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// This file was generated by gir (https://github.com/gtk-rs/gir)
// from gir-files (https://github.com/gtk-rs/gir-files.git)
// DO NOT EDIT
use crate::TreeIter;
use crate::TreeModelFlags;
use crate::TreePath;
use glib::object::Cast;
use glib::object::IsA;
use glib::signal::connect_raw;
use glib::signal::SignalHandlerId;
use glib::translate::*;
use std::boxed::Box as Box_;
use std::fmt;
use std::mem::transmute;
glib::wrapper! {
/// The tree interface used by GtkTreeView
///
/// The [`TreeModel`][crate::TreeModel] interface defines a generic tree interface for
/// use by the [`TreeView`][crate::TreeView] widget. It is an abstract interface, and
/// is designed to be usable with any appropriate data structure. The
/// programmer just has to implement this interface on their own data
/// type for it to be viewable by a [`TreeView`][crate::TreeView] widget.
///
/// The model is represented as a hierarchical tree of strongly-typed,
/// columned data. In other words, the model can be seen as a tree where
/// every node has different values depending on which column is being
/// queried. The type of data found in a column is determined by using
/// the GType system (ie. `G_TYPE_INT`, `GTK_TYPE_BUTTON`, `G_TYPE_POINTER`,
/// etc). The types are homogeneous per column across all nodes. It is
/// important to note that this interface only provides a way of examining
/// a model and observing changes. The implementation of each individual
/// model decides how and if changes are made.
///
/// In order to make life simpler for programmers who do not need to
/// write their own specialized model, two generic models are provided
/// — the [`TreeStore`][crate::TreeStore] and the [`ListStore`][crate::ListStore]. To use these, the
/// developer simply pushes data into these models as necessary. These
/// models provide the data structure as well as all appropriate tree
/// interfaces. As a result, implementing drag and drop, sorting, and
/// storing data is trivial. For the vast majority of trees and lists,
/// these two models are sufficient.
///
/// Models are accessed on a node/column level of granularity. One can
/// query for the value of a model at a certain node and a certain
/// column on that node. There are two structures used to reference a
/// particular node in a model. They are the [`TreePath`][crate::TreePath] and
/// the [`TreeIter`][crate::TreeIter] (“iter” is short for iterator). Most of the
/// interface consists of operations on a [`TreeIter`][crate::TreeIter].
///
/// A path is essentially a potential node. It is a location on a model
/// that may or may not actually correspond to a node on a specific
/// model. A [`TreePath`][crate::TreePath] can be converted into either an
/// array of unsigned integers or a string. The string form is a list
/// of numbers separated by a colon. Each number refers to the offset
/// at that level. Thus, the path `0` refers to the root
/// node and the path `2:4` refers to the fifth child of
/// the third node.
///
/// By contrast, a [`TreeIter`][crate::TreeIter] is a reference to a specific node on
/// a specific model. It is a generic struct with an integer and three
/// generic pointers. These are filled in by the model in a model-specific
/// way. One can convert a path to an iterator by calling
/// gtk_tree_model_get_iter(). These iterators are the primary way
/// of accessing a model and are similar to the iterators used by
/// [`TextBuffer`][crate::TextBuffer]. They are generally statically allocated on the
/// stack and only used for a short time. The model interface defines
/// a set of operations using them for navigating the model.
///
/// It is expected that models fill in the iterator with private data.
/// For example, the [`ListStore`][crate::ListStore] model, which is internally a simple
/// linked list, stores a list node in one of the pointers. The
/// [`TreeModel`][crate::TreeModel]Sort stores an array and an offset in two of the
/// pointers. Additionally, there is an integer field. This field is
/// generally filled with a unique stamp per model. This stamp is for
/// catching errors resulting from using invalid iterators with a model.
///
/// The lifecycle of an iterator can be a little confusing at first.
/// Iterators are expected to always be valid for as long as the model
/// is unchanged (and doesn’t emit a signal). The model is considered
/// to own all outstanding iterators and nothing needs to be done to
/// free them from the user’s point of view. Additionally, some models
/// guarantee that an iterator is valid for as long as the node it refers
/// to is valid (most notably the [`TreeStore`][crate::TreeStore] and [`ListStore`][crate::ListStore]).
/// Although generally uninteresting, as one always has to allow for
/// the case where iterators do not persist beyond a signal, some very
/// important performance enhancements were made in the sort model.
/// As a result, the [`TreeModelFlags::ITERS_PERSIST`][crate::TreeModelFlags::ITERS_PERSIST] flag was added to
/// indicate this behavior.
///
/// To help show some common operation of a model, some examples are
/// provided. The first example shows three ways of getting the iter at
/// the location `3:2:5`. While the first method shown is
/// easier, the second is much more common, as you often get paths from
/// callbacks.
///
/// ## Acquiring a [`TreeIter`][crate::TreeIter]
///
/// **⚠️ The following code is in c ⚠️**
///
/// ```c
/// // Three ways of getting the iter pointing to the location
/// GtkTreePath *path;
/// GtkTreeIter iter;
/// GtkTreeIter parent_iter;
///
/// // get the iterator from a string
/// gtk_tree_model_get_iter_from_string (model,
/// &iter,
/// "3:2:5");
///
/// // get the iterator from a path
/// path = gtk_tree_path_new_from_string ("3:2:5");
/// gtk_tree_model_get_iter (model, &iter, path);
/// gtk_tree_path_free (path);
///
/// // walk the tree to find the iterator
/// gtk_tree_model_iter_nth_child (model, &iter,
/// NULL, 3);
/// parent_iter = iter;
/// gtk_tree_model_iter_nth_child (model, &iter,
/// &parent_iter, 2);
/// parent_iter = iter;
/// gtk_tree_model_iter_nth_child (model, &iter,
/// &parent_iter, 5);
/// ```
///
/// This second example shows a quick way of iterating through a list
/// and getting a string and an integer from each row. The
/// populate_model() function used below is not
/// shown, as it is specific to the [`ListStore`][crate::ListStore]. For information on
/// how to write such a function, see the [`ListStore`][crate::ListStore] documentation.
///
/// ## Reading data from a [`TreeModel`][crate::TreeModel]
///
/// **⚠️ The following code is in c ⚠️**
///
/// ```c
/// enum
/// {
/// STRING_COLUMN,
/// INT_COLUMN,
/// N_COLUMNS
/// };
///
/// ...
///
/// GtkTreeModel *list_store;
/// GtkTreeIter iter;
/// gboolean valid;
/// int row_count = 0;
///
/// // make a new list_store
/// list_store = gtk_list_store_new (N_COLUMNS,
/// G_TYPE_STRING,
/// G_TYPE_INT);
///
/// // Fill the list store with data
/// populate_model (list_store);
///
/// // Get the first iter in the list, check it is valid and walk
/// // through the list, reading each row.
///
/// valid = gtk_tree_model_get_iter_first (list_store,
/// &iter);
/// while (valid)
/// {
/// char *str_data;
/// int int_data;
///
/// // Make sure you terminate calls to gtk_tree_model_get() with a “-1” value
/// gtk_tree_model_get (list_store, &iter,
/// STRING_COLUMN, &str_data,
/// INT_COLUMN, &int_data,
/// -1);
///
/// // Do something with the data
/// g_print ("Row %d: (%s,%d)\n",
/// row_count, str_data, int_data);
/// g_free (str_data);
///
/// valid = gtk_tree_model_iter_next (list_store,
/// &iter);
/// row_count++;
/// }
/// ```
///
/// The [`TreeModel`][crate::TreeModel] interface contains two methods for reference
/// counting: gtk_tree_model_ref_node() and gtk_tree_model_unref_node().
/// These two methods are optional to implement. The reference counting
/// is meant as a way for views to let models know when nodes are being
/// displayed. [`TreeView`][crate::TreeView] will take a reference on a node when it is
/// visible, which means the node is either in the toplevel or expanded.
/// Being displayed does not mean that the node is currently directly
/// visible to the user in the viewport. Based on this reference counting
/// scheme a caching model, for example, can decide whether or not to cache
/// a node based on the reference count. A file-system based model would
/// not want to keep the entire file hierarchy in memory, but just the
/// folders that are currently expanded in every current view.
///
/// When working with reference counting, the following rules must be taken
/// into account:
///
/// - Never take a reference on a node without owning a reference on its parent.
/// This means that all parent nodes of a referenced node must be referenced
/// as well.
///
/// - Outstanding references on a deleted node are not released. This is not
/// possible because the node has already been deleted by the time the
/// row-deleted signal is received.
///
/// - Models are not obligated to emit a signal on rows of which none of its
/// siblings are referenced. To phrase this differently, signals are only
/// required for levels in which nodes are referenced. For the root level
/// however, signals must be emitted at all times (however the root level
/// is always referenced when any view is attached).
///
/// # Implements
///
/// [`TreeModelExt`][trait@crate::prelude::TreeModelExt], [`TreeModelExtManual`][trait@crate::prelude::TreeModelExtManual]
#[doc(alias = "GtkTreeModel")]
pub struct TreeModel(Interface<ffi::GtkTreeModel, ffi::GtkTreeModelIface>);
match fn {
type_ => || ffi::gtk_tree_model_get_type(),
}
}
impl TreeModel {
pub const NONE: Option<&'static TreeModel> = None;
}
/// Trait containing all [`struct@TreeModel`] methods.
///
/// # Implementors
///
/// [`ListStore`][struct@crate::ListStore], [`TreeModelFilter`][struct@crate::TreeModelFilter], [`TreeModelSort`][struct@crate::TreeModelSort], [`TreeModel`][struct@crate::TreeModel], [`TreeSortable`][struct@crate::TreeSortable], [`TreeStore`][struct@crate::TreeStore]
pub trait TreeModelExt: 'static {
/// Calls @func on each node in model in a depth-first fashion.
///
/// If @func returns [`true`], then the tree ceases to be walked,
/// and gtk_tree_model_foreach() returns.
/// ## `func`
/// a function to be called on each row
#[doc(alias = "gtk_tree_model_foreach")]
fn foreach<P: FnMut(&TreeModel, &TreePath, &TreeIter) -> bool>(&self, func: P);
/// Returns the type of the column.
/// ## `index_`
/// the column index
///
/// # Returns
///
/// the type of the column
#[doc(alias = "gtk_tree_model_get_column_type")]
#[doc(alias = "get_column_type")]
fn column_type(&self, index_: i32) -> glib::types::Type;
/// Returns a set of flags supported by this interface.
///
/// The flags are a bitwise combination of [`TreeModel`][crate::TreeModel]Flags.
/// The flags supported should not change during the lifetime
/// of the @self.
///
/// # Returns
///
/// the flags supported by this interface
#[doc(alias = "gtk_tree_model_get_flags")]
#[doc(alias = "get_flags")]
fn flags(&self) -> TreeModelFlags;
/// Sets @iter to a valid iterator pointing to @path.
///
/// If @path does not exist, @iter is set to an invalid
/// iterator and [`false`] is returned.
/// ## `path`
/// the [`TreePath`][crate::TreePath]
///
/// # Returns
///
/// [`true`], if @iter was set
///
/// ## `iter`
/// the uninitialized [`TreeIter`][crate::TreeIter]
#[doc(alias = "gtk_tree_model_get_iter")]
#[doc(alias = "get_iter")]
fn iter(&self, path: &TreePath) -> Option<TreeIter>;
/// Initializes @iter with the first iterator in the tree
/// (the one at the path "0").
///
/// Returns [`false`] if the tree is empty, [`true`] otherwise.
///
/// # Returns
///
/// [`true`], if @iter was set
///
/// ## `iter`
/// the uninitialized [`TreeIter`][crate::TreeIter]
#[doc(alias = "gtk_tree_model_get_iter_first")]
#[doc(alias = "get_iter_first")]
fn iter_first(&self) -> Option<TreeIter>;
/// Sets @iter to a valid iterator pointing to @path_string, if it
/// exists.
///
/// Otherwise, @iter is left invalid and [`false`] is returned.
/// ## `path_string`
/// a string representation of a [`TreePath`][crate::TreePath]
///
/// # Returns
///
/// [`true`], if @iter was set
///
/// ## `iter`
/// an uninitialized [`TreeIter`][crate::TreeIter]
#[doc(alias = "gtk_tree_model_get_iter_from_string")]
#[doc(alias = "get_iter_from_string")]
fn iter_from_string(&self, path_string: &str) -> Option<TreeIter>;
/// Returns the number of columns supported by @self.
///
/// # Returns
///
/// the number of columns
#[doc(alias = "gtk_tree_model_get_n_columns")]
#[doc(alias = "get_n_columns")]
fn n_columns(&self) -> i32;
/// Returns a newly-created [`TreePath`][crate::TreePath] referenced by @iter.
///
/// This path should be freed with gtk_tree_path_free().
/// ## `iter`
/// the [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// a newly-created [`TreePath`][crate::TreePath]
#[doc(alias = "gtk_tree_model_get_path")]
#[doc(alias = "get_path")]
fn path(&self, iter: &TreeIter) -> TreePath;
/// Generates a string representation of the iter.
///
/// This string is a “:” separated list of numbers.
/// For example, “4:10:0:3” would be an acceptable
/// return value for this string.
/// ## `iter`
/// a [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// a newly-allocated string
#[doc(alias = "gtk_tree_model_get_string_from_iter")]
#[doc(alias = "get_string_from_iter")]
fn string_from_iter(&self, iter: &TreeIter) -> Option<glib::GString>;
/// Sets @iter to point to the first child of @parent.
///
/// If @parent has no children, [`false`] is returned and @iter is
/// set to be invalid. @parent will remain a valid node after this
/// function has been called.
///
/// If @parent is [`None`] returns the first node, equivalent to
/// `gtk_tree_model_get_iter_first (tree_model, iter);`
/// ## `parent`
/// the [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// [`true`], if @iter has been set to the first child
///
/// ## `iter`
/// the new [`TreeIter`][crate::TreeIter] to be set to the child
#[doc(alias = "gtk_tree_model_iter_children")]
fn iter_children(&self, parent: Option<&TreeIter>) -> Option<TreeIter>;
/// Returns [`true`] if @iter has children, [`false`] otherwise.
/// ## `iter`
/// the [`TreeIter`][crate::TreeIter] to test for children
///
/// # Returns
///
/// [`true`] if @iter has children
#[doc(alias = "gtk_tree_model_iter_has_child")]
fn iter_has_child(&self, iter: &TreeIter) -> bool;
/// Returns the number of children that @iter has.
///
/// As a special case, if @iter is [`None`], then the number
/// of toplevel nodes is returned.
/// ## `iter`
/// the [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// the number of children of @iter
#[doc(alias = "gtk_tree_model_iter_n_children")]
fn iter_n_children(&self, iter: Option<&TreeIter>) -> i32;
/// Sets @iter to point to the node following it at the current level.
///
/// If there is no next @iter, [`false`] is returned and @iter is set
/// to be invalid.
/// ## `iter`
/// the [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// [`true`] if @iter has been changed to the next node
#[doc(alias = "gtk_tree_model_iter_next")]
fn iter_next(&self, iter: &TreeIter) -> bool;
/// Sets @iter to be the child of @parent, using the given index.
///
/// The first index is 0. If @n is too big, or @parent has no children,
/// @iter is set to an invalid iterator and [`false`] is returned. @parent
/// will remain a valid node after this function has been called. As a
/// special case, if @parent is [`None`], then the @n-th root node
/// is set.
/// ## `parent`
/// the [`TreeIter`][crate::TreeIter] to get the child from
/// ## `n`
/// the index of the desired child
///
/// # Returns
///
/// [`true`], if @parent has an @n-th child
///
/// ## `iter`
/// the [`TreeIter`][crate::TreeIter] to set to the nth child
#[doc(alias = "gtk_tree_model_iter_nth_child")]
fn iter_nth_child(&self, parent: Option<&TreeIter>, n: i32) -> Option<TreeIter>;
/// Sets @iter to be the parent of @child.
///
/// If @child is at the toplevel, and doesn’t have a parent, then
/// @iter is set to an invalid iterator and [`false`] is returned.
/// @child will remain a valid node after this function has been
/// called.
///
/// @iter will be initialized before the lookup is performed, so @child
/// and @iter cannot point to the same memory location.
/// ## `child`
/// the [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// [`true`], if @iter is set to the parent of @child
///
/// ## `iter`
/// the new [`TreeIter`][crate::TreeIter] to set to the parent
#[doc(alias = "gtk_tree_model_iter_parent")]
fn iter_parent(&self, child: &TreeIter) -> Option<TreeIter>;
/// Sets @iter to point to the previous node at the current level.
///
/// If there is no previous @iter, [`false`] is returned and @iter is
/// set to be invalid.
/// ## `iter`
/// the [`TreeIter`][crate::TreeIter]
///
/// # Returns
///
/// [`true`] if @iter has been changed to the previous node
#[doc(alias = "gtk_tree_model_iter_previous")]
fn iter_previous(&self, iter: &TreeIter) -> bool;
/// Emits the ::row-changed signal on @self.
///
/// See `signal::TreeModel::row-changed`.
/// ## `path`
/// a [`TreePath`][crate::TreePath] pointing to the changed row
/// ## `iter`
/// a valid [`TreeIter`][crate::TreeIter] pointing to the changed row
#[doc(alias = "gtk_tree_model_row_changed")]
fn row_changed(&self, path: &TreePath, iter: &TreeIter);
/// Emits the ::row-deleted signal on @self.
///
/// See `signal::TreeModel::row-deleted`.
///
/// This should be called by models after a row has been removed.
/// The location pointed to by @path should be the location that
/// the row previously was at. It may not be a valid location anymore.
///
/// Nodes that are deleted are not unreffed, this means that any
/// outstanding references on the deleted node should not be released.
/// ## `path`
/// a [`TreePath`][crate::TreePath] pointing to the previous location of
/// the deleted row
#[doc(alias = "gtk_tree_model_row_deleted")]
fn row_deleted(&self, path: &TreePath);
/// Emits the ::row-has-child-toggled signal on @self.
///
/// See `signal::TreeModel::row-has-child-toggled`.
///
/// This should be called by models after the child
/// state of a node changes.
/// ## `path`
/// a [`TreePath`][crate::TreePath] pointing to the changed row
/// ## `iter`
/// a valid [`TreeIter`][crate::TreeIter] pointing to the changed row
#[doc(alias = "gtk_tree_model_row_has_child_toggled")]
fn row_has_child_toggled(&self, path: &TreePath, iter: &TreeIter);
/// Emits the ::row-inserted signal on @self.
///
/// See `signal::TreeModel::row-inserted`.
/// ## `path`
/// a [`TreePath`][crate::TreePath] pointing to the inserted row
/// ## `iter`
/// a valid [`TreeIter`][crate::TreeIter] pointing to the inserted row
#[doc(alias = "gtk_tree_model_row_inserted")]
fn row_inserted(&self, path: &TreePath, iter: &TreeIter);
/// This signal is emitted when a row in the model has changed.
/// ## `path`
/// a [`TreePath`][crate::TreePath] identifying the changed row
/// ## `iter`
/// a valid [`TreeIter`][crate::TreeIter] pointing to the changed row
#[doc(alias = "row-changed")]
fn connect_row_changed<F: Fn(&Self, &TreePath, &TreeIter) + 'static>(
&self,
f: F,
) -> SignalHandlerId;
/// This signal is emitted when a row has been deleted.
///
/// Note that no iterator is passed to the signal handler,
/// since the row is already deleted.
///
/// This should be called by models after a row has been removed.
/// The location pointed to by @path should be the location that
/// the row previously was at. It may not be a valid location anymore.
/// ## `path`
/// a [`TreePath`][crate::TreePath] identifying the row
#[doc(alias = "row-deleted")]
fn connect_row_deleted<F: Fn(&Self, &TreePath) + 'static>(&self, f: F) -> SignalHandlerId;
/// This signal is emitted when a row has gotten the first child
/// row or lost its last child row.
/// ## `path`
/// a [`TreePath`][crate::TreePath] identifying the row
/// ## `iter`
/// a valid [`TreeIter`][crate::TreeIter] pointing to the row
#[doc(alias = "row-has-child-toggled")]
fn connect_row_has_child_toggled<F: Fn(&Self, &TreePath, &TreeIter) + 'static>(
&self,
f: F,
) -> SignalHandlerId;
/// This signal is emitted when a new row has been inserted in
/// the model.
///
/// Note that the row may still be empty at this point, since
/// it is a common pattern to first insert an empty row, and
/// then fill it with the desired values.
/// ## `path`
/// a [`TreePath`][crate::TreePath] identifying the new row
/// ## `iter`
/// a valid [`TreeIter`][crate::TreeIter] pointing to the new row
#[doc(alias = "row-inserted")]
fn connect_row_inserted<F: Fn(&Self, &TreePath, &TreeIter) + 'static>(
&self,
f: F,
) -> SignalHandlerId;
//#[doc(alias = "rows-reordered")]
//fn connect_rows_reordered<Unsupported or ignored types>(&self, f: F) -> SignalHandlerId;
}
impl<O: IsA<TreeModel>> TreeModelExt for O {
fn foreach<P: FnMut(&TreeModel, &TreePath, &TreeIter) -> bool>(&self, func: P) {
let func_data: P = func;
unsafe extern "C" fn func_func<P: FnMut(&TreeModel, &TreePath, &TreeIter) -> bool>(
model: *mut ffi::GtkTreeModel,
path: *mut ffi::GtkTreePath,
iter: *mut ffi::GtkTreeIter,
data: glib::ffi::gpointer,
) -> glib::ffi::gboolean {
let model = from_glib_borrow(model);
let path = from_glib_borrow(path);
let iter = from_glib_borrow(iter);
let callback: *mut P = data as *const _ as usize as *mut P;
let res = (*callback)(&model, &path, &iter);
res.into_glib()
}
let func = Some(func_func::<P> as _);
let super_callback0: &P = &func_data;
unsafe {
ffi::gtk_tree_model_foreach(
self.as_ref().to_glib_none().0,
func,
super_callback0 as *const _ as usize as *mut _,
);
}
}
fn column_type(&self, index_: i32) -> glib::types::Type {
unsafe {
from_glib(ffi::gtk_tree_model_get_column_type(
self.as_ref().to_glib_none().0,
index_,
))
}
}
fn flags(&self) -> TreeModelFlags {
unsafe {
from_glib(ffi::gtk_tree_model_get_flags(
self.as_ref().to_glib_none().0,
))
}
}
fn iter(&self, path: &TreePath) -> Option<TreeIter> {
unsafe {
let mut iter = TreeIter::uninitialized();
let ret = from_glib(ffi::gtk_tree_model_get_iter(
self.as_ref().to_glib_none().0,
iter.to_glib_none_mut().0,
mut_override(path.to_glib_none().0),
));
if ret {
Some(iter)
} else {
None
}
}
}
fn iter_first(&self) -> Option<TreeIter> {
unsafe {
let mut iter = TreeIter::uninitialized();
let ret = from_glib(ffi::gtk_tree_model_get_iter_first(
self.as_ref().to_glib_none().0,
iter.to_glib_none_mut().0,
));
if ret {
Some(iter)
} else {
None
}
}
}
fn iter_from_string(&self, path_string: &str) -> Option<TreeIter> {
unsafe {
let mut iter = TreeIter::uninitialized();
let ret = from_glib(ffi::gtk_tree_model_get_iter_from_string(
self.as_ref().to_glib_none().0,
iter.to_glib_none_mut().0,
path_string.to_glib_none().0,
));
if ret {
Some(iter)
} else {
None
}
}
}
fn n_columns(&self) -> i32 {
unsafe { ffi::gtk_tree_model_get_n_columns(self.as_ref().to_glib_none().0) }
}
fn path(&self, iter: &TreeIter) -> TreePath {
unsafe {
from_glib_full(ffi::gtk_tree_model_get_path(
self.as_ref().to_glib_none().0,
mut_override(iter.to_glib_none().0),
))
}
}
fn string_from_iter(&self, iter: &TreeIter) -> Option<glib::GString> {
unsafe {
from_glib_full(ffi::gtk_tree_model_get_string_from_iter(
self.as_ref().to_glib_none().0,
mut_override(iter.to_glib_none().0),
))
}
}
fn iter_children(&self, parent: Option<&TreeIter>) -> Option<TreeIter> {
unsafe {
let mut iter = TreeIter::uninitialized();
let ret = from_glib(ffi::gtk_tree_model_iter_children(
self.as_ref().to_glib_none().0,
iter.to_glib_none_mut().0,
mut_override(parent.to_glib_none().0),
));
if ret {
Some(iter)
} else {
None
}
}
}
fn iter_has_child(&self, iter: &TreeIter) -> bool {
unsafe {
from_glib(ffi::gtk_tree_model_iter_has_child(
self.as_ref().to_glib_none().0,
mut_override(iter.to_glib_none().0),
))
}
}
fn iter_n_children(&self, iter: Option<&TreeIter>) -> i32 {
unsafe {
ffi::gtk_tree_model_iter_n_children(
self.as_ref().to_glib_none().0,
mut_override(iter.to_glib_none().0),
)
}
}
fn iter_next(&self, iter: &TreeIter) -> bool {
unsafe {
from_glib(ffi::gtk_tree_model_iter_next(
self.as_ref().to_glib_none().0,
mut_override(iter.to_glib_none().0),
))
}
}
fn iter_nth_child(&self, parent: Option<&TreeIter>, n: i32) -> Option<TreeIter> {
unsafe {
let mut iter = TreeIter::uninitialized();
let ret = from_glib(ffi::gtk_tree_model_iter_nth_child(
self.as_ref().to_glib_none().0,
iter.to_glib_none_mut().0,
mut_override(parent.to_glib_none().0),
n,
));
if ret {
Some(iter)
} else {
None
}
}
}
fn iter_parent(&self, child: &TreeIter) -> Option<TreeIter> {
unsafe {
let mut iter = TreeIter::uninitialized();
let ret = from_glib(ffi::gtk_tree_model_iter_parent(
self.as_ref().to_glib_none().0,
iter.to_glib_none_mut().0,
mut_override(child.to_glib_none().0),
));
if ret {
Some(iter)
} else {
None
}
}
}
fn iter_previous(&self, iter: &TreeIter) -> bool {
unsafe {
from_glib(ffi::gtk_tree_model_iter_previous(
self.as_ref().to_glib_none().0,
mut_override(iter.to_glib_none().0),
))
}
}
fn row_changed(&self, path: &TreePath, iter: &TreeIter) {
unsafe {
ffi::gtk_tree_model_row_changed(
self.as_ref().to_glib_none().0,
mut_override(path.to_glib_none().0),
mut_override(iter.to_glib_none().0),
);
}
}
fn row_deleted(&self, path: &TreePath) {
unsafe {
ffi::gtk_tree_model_row_deleted(
self.as_ref().to_glib_none().0,
mut_override(path.to_glib_none().0),
);
}
}
fn row_has_child_toggled(&self, path: &TreePath, iter: &TreeIter) {
unsafe {
ffi::gtk_tree_model_row_has_child_toggled(
self.as_ref().to_glib_none().0,
mut_override(path.to_glib_none().0),
mut_override(iter.to_glib_none().0),
);
}
}
fn row_inserted(&self, path: &TreePath, iter: &TreeIter) {
unsafe {
ffi::gtk_tree_model_row_inserted(
self.as_ref().to_glib_none().0,
mut_override(path.to_glib_none().0),
mut_override(iter.to_glib_none().0),
);
}
}
fn connect_row_changed<F: Fn(&Self, &TreePath, &TreeIter) + 'static>(
&self,
f: F,
) -> SignalHandlerId {
unsafe extern "C" fn row_changed_trampoline<
P: IsA<TreeModel>,
F: Fn(&P, &TreePath, &TreeIter) + 'static,
>(
this: *mut ffi::GtkTreeModel,
path: *mut ffi::GtkTreePath,
iter: *mut ffi::GtkTreeIter,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(
TreeModel::from_glib_borrow(this).unsafe_cast_ref(),
&from_glib_borrow(path),
&from_glib_borrow(iter),
)
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"row-changed\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
row_changed_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
fn connect_row_deleted<F: Fn(&Self, &TreePath) + 'static>(&self, f: F) -> SignalHandlerId {
unsafe extern "C" fn row_deleted_trampoline<
P: IsA<TreeModel>,
F: Fn(&P, &TreePath) + 'static,
>(
this: *mut ffi::GtkTreeModel,
path: *mut ffi::GtkTreePath,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(
TreeModel::from_glib_borrow(this).unsafe_cast_ref(),
&from_glib_borrow(path),
)
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"row-deleted\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
row_deleted_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
fn connect_row_has_child_toggled<F: Fn(&Self, &TreePath, &TreeIter) + 'static>(
&self,
f: F,
) -> SignalHandlerId {
unsafe extern "C" fn row_has_child_toggled_trampoline<
P: IsA<TreeModel>,
F: Fn(&P, &TreePath, &TreeIter) + 'static,
>(
this: *mut ffi::GtkTreeModel,
path: *mut ffi::GtkTreePath,
iter: *mut ffi::GtkTreeIter,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(
TreeModel::from_glib_borrow(this).unsafe_cast_ref(),
&from_glib_borrow(path),
&from_glib_borrow(iter),
)
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"row-has-child-toggled\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
row_has_child_toggled_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
fn connect_row_inserted<F: Fn(&Self, &TreePath, &TreeIter) + 'static>(
&self,
f: F,
) -> SignalHandlerId {
unsafe extern "C" fn row_inserted_trampoline<
P: IsA<TreeModel>,
F: Fn(&P, &TreePath, &TreeIter) + 'static,
>(
this: *mut ffi::GtkTreeModel,
path: *mut ffi::GtkTreePath,
iter: *mut ffi::GtkTreeIter,
f: glib::ffi::gpointer,
) {
let f: &F = &*(f as *const F);
f(
TreeModel::from_glib_borrow(this).unsafe_cast_ref(),
&from_glib_borrow(path),
&from_glib_borrow(iter),
)
}
unsafe {
let f: Box_<F> = Box_::new(f);
connect_raw(
self.as_ptr() as *mut _,
b"row-inserted\0".as_ptr() as *const _,
Some(transmute::<_, unsafe extern "C" fn()>(
row_inserted_trampoline::<Self, F> as *const (),
)),
Box_::into_raw(f),
)
}
}
//fn connect_rows_reordered<Unsupported or ignored types>(&self, f: F) -> SignalHandlerId {
// Unimplemented new_order: *.Pointer
//}
}
impl fmt::Display for TreeModel {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str("TreeModel")
}
}