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/* Copyright (C) 2011 The giomm Development Team
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library. If not, see <http://www.gnu.org/licenses/>.
*/
_CONFIGINCLUDE(giommconfig.h)
#include <glibmm/interface.h>
#include <glibmm/variant.h>
#include <glibmm/varianttype.h>
#include <gio/gio.h>
_DEFS(giomm,gio)
_PINCLUDE(glibmm/private/interface_p.h)
_PINCLUDE(gio/gio.h)
#ifndef DOXYGEN_SHOULD_SKIP_THIS
typedef struct _GActionInterface GActionInterface;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
namespace Gio
{
/** Action - An action.
* Action represents a single named action.
*
* The main interface to an action is that it can be activated with activate().
* This results in the signal_activate() signal being emitted. An activation
* has a Glib::VariantBase parameter (which may be <tt>0</tt>). The correct
* type for the parameter is determined by a static parameter type (which is
* given at construction time).
*
* An action may optionally have a state, in which case the state may be set
* with change_state(). This call takes a Glib::VariantBase. The correct type
* for the state is determined by a static state type (which is given at
* construction time).
*
* The state may have a hint associated with it, specifying its valid range.
*
* Action is merely the interface to the concept of an action, as described
* above. Various implementations of actions exist, including SimpleAction and
* Gtk::Action.
*
* In all cases, the implementing class is responsible for storing the name of
* the action, the parameter type, the enabled state, the optional state type
* and the state and emitting the appropriate signals when these change. The
* implementor responsible for filtering calls to activate() and change_state()
* for type safety and for the state being enabled.
*
* Probably the only useful thing to do with a Action is to put it inside of a
* SimpleActionGroup.
*
* @newin{2,32}
*/
class GIOMM_API Action : public Glib::Interface
{
_CLASS_INTERFACE(Action, GAction, G_ACTION, GActionInterface, , , GIOMM_API)
public:
_WRAP_METHOD(Glib::ustring get_name() const, g_action_get_name)
_WRAP_METHOD(Glib::VariantType get_parameter_type() const, g_action_get_parameter_type)
_WRAP_METHOD(Glib::VariantType get_state_type() const, g_action_get_state_type)
//TODO: Is there any specific type that can really be used with this? A std::list<>. We must test this.
// See also ActionGroup:::get_action_state_hint().
/** Requests a hint about the valid range of values for the state of
* the action.
*
* If a null Variant is returned it either means that the action is not stateful
* or that there is no hint about the valid range of values for the
* state of the action.
*
* If a Variant array is returned then each item in the array is a
* possible value for the state. If a Variant pair (ie: two-tuple) is
* returned then the tuple specifies the inclusive lower and upper bound
* of valid values for the state.
*
* In any case, the information is merely a hint. It may be possible to
* have a state value outside of the hinted range and setting a value
* within the range may fail.
*
* @param value This will be set to the state range hint.
*/
template <typename T_Value>
void get_state_hint(T_Value& value) const;
_WRAP_METHOD(Glib::VariantContainerBase get_state_hint_variant() const, g_action_get_state_hint)
_WRAP_METHOD(bool get_enabled() const, g_action_get_enabled)
/** Request for the state of @a action to be changed to @a value,
* assuming that the action has the expected state type.
*
* See get_state_type().
*
* This call merely requests a change. The action may refuse to change
* its state or may change its state to something other than @a value.
* See get_state_hint().
*
* @newin{2,38}
*
* @param value The new state.
*/
template <typename T_Value>
void change_state(const T_Value& value);
//This is just here to maintain API compatibility,
//by stopping the compiler from calling the
//regular change_state() with a Variant,
//if the application code previously called change_state(VariantBase).
template <typename T_Value>
void change_state(const Glib::Variant<T_Value>& value);
_WRAP_METHOD(void change_state_variant(const Glib::VariantBase& value), g_action_change_state)
/** Queries the current state of the action.
*
* If the action is not stateful then a null Variant will be returned. If the
* action is stateful then the type of the return value is the type
* given by get_state_type().
*
* @param value This will be set to the current state of the action.
*/
template <typename T_Value>
void get_state(T_Value& value) const;
_WRAP_METHOD(Glib::VariantBase get_state_variant() const, g_action_get_state)
/** Activates the action.
*/
void activate();
/** Activates the action.
*
* The @a parameter must be the correct type of parameter for the action (ie:
* the parameter type given at construction time), if any.
*
* @param parameter: The parameter to the activation
*/
template <typename T_Value>
void activate(const T_Value& parameter);
//This is just here to maintain API compatibility,
//by stopping the compiler from calling the
//regular activate() with a Variant,
//if the application code previously called activate(VariantBase).
template <typename T_Value>
void activate(const Glib::Variant<T_Value>& parameter);
_WRAP_METHOD(void activate_variant(const Glib::VariantBase& parameter), g_action_activate)
_WRAP_METHOD(static bool name_is_valid(const Glib::ustring& action_name), g_action_name_is_valid )
/** Parses a detailed action name into its separate name and target components.
*
* Detailed action names can have three formats. See parse_detailed_name_variant().
*
* @newin{2,40}
*
* @param detailed_name A detailed action name.
* @param[out] action_name The action name.
* @param[out] target_value The target value.
* @throw Glib::VariantParseError if @a detailed_name has an invalid format or a target of an unexpected type.
*/
template <typename T_Value>
static void parse_detailed_name(const Glib::ustring& detailed_name, Glib::ustring& action_name, T_Value& target_value);
_WRAP_METHOD(static void parse_detailed_name_variant(const Glib::ustring& detailed_name,
Glib::ustring& action_name{>>}, Glib::VariantBase& target_value{>>}), g_action_parse_detailed_name, errthrow "Glib::VariantParseError")
/** Formats a detailed action name from the action's action_name and @a target_value.
*
* This function is the opposite of parse_detailed_action_name().
* It will produce a string that can be parsed back to the @a action_name
* and @a target_value by that function.
*
* See that function for the types of strings that will be printed by
* this function.
*
* @param target_value A Variant target value.
* @result A detailed format string.
*/
template <typename T_Value>
Glib::ustring print_detailed_name(const T_Value& target_value);
_WRAP_METHOD(static Glib::ustring print_detailed_name_variant(const Glib::ustring& action_name, const Glib::VariantBase& target_value), g_action_print_detailed_name)
_WRAP_PROPERTY("enabled", bool)
_WRAP_PROPERTY("name", Glib::ustring)
_WRAP_PROPERTY("parameter-type", Glib::VariantType)
_WRAP_PROPERTY("state", Glib::VariantBase)
_WRAP_PROPERTY("state-type", Glib::VariantType)
protected:
#m4 _CONVERSION(`Glib::ustring',`const gchar*',`$3.c_str()')
_WRAP_VFUNC(Glib::ustring get_name() const, "get_name", keep_return)
#m4 _CONVERSION(`Glib::VariantType',`const GVariantType*',`$3.gobj()')
_WRAP_VFUNC(Glib::VariantType get_parameter_type() const, "get_parameter_type", keep_return)
_WRAP_VFUNC(Glib::VariantType get_state_type() const, "get_state_type", keep_return)
_WRAP_VFUNC(Glib::VariantBase get_state_hint() const, "get_state_hint", refreturn_ctype)
_WRAP_VFUNC(bool get_enabled() const, "get_enabled")
_WRAP_VFUNC(Glib::VariantBase get_state() const, "get_state", refreturn_ctype)
#m4 _CONVERSION(`GVariant*',`const Glib::VariantBase&',`Glib::wrap($3, true)')
_WRAP_VFUNC(void change_state(const Glib::VariantBase& value), "change_state")
_WRAP_VFUNC(void activate(const Glib::VariantBase& parameter), "activate")
};
template <typename T_Value>
void Action::get_state(T_Value& value) const
{
value = T_Value(); //Make sure that it is initialized.
using type_glib_variant = Glib::Variant<T_Value>;
g_return_if_fail(
g_variant_type_equal(g_action_get_state_type(const_cast<GAction*>(gobj())), type_glib_variant::variant_type().gobj()));
const auto variantBase = get_state_variant();
const auto variantDerived = variantBase.cast_dynamic<type_glib_variant>(variantBase);
value = variantDerived.get();
}
template <typename T_Value>
void Action::get_state_hint(T_Value& value) const
{
value = T_Value(); //Make sure that it is initialized.
using type_glib_variant = Glib::Variant<T_Value>;
const auto variantBase = get_state_hint_variant();
// We can't check the type (a range) that will be returned before getting the range hint.
g_return_if_fail(
variantBase.is_of_type(type_glib_variant::variant_type()) );
const auto variantDerived = variantBase.cast_dynamic<type_glib_variant>(variantBase);
value = variantDerived.get();
}
#ifndef DOXYGEN_SHOULD_SKIP_THIS
// Doxygen 1.8.4 does not understand that this is the static function previously declared.
template <typename T_Value>
//static
void Action::parse_detailed_name(const Glib::ustring& detailed_name, Glib::ustring& action_name, T_Value& target_value)
{
action_name.clear(); //Make sure the output arguments are initialized.
target_value = T_Value();
using type_glib_variant = Glib::Variant<T_Value>;
Glib::VariantBase target_value_variantBase;
parse_detailed_name_variant(detailed_name, action_name, target_value_variantBase);
if (!target_value_variantBase)
throw Glib::VariantParseError(Glib::VariantParseError::TYPE_ERROR,
"Detailed action name '" + detailed_name + "' has no target. Expected a target of type " +
type_glib_variant::variant_type().get_string());
if (!target_value_variantBase.is_of_type(type_glib_variant::variant_type()))
throw Glib::VariantParseError(Glib::VariantParseError::TYPE_ERROR,
"Detailed action name '" + detailed_name + "' has a target of type " +
target_value_variantBase.get_type_string() + ". Expected " + type_glib_variant::variant_type().get_string());
const type_glib_variant target_value_variantDerived =
target_value_variantBase.cast_dynamic<type_glib_variant>(target_value_variantBase);
target_value = target_value_variantDerived.get();
}
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
template <typename T_Value>
Glib::ustring Action::print_detailed_name(const T_Value& target_value)
{
using type_glib_variant = Glib::Variant<T_Value>;
g_return_val_if_fail(
g_variant_type_equal(g_action_get_parameter_type(const_cast<GAction*>(gobj())), type_glib_variant::variant_type().gobj()),
Glib::ustring());
return print_detailed_name_variant(get_name(), type_glib_variant::create(target_value));
}
template <typename T_Value>
void Action::change_state(const T_Value& value)
{
using type_glib_variant = Glib::Variant<T_Value>;
g_return_if_fail(
g_variant_type_equal(g_action_get_state_type(const_cast<GAction*>(gobj())), type_glib_variant::variant_type().gobj()));
change_state_variant(type_glib_variant::create(value));
}
template <typename T_Value>
void Action::change_state(const Glib::Variant<T_Value>& value)
{
change_state_variant(value);
}
template <typename T_Value>
void Action::activate(const T_Value& parameter)
{
using type_glib_variant = Glib::Variant<T_Value>;
g_return_if_fail(
g_variant_type_equal(g_action_get_parameter_type(const_cast<GAction*>(gobj())), type_glib_variant::variant_type().gobj()));
activate_variant(type_glib_variant::create(parameter));
}
template <typename T_Value>
void Action::activate(const Glib::Variant<T_Value>& value)
{
activate_variant(value);
}
} // namespace Gio
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