It is created by gio.application.Application and emitted
in the signal@Gio.Application::command-line signal and virtual function.
The class contains the list of arguments that the program was invoked
with. It is also possible to query if the commandline invocation was
local (ie: the current process is running in direct response to the
invocation) or remote (ie: some other process forwarded the
commandline to this process).
The main use for gio.application_command_line.ApplicationCommandLine (and the
signal@Gio.Application::command-line signal) is 'Emacs server' like use cases:
You can set the EDITOR environment variable to have e.g. git use
your favourite editor to edit commit messages, and if you already
have an instance of the editor running, the editing will happen
in the running instance, instead of opening a new one. An important
aspect of this use case is that the process that gets started by git
does not return until the editing is done.
Normally, the commandline is completely handled in the
signal@Gio.Application::command-line handler. The launching instance exits
once the signal handler in the primary instance has returned, and
the return value of the signal handler becomes the exit status
of the launching instance.
staticint
command_line (GApplication *application,
GApplicationCommandLine *cmdline)
{
gchar **argv;
gint argc;
gint i;
argv = g_application_command_line_get_arguments (cmdline, &argc);
g_application_command_line_print (cmdline,
"This text is written back\n""to stdout of the caller\n");
for (i = 0; i < argc; i++)
g_print ("argument %d: %s\n", i, argv[i]);
g_strfreev (argv);
return0;
}
In this example of split commandline handling, options that start
with --local- are handled locally, all other options are passed
to the signal@Gio.Application::command-line handler which runs in the primary
instance.
If handling the commandline requires a lot of work, it may be better to defer it.
static gboolean
my_cmdline_handler (gpointer data)
{
GApplicationCommandLine *cmdline = data;
// do the heavy lifting in an idle
g_application_command_line_set_exit_status (cmdline, 0);
g_object_unref (cmdline); // this releases the applicationreturn G_SOURCE_REMOVE;
}
staticint
command_line (GApplication *application,
GApplicationCommandLine *cmdline)
{
// keep the application running until we are done with this commandline
g_application_hold (application);
g_object_set_data_full (G_OBJECT (cmdline),
"application", application,
(GDestroyNotify)g_application_release);
g_object_ref (cmdline);
g_idle_add (my_cmdline_handler, cmdline);
return0;
}
In this example the commandline is not completely handled before
the signal@Gio.Application::command-line handler returns. Instead, we keep
a reference to the gio.application_command_line.ApplicationCommandLine object and handle it
later (in this example, in an idle). Note that it is necessary to
hold the application until you are done with the commandline.
gio.application_command_line.ApplicationCommandLine represents a command-line invocation of an application.
It is created by gio.application.Application and emitted in the signal@Gio.Application::command-line signal and virtual function.
The class contains the list of arguments that the program was invoked with. It is also possible to query if the commandline invocation was local (ie: the current process is running in direct response to the invocation) or remote (ie: some other process forwarded the commandline to this process).
The gio.application_command_line.ApplicationCommandLine object can provide the @argc and @argv parameters for use with the glib.option_context.OptionContext command-line parsing API, with the gio.application_command_line.ApplicationCommandLine.getArguments function. See [gapplication-example-cmdline3.c][gapplication-example-cmdline3] for an example.
The exit status of the originally-invoked process may be set and messages can be printed to stdout or stderr of that process.
For remote invocation, the originally-invoked process exits when gio.application_command_line.ApplicationCommandLine.done method is called. This method is also automatically called when the object is disposed.
The main use for gio.application_command_line.ApplicationCommandLine (and the signal@Gio.Application::command-line signal) is 'Emacs server' like use cases: You can set the EDITOR environment variable to have e.g. git use your favourite editor to edit commit messages, and if you already have an instance of the editor running, the editing will happen in the running instance, instead of opening a new one. An important aspect of this use case is that the process that gets started by git does not return until the editing is done.
Normally, the commandline is completely handled in the signal@Gio.Application::command-line handler. The launching instance exits once the signal handler in the primary instance has returned, and the return value of the signal handler becomes the exit status of the launching instance.
The complete example can be found here: gapplication-example-cmdline.c
In more complicated cases, the handling of the commandline can be split between the launcher and the primary instance.
In this example of split commandline handling, options that start with --local- are handled locally, all other options are passed to the signal@Gio.Application::command-line handler which runs in the primary instance.
The complete example can be found here: gapplication-example-cmdline2.c
If handling the commandline requires a lot of work, it may be better to defer it.
In this example the commandline is not completely handled before the signal@Gio.Application::command-line handler returns. Instead, we keep a reference to the gio.application_command_line.ApplicationCommandLine object and handle it later (in this example, in an idle). Note that it is necessary to hold the application until you are done with the commandline.
The complete example can be found here: gapplication-example-cmdline3.c