3; Gtk::Button* m_pbutton4; }; #endif //GTKMM_EXAMPLE_PACKBOX_H
File: main.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include <gtkmm/application.h> #include <iostream> #include <cstdlib> #define GTK_APPLICATION_RECEIVES_COMMAND_LINE_ARGUMENTS 0 #if GTK_APPLICATION_RECEIVES_COMMAND_LINE_ARGUMENTS namespace { int on_command_line(const Glib::RefPtr<Gio::ApplicationCommandLine>& command_line, Glib::RefPtr<Gtk::Application>& app) { int argc = 0; char** argv = command_line->get_arguments(argc); for (int i = 0; i < argc; ++i) std::cout << "argv[" << i << "] = " << argv[i] << std::endl; app->activate(); // Without activate() the window won't be shown. return EXIT_SUCCESS; } } // anonymous namespace #endif int main(int argc, char *argv[]) { if (argc != 2) { std::cerr << "Usage: example <num>, where <num> is 1, 2, or 3." << std::endl; return EXIT_FAILURE; } #if GTK_APPLICATION_RECEIVES_COMMAND_LINE_ARGUMENTS // The command line arguments must be checked before Gtk::Application::run() // is called. The Gio::APPLICATION_HANDLES_COMMAND_LINE flag and the // on_command_line() signal handler are not necessary. This program is simpler // without them, and with argc = 1 in the call to Gtk::Application::create(). // They are included to show a program with Gio::APPLICATION_HANDLES_COMMAND_LINE. // Gio::APPLICATION_NON_UNIQUE makes it possible to run several instances of // this application simultaneously. auto app = Gtk::Application::create(argc, argv, "org.gtkmm.example", Gio::APPLICATION_HANDLES_COMMAND_LINE | Gio::APPLICATION_NON_UNIQUE); // Note after = false. // Only one signal handler is invoked. This signal handler must run before // the default signal handler, or else it won't run at all. app->signal_command_line().connect(sigc::bind(sigc::ptr_fun(&on_command_line), app), false); #else // Gio::APPLICATION_NON_UNIQUE makes it possible to run several instances of // this application simultaneously. int argc1 = 1; // Don't give the command line arguments to Gtk::Application. auto app = Gtk::Application::create(argc1, argv, "org.gtkmm.example", Gio::APPLICATION_NON_UNIQUE); #endif ExampleWindow window(std::atoi(argv[1])); return app->run(window); //Shows the window and returns when it is closed. }
File: packbox.cc
(For use with gtkmm 3, not gtkmm 2)
#include "packbox.h" PackBox::PackBox(bool homogeneous, int spacing, Gtk::PackOptions options, int padding) : Gtk::Box(Gtk::ORIENTATION_HORIZONTAL, spacing), m_button1("box.pack_start("), m_button2("button,"), m_button3((options == Gtk::PACK_SHRINK) ? "Gtk::PACK_SHRINK" : ((options == Gtk::PACK_EXPAND_PADDING) ? "Gtk::PACK_EXPAND_PADDING" : "Gtk::PACK_EXPAND_WIDGET")) { set_homogeneous(homogeneous); pack_start(m_button1, options, padding); pack_start(m_button2, options, padding); pack_start(m_button3, options, padding); m_pbutton4 = new Gtk::Button(Glib::ustring::format(padding) + ");"); pack_start(*m_pbutton4, options, padding); } PackBox::~PackBox() { delete m_pbutton4; }
File: examplewindow.cc
(For use with gtkmm 3, not gtkmm 2)
#include <iostream> #include "examplewindow.h" #include "packbox.h" ExampleWindow::ExampleWindow(int which) : m_box1(Gtk::ORIENTATION_VERTICAL), m_buttonQuit("Quit") { set_title("Gtk::Box example"); PackBox *pPackBox1, *pPackBox2, *pPackBox3, *pPackBox4, *pPackBox5; switch(which) { case 1: { m_Label1.set_text("Gtk::Box(Gtk::ORIENTATION_HORIZONTAL); set_homogeneous(false);"); // Align the label to the left side. m_Label1.set_halign(Gtk::ALIGN_START); m_Label1.set_valign(Gtk::ALIGN_START); // Pack the label into the vertical box (vbox box1). Remember that // widgets added to a vbox will be packed one on top of the other in // order. m_box1.pack_start(m_Label1, Gtk::PACK_SHRINK); // Create a PackBox - homogeneous = false, spacing = 0, // options = Gtk::PACK_SHRINK, padding = 0 pPackBox1 = Gtk::make_managed<PackBox>(false, 0, Gtk::PACK_SHRINK); m_box1.pack_start(*pPackBox1, Gtk::PACK_SHRINK); // Create a PackBox - homogeneous = false, spacing = 0, // options = Gtk::PACK_EXPAND_PADDING, padding = 0 pPackBox2 = Gtk::make_managed<PackBox>(false, 0, Gtk::PACK_EXPAND_PADDING); m_box1.pack_start(*pPackBox2, Gtk::PACK_SHRINK); // Create a PackBox - homogeneous = false, spacing = 0, // options = Gtk::PACK_EXPAND_WIDGET, padding = 0 pPackBox3 = Gtk::make_managed<PackBox>(false, 0, Gtk::PACK_EXPAND_WIDGET); m_box1.pack_start(*pPackBox3, Gtk::PACK_SHRINK); // pack the separator into the vbox. Remember each of these // widgets are being packed into a vbox, so they'll be stacked // vertically. m_box1.pack_start(m_separator1, Gtk::PACK_SHRINK, 5); // create another new label, and show it. m_Label2.set_text("Gtk::Box(Gtk::ORIENTATION_HORIZONTAL); set_homogeneous(true);"); m_Label2.set_halign(Gtk::ALIGN_START); m_Label2.set_valign(Gtk::ALIGN_START); m_box1.pack_start(m_Label2, Gtk::PACK_SHRINK); // Args are: homogeneous, spacing, options, padding pPackBox4 = Gtk::make_managed<PackBox>(true, 0, Gtk::PACK_EXPAND_PADDING); m_box1.pack_start(*pPackBox4, Gtk::PACK_SHRINK); // Args are: homogeneous, spacing, options, padding pPackBox5 = Gtk::make_managed<PackBox>(true, 0, Gtk::PACK_EXPAND_WIDGET); m_box1.pack_start(*pPackBox5, Gtk::PACK_SHRINK); m_box1.pack_start(m_separator2, Gtk::PACK_SHRINK, 5); break; } case 2: { m_Label1.set_text("Gtk::Box(Gtk::ORIENTATION_HORIZONTAL, 10); set_homogeneous(false);"); m_Label1.set_halign(Gtk::ALIGN_START); m_Label1.set_valign(Gtk::ALIGN_START); m_box1.pack_start(m_Label1, Gtk::PACK_SHRINK); pPackBox1 = Gtk::make_managed<PackBox>(false, 10, Gtk::PACK_EXPAND_PADDING); m_box1.pack_start(*pPackBox1, Gtk::PACK_SHRINK); pPackBox2 = Gtk::make_managed<PackBox>(false, 10, Gtk::PACK_EXPAND_WIDGET); m_box1.pack_start(*pPackBox2, Gtk::PACK_SHRINK); m_box1.pack_start(m_separator1, Gtk::PACK_SHRINK, 5); m_Label2.set_text("Gtk::Box(Gtk::ORIENTATION_HORIZONTAL); set_homogeneous(false);"); m_Label2.set_halign(Gtk::ALIGN_START); m_Label2.set_valign(Gtk::ALIGN_START); m_box1.pack_start(m_Label2, Gtk::PACK_SHRINK); pPackBox3 = Gtk::make_managed<PackBox>(false, 0, Gtk::PACK_SHRINK, 10); m_box1.pack_start(*pPackBox3, Gtk::PACK_SHRINK); pPackBox4 = Gtk::make_managed<PackBox>(false, 0, Gtk::PACK_EXPAND_WIDGET, 10); m_box1.pack_start(*pPackBox4, Gtk::PACK_SHRINK); m_box1.pack_start(m_separator2, Gtk::PACK_SHRINK, 5); break; } case 3: { // This demonstrates the ability to use Gtk::Box::pack_end() to // right justify widgets. First, we create a new box as before. pPackBox1 = Gtk::make_managed<PackBox>(false, 0, Gtk::PACK_SHRINK); // create the label that will be put at the end. m_Label1.set_text("end"); // pack it using pack_end(), so it is put on the right side // of the PackBox. pPackBox1->pack_end(m_Label1, Gtk::PACK_SHRINK); m_box1.pack_start(*pPackBox1, Gtk::PACK_SHRINK); // this explicitly sets the separator to 500 pixels wide by 5 pixels // high. This is so the hbox we created will also be 500 pixels wide, // and the "end" label will be separated from the other labels in the // hbox. Otherwise, all the widgets in the hbox would be packed as // close together as possible. m_separator1.set_size_request(500, 5); // pack the separator into the vbox. m_box1.pack_start(m_separator1, Gtk::PACK_SHRINK, 5); break; } default: { std::cerr << "Unexpected command-line option." << std::endl; break; } } // Connect the signal to hide the window: m_buttonQuit.signal_clicked().connect( sigc::mem_fun(*this, &ExampleWindow::on_button_quit_clicked) ); // pack the button into the quitbox. // The last 2 arguments to Box::pack_start are: options, padding. m_boxQuit.pack_start(m_buttonQuit, Gtk::PACK_EXPAND_PADDING); m_box1.pack_start(m_boxQuit, Gtk::PACK_SHRINK); // pack the vbox (box1) which now contains all our widgets, into the // main window. add(m_box1); show_all_children(); } ExampleWindow::~ExampleWindow() { } void ExampleWindow::on_button_quit_clicked() { hide(); }
Button boxes are a convenient way to quickly arrange a group of buttons. Their orientation can be either horizontal or vertical.
ButtonBox
es help to make applications appear consistent
because they use standard settings, such as inter-button spacing and packing.
Buttons are added to a ButtonBox
with the
add()
method.
Button boxes support several layout styles. The style can be retrieved and
changed using get_layout()
and
set_layout()
.
File: examplewindow.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLEWINDOW_H #define GTKMM_EXAMPLEWINDOW_H #include <gtkmm.h> class ExampleWindow : public Gtk::Window { public: ExampleWindow(); virtual ~ExampleWindow(); protected: //Signal handlers: void on_button_clicked(); //Child widgets: Gtk::Box m_VBox_Main, m_VBox; Gtk::Box m_HBox; Gtk::Frame m_Frame_Horizontal, m_Frame_Vertical; }; #endif //GTKMM_EXAMPLEWINDOW_H
File: examplebuttonbox.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLE_BUTTONBOX_H #define GTKMM_EXAMPLE_BUTTONBOX_H #include <gtkmm.h> class ExampleButtonBox : public Gtk::Frame { public: ExampleButtonBox(bool horizontal, const Glib::ustring& title, gint spacing, Gtk::ButtonBoxStyle layout); protected: Gtk::Button m_Button_OK, m_Button_Cancel, m_Button_Help; }; #endif //GTKMM_EXAMPLE_BUTTONBOX_H
File: examplebuttonbox.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplebuttonbox.h" ExampleButtonBox::ExampleButtonBox(bool horizontal, const Glib::ustring& title, gint spacing, Gtk::ButtonBoxStyle layout) : Gtk::Frame(title), m_Button_OK("OK"), m_Button_Cancel("Cancel"), m_Button_Help("Help") { Gtk::ButtonBox* bbox = nullptr; if(horizontal) bbox = Gtk::make_managed<Gtk::ButtonBox>(Gtk::ORIENTATION_HORIZONTAL); else bbox = Gtk::make_managed<Gtk::ButtonBox>(Gtk::ORIENTATION_VERTICAL); bbox->set_border_width(5); add(*bbox); /* Set the appearance of the Button Box */ bbox->set_layout(layout); bbox->set_spacing(spacing); bbox->add(m_Button_OK); bbox->add(m_Button_Cancel); bbox->add(m_Button_Help); }
File: main.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include <gtkmm/application.h> int main(int argc, char *argv[]) { auto app = Gtk::Application::create(argc, argv, "org.gtkmm.example"); ExampleWindow window; //Shows the window and returns when it is closed. return app->run(window); }
File: examplewindow.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include "examplebuttonbox.h" ExampleWindow::ExampleWindow() : m_VBox_Main(Gtk::ORIENTATION_VERTICAL), m_VBox(Gtk::ORIENTATION_VERTICAL), m_Frame_Horizontal("Horizontal Button Boxes"), m_Frame_Vertical("Vertical Button Boxes") { set_title("Gtk::ButtonBox"); add(m_VBox_Main); m_VBox_Main.pack_start(m_Frame_Horizontal, Gtk::PACK_EXPAND_WIDGET, 10); //The horizontal ButtonBoxes: m_VBox.set_border_width(10); m_Frame_Horizontal.add(m_VBox); m_VBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (true, "Spread (spacing 40)", 40, Gtk::BUTTONBOX_SPREAD), Gtk::PACK_EXPAND_WIDGET); m_VBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (true, "Edge (spacing 30)", 30, Gtk::BUTTONBOX_EDGE), Gtk::PACK_EXPAND_WIDGET, 5); m_VBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (true, "Start (spacing 20)", 20, Gtk::BUTTONBOX_START), Gtk::PACK_EXPAND_WIDGET, 5); m_VBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (true, "End (spacing 10)", 10, Gtk::BUTTONBOX_END), Gtk::PACK_EXPAND_WIDGET, 5); //The vertical ButtonBoxes: m_VBox_Main.pack_start(m_Frame_Vertical, Gtk::PACK_EXPAND_WIDGET, 10); m_HBox.set_border_width(10); m_Frame_Vertical.add(m_HBox); m_HBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (false, "Spread (spacing 5)", 5, Gtk::BUTTONBOX_SPREAD), Gtk::PACK_EXPAND_WIDGET); m_HBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (false, "Edge (spacing 30)", 30, Gtk::BUTTONBOX_EDGE), Gtk::PACK_EXPAND_WIDGET, 5); m_HBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (false, "Start (spacing 20)", 20, Gtk::BUTTONBOX_START), Gtk::PACK_EXPAND_WIDGET, 5); m_HBox.pack_start(*Gtk::make_managed<ExampleButtonBox> (false, "End (spacing 10)", 10, Gtk::BUTTONBOX_END), Gtk::PACK_EXPAND_WIDGET, 5); show_all_children(); } ExampleWindow::~ExampleWindow() { } void ExampleWindow::on_button_clicked() { hide(); }
A Grid
dynamically lays out child widgets in rows and
columns. The dimensions of the grid do not need to be specified in the constructor.
Child widgets can span multiple rows or columns, using
attach()
, or added next to an existing widget inside
the grid with attach_next_to()
. Individual rows and columns of the grid can be set to have uniform height or width with
set_row_homogeneous()
and
set_column_homogeneous()
.
You can set the margin and expand properties of the
child Widget
s to control their spacing and their behaviour when the Grid is resized.
This example creates a window with three buttons in a grid. The first two buttons are in the upper row, from left to right. A third button is attached underneath the first button, in a new lower row, spanning two columns.
File: examplewindow.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLEWINDOW_H #define GTKMM_EXAMPLEWINDOW_H #include <gtkmm.h> class ExampleWindow : public Gtk::Window { public: ExampleWindow(); virtual ~ExampleWindow(); private: // Signal handlers: void on_button_quit(); void on_button_numbered(const Glib::ustring& data); // Child widgets: Gtk::Grid m_grid; Gtk::Button m_button_1, m_button_2, m_button_quit; }; #endif /* GTKMM_EXAMPLEWINDOW_H */
File: main.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include <gtkmm/application.h> int main(int argc, char *argv[]) { auto app = Gtk::Application::create(argc, argv, "org.gtkmm.example"); ExampleWindow window; // Shows the window and returns when it is closed. return app->run(window); }
File: examplewindow.cc
(For use with gtkmm 3, not gtkmm 2)
#include <iostream> #include "examplewindow.h" ExampleWindow::ExampleWindow() : m_button_1("button 1"), m_button_2("button 2"), m_button_quit("Quit") { set_title("Gtk::Grid"); set_border_width(12); add(m_grid); m_grid.add(m_button_1); m_grid.add(m_button_2); m_grid.attach_next_to(m_button_quit, m_button_1, Gtk::POS_BOTTOM, 2, 1); m_button_1.signal_clicked().connect( sigc::bind<Glib::ustring>( sigc::mem_fun(*this, &ExampleWindow::on_button_numbered), "button 1") ); m_button_2.signal_clicked().connect( sigc::bind<Glib::ustring>( sigc::mem_fun(*this, &ExampleWindow::on_button_numbered), "button 2") ); m_button_quit.signal_clicked().connect(sigc::mem_fun(*this, &ExampleWindow::on_button_quit) ); show_all_children(); } ExampleWindow::~ExampleWindow() { } void ExampleWindow::on_button_quit() { hide(); } void ExampleWindow::on_button_numbered(const Glib::ustring& data) { std::cout << data << " was pressed" << std::endl; }
Gtk::Table
allows us to place widgets in a grid,
similar to Gtk::Grid
.
Gtk::Table
is deprecated from gtkmm version 3.4 and should
not be used in newly-written code. Use Gtk::Grid
instead.
A Notebook
has a set of stacked
pages
, each of which contains widgets. Labelled
tabs
allow the user to select the pages.
Notebook
s allow several sets of widgets to be placed in a
small space, by only showing one page at a time. For instance, they are often
used in preferences dialogs.
Use the append_page()
, prepend_page()
and insert_page()
methods to add tabbed pages to the
Notebook
, supplying the child widget and the name for the
tab.
To discover the currently visible page, use the
get_current_page()
method. This returns the page number,
and then calling get_nth_page()
with that number will give
you a pointer to the actual child widget.
To programmatically change the selected page, use the
set_current_page()
method.
File: examplewindow.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLEWINDOW_H #define GTKMM_EXAMPLEWINDOW_H #include <gtkmm.h> class ExampleWindow : public Gtk::Window { public: ExampleWindow(); virtual ~ExampleWindow(); protected: //Signal handlers: void on_button_quit(); void on_notebook_switch_page(Gtk::Widget* page, guint page_num); //Child widgets: Gtk::Box m_VBox; Gtk::Notebook m_Notebook; Gtk::Label m_Label1, m_Label2; Gtk::ButtonBox m_ButtonBox; Gtk::Button m_Button_Quit; }; #endif //GTKMM_EXAMPLEWINDOW_H
File: main.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include <gtkmm/application.h> int main(int argc, char *argv[]) { auto app = Gtk::Application::create(argc, argv, "org.gtkmm.example"); ExampleWindow window; //Shows the window and returns when it is closed. return app->run(window); }
File: examplewindow.cc
(For use with gtkmm 3, not gtkmm 2)
#include <iostream> #include "examplewindow.h" ExampleWindow::ExampleWindow() : m_VBox(Gtk::ORIENTATION_VERTICAL), m_Label1("Contents of tab 1"), m_Label2("Contents of tab 2"), m_Button_Quit("Quit") { set_title("Gtk::Notebook example"); set_border_width(10); set_default_size(400, 200); add(m_VBox); //Add the Notebook, with the button underneath: m_Notebook.set_border_width(10); m_VBox.pack_start(m_Notebook); m_VBox.pack_start(m_ButtonBox, Gtk::PACK_SHRINK); m_ButtonBox.pack_start(m_Button_Quit, Gtk::PACK_SHRINK); m_Button_Quit.signal_clicked().connect(sigc::mem_fun(*this, &ExampleWindow::on_button_quit) ); //Add the Notebook pages: m_Notebook.append_page(m_Label1, "First"); m_Notebook.append_page(m_Label2, "Second"); m_Notebook.signal_switch_page().connect(sigc::mem_fun(*this, &ExampleWindow::on_notebook_switch_page) ); show_all_children(); } ExampleWindow::~ExampleWindow() { } void ExampleWindow::on_button_quit() { hide(); } void ExampleWindow::on_notebook_switch_page(Gtk::Widget* /* page */, guint page_num) { std::cout << "Switched to tab with index " << page_num << std::endl; //You can also use m_Notebook.get_current_page() to get this index. }
An Assistant
splits a complex operation into steps. Each step is a page, containing a header, a child widget and an action area. The Assistant's action area has navigation buttons which update automatically depending on the type of the page, set with set_page_type()
.
Use the append_page()
, prepend_page
and insert_page()
methods to add pages to the Assistant
, supplying the child widget for each page.
To determine the currently-visible page, use the get_current_page()
method, and pass the result to get_nth_page()
, which returns a pointer to the actual widget. To programmatically change the current page, use the set_current_page()
method.
To set the title of a page, use the set_page_title()
method. The header and side images of a page can be set with the set_page_header_image()
and set_page_side_image()
methods.
To add widgets to the action area, use the add_action_widget()
method. They will be packed alongside the default buttons. Use the remove_action_widget()
method to remove widgets.
File: examplewindow.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLEWINDOW_H #define GTKMM_EXAMPLEWINDOW_H #include "exampleassistant.h" #include <gtkmm.h> class ExampleWindow : public Gtk::Window { public: ExampleWindow(); virtual ~ExampleWindow(); private: // Signal handlers: void on_button_clicked(); void on_assistant_apply(); // Child widgets: Gtk::Grid m_grid; Gtk::Button m_button; Gtk::Label m_label1, m_label2; Gtk::CheckButton m_check; Gtk::Entry m_entry; ExampleAssistant m_assistant; }; #endif /* GTKMM_EXAMPLEWINDOW_H */
File: exampleassistant.h
(For use with gtkmm 3, not gtkmm 2)
#ifndef GTKMM_EXAMPLEASSISTANT_H #define GTKMM_EXAMPLEASSISTANT_H #include <gtkmm.h> class ExampleAssistant : public Gtk::Assistant { public: ExampleAssistant(); virtual ~ExampleAssistant(); void get_result(bool& check_state, Glib::ustring& entry_text); private: // Signal handlers: void on_assistant_apply(); void on_assistant_cancel(); void on_assistant_close(); void on_assistant_prepare(Gtk::Widget* widget); void on_entry_changed(); // Member functions: void print_status(); // Child widgets: Gtk::Box m_box; Gtk::Label m_label1, m_label2; Gtk::CheckButton m_check; Gtk::Entry m_entry; }; #endif /* GTKMM_EXAMPLEASSISTANT_H */
File: main.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include <gtkmm/application.h> int main(int argc, char *argv[]) { auto app = Gtk::Application::create(argc, argv, "org.gtkmm.example"); ExampleWindow window; // Shows the window and returns when it is closed. return app->run(window); }
File: exampleassistant.cc
(For use with gtkmm 3, not gtkmm 2)
#include <iostream> #include "exampleassistant.h" ExampleAssistant::ExampleAssistant() : m_box(Gtk::ORIENTATION_HORIZONTAL, 12), m_label1("Type text to allow the assistant to continue:"), m_label2("Confirmation page"), m_check("Optional extra information") { set_title("Gtk::Assistant example"); set_border_width(12); set_default_size(400, 300); m_box.pack_start(m_label1); m_box.pack_start(m_entry); append_page(m_box); append_page(m_check); append_page(m_label2); set_page_title(*get_nth_page(0), "Page 1"); set_page_title(*get_nth_page(1), "Page 2"); set_page_title(*get_nth_page(2), "Confirmation"); set_page_complete(m_check, true); set_page_complete(m_label2, true); set_page_type(m_box, Gtk::ASSISTANT_PAGE_INTRO); set_page_type(m_label2, Gtk::ASSISTANT_PAGE_CONFIRM); signal_apply().connect(sigc::mem_fun(*this, &ExampleAssistant::on_assistant_apply)); signal_cancel().connect(sigc::mem_fun(*this, &ExampleAssistant::on_assistant_cancel)); signal_close().connect(sigc::mem_fun(*this, &ExampleAssistant::on_assistant_close)); signal_prepare().connect(sigc::mem_fun(*this, &ExampleAssistant::on_assistant_prepare)); m_entry.signal_changed().connect(sigc::mem_fun(*this, &ExampleAssistant::on_entry_changed)); show_all_children(); } ExampleAssistant::~ExampleAssistant() { } void ExampleAssistant::get_result(bool& check_state, Glib::ustring& entry_text) { check_state = m_check.get_active(); entry_text = m_entry.get_text(); } void ExampleAssistant::on_assistant_apply() { std::cout << "Apply was clicked"; print_status(); } void ExampleAssistant::on_assistant_cancel() { std::cout << "Cancel was clicked"; print_status(); hide(); } void ExampleAssistant::on_assistant_close() { std::cout << "Assistant was closed"; print_status(); hide(); } void ExampleAssistant::on_assistant_prepare(Gtk::Widget* /* widget */) { set_title(Glib::ustring::compose("Gtk::Assistant example (Page %1 of %2)", get_current_page() + 1, get_n_pages())); } void ExampleAssistant::on_entry_changed() { // The page is only complete if the entry contains text. if(m_entry.get_text_length()) set_page_complete(m_box, true); else set_page_complete(m_box, false); } void ExampleAssistant::print_status() { std::cout << ", entry contents: \"" << m_entry.get_text() << "\", checkbutton status: " << m_check.get_active() << std::endl; }
File: examplewindow.cc
(For use with gtkmm 3, not gtkmm 2)
#include "examplewindow.h" #include "exampleassistant.h" ExampleWindow::ExampleWindow() : m_button("Show the assistant"), m_label1("State of assistant checkbutton:", Gtk::ALIGN_START, Gtk::ALIGN_CENTER), m_label2("Contents of assistant entry:", Gtk::ALIGN_START, Gtk::ALIGN_CENTER) { set_title("Gtk::Assistant example"); set_border_width(12); m_grid.set_row_homogeneous(true); m_grid.attach(m_button, 0, 0, 2, 1); m_button.set_hexpand(true); m_button.set_valign(Gtk::ALIGN_CENTER); m_grid.attach(m_label1, 0, 1, 1, 1); m_grid.attach(m_label2, 0, 2, 1, 1); m_grid.attach(m_check, 1, 1, 1, 1); m_check.set_halign(Gtk::ALIGN_START); m_grid.attach(m_entry, 1, 2, 1, 1); m_entry.set_hexpand(true); add(m_grid); m_button.signal_clicked().connect(sigc::mem_fun(*this, &ExampleWindow::on_button_clicked)); m_assistant.signal_apply().connect(sigc::mem_fun(*this, &ExampleWindow::on_assistant_apply)); m_check.set_sensitive(false); m_entry.set_sensitive(false); show_all_children(); } ExampleWindow::~ExampleWindow() { } void ExampleWindow::on_assistant_apply() { bool check_state; Glib::ustring entry_text; m_assistant.get_result(check_state, entry_text); m_check.set_active(check_state); m_entry.set_text(entry_text); } void ExampleWindow::on_button_clicked() { m_assistant.show(); }