/* gtktreemodel.c * Copyright (C) 2000 Red Hat, Inc., Jonathan Blandford * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library. If not, see . */ #include "config.h" #include #include #include #include #include #include "gtktreemodel.h" #include "gtktreeview.h" #include "gtktreeprivate.h" #include "gtkmarshalers.h" #include "gtkintl.h" /** * GtkTreeModel: * * The tree interface used by GtkTreeView * * The `GtkTreeModel` interface defines a generic tree interface for * use by the `GtkTreeView` 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 `GtkTreeView` 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 `GtkTreeStore` and the `GtkListStore`. 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 [struct@Gtk.TreePath] and * the [struct@Gtk.TreeIter] (“iter” is short for iterator). Most of the * interface consists of operations on a [struct@Gtk.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 [struct@Gtk.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 [struct@Gtk.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 * `GtkTextBuffer`. 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 `GtkListStore` model, which is internally a simple * linked list, stores a list node in one of the pointers. The * `GtkTreeModel`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 `GtkTreeStore` and `GtkListStore`). * 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 %GTK_TREE_MODEL_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 `GtkTreeIter` * * ```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 `GtkListStore`. For information on * how to write such a function, see the `GtkListStore` documentation. * * ## Reading data from a `GtkTreeModel` * * ```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 `GtkTreeModel` 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. `GtkTreeView` 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). */ #define INITIALIZE_TREE_ITER(Iter) \ G_STMT_START{ \ (Iter)->stamp = 0; \ (Iter)->user_data = NULL; \ (Iter)->user_data2 = NULL; \ (Iter)->user_data3 = NULL; \ }G_STMT_END #define ROW_REF_DATA_STRING "gtk-tree-row-refs" enum { ROW_CHANGED, ROW_INSERTED, ROW_HAS_CHILD_TOGGLED, ROW_DELETED, ROWS_REORDERED, LAST_SIGNAL }; static guint tree_model_signals[LAST_SIGNAL] = { 0 }; /** * GtkTreePath: * * An opaque structure representing a path to a row in a model. */ struct _GtkTreePath { int depth; /* Number of elements */ int alloc; /* Number of allocated elements */ int *indices; }; typedef struct { GSList *list; } RowRefList; static void gtk_tree_model_base_init (gpointer g_class); /* custom closures */ static void row_inserted_marshal (GClosure *closure, GValue /* out */ *return_value, guint n_param_value, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data); static void row_deleted_marshal (GClosure *closure, GValue /* out */ *return_value, guint n_param_value, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data); static void rows_reordered_marshal (GClosure *closure, GValue /* out */ *return_value, guint n_param_value, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data); static void gtk_tree_row_ref_inserted (RowRefList *refs, GtkTreePath *path, GtkTreeIter *iter); static void gtk_tree_row_ref_deleted (RowRefList *refs, GtkTreePath *path); static void gtk_tree_row_ref_reordered (RowRefList *refs, GtkTreePath *path, GtkTreeIter *iter, int *new_order); GType gtk_tree_model_get_type (void) { static GType tree_model_type = 0; if (! tree_model_type) { const GTypeInfo tree_model_info = { sizeof (GtkTreeModelIface), /* class_size */ gtk_tree_model_base_init, /* base_init */ NULL, /* base_finalize */ NULL, NULL, /* class_finalize */ NULL, /* class_data */ 0, 0, /* n_preallocs */ NULL }; tree_model_type = g_type_register_static (G_TYPE_INTERFACE, I_("GtkTreeModel"), &tree_model_info, 0); g_type_interface_add_prerequisite (tree_model_type, G_TYPE_OBJECT); } return tree_model_type; } static void gtk_tree_model_base_init (gpointer g_class) { static gboolean initialized = FALSE; GClosure *closure; if (! initialized) { GType row_inserted_params[2]; GType row_deleted_params[1]; GType rows_reordered_params[3]; row_inserted_params[0] = GTK_TYPE_TREE_PATH | G_SIGNAL_TYPE_STATIC_SCOPE; row_inserted_params[1] = GTK_TYPE_TREE_ITER; row_deleted_params[0] = GTK_TYPE_TREE_PATH | G_SIGNAL_TYPE_STATIC_SCOPE; rows_reordered_params[0] = GTK_TYPE_TREE_PATH | G_SIGNAL_TYPE_STATIC_SCOPE; rows_reordered_params[1] = GTK_TYPE_TREE_ITER; rows_reordered_params[2] = G_TYPE_POINTER; /** * GtkTreeModel::row-changed: * @tree_model: the `GtkTreeModel` on which the signal is emitted * @path: a `GtkTreePath` identifying the changed row * @iter: a valid `GtkTreeIter` pointing to the changed row * * This signal is emitted when a row in the model has changed. */ tree_model_signals[ROW_CHANGED] = g_signal_new (I_("row-changed"), GTK_TYPE_TREE_MODEL, G_SIGNAL_RUN_LAST, G_STRUCT_OFFSET (GtkTreeModelIface, row_changed), NULL, NULL, _gtk_marshal_VOID__BOXED_BOXED, G_TYPE_NONE, 2, GTK_TYPE_TREE_PATH | G_SIGNAL_TYPE_STATIC_SCOPE, GTK_TYPE_TREE_ITER); g_signal_set_va_marshaller (tree_model_signals[ROW_CHANGED], G_TYPE_FROM_CLASS (g_class), _gtk_marshal_VOID__BOXED_BOXEDv); /* We need to get notification about structure changes * to update row references., so instead of using the * standard g_signal_new() with an offset into our interface * structure, we use a customs closures for the class * closures (default handlers) that first update row references * and then calls the function from the interface structure. * * The reason we don't simply update the row references from * the wrapper functions (gtk_tree_model_row_inserted(), etc.) * is to keep proper ordering with respect to signal handlers * connected normally and after. */ /** * GtkTreeModel::row-inserted: * @tree_model: the `GtkTreeModel` on which the signal is emitted * @path: a `GtkTreePath` identifying the new row * @iter: a valid `GtkTreeIter` pointing to the new row * * 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. */ closure = g_closure_new_simple (sizeof (GClosure), NULL); g_closure_set_marshal (closure, row_inserted_marshal); tree_model_signals[ROW_INSERTED] = g_signal_newv (I_("row-inserted"), GTK_TYPE_TREE_MODEL, G_SIGNAL_RUN_FIRST, closure, NULL, NULL, _gtk_marshal_VOID__BOXED_BOXED, G_TYPE_NONE, 2, row_inserted_params); g_signal_set_va_marshaller (tree_model_signals[ROW_INSERTED], G_TYPE_FROM_CLASS (g_class), _gtk_marshal_VOID__BOXED_BOXEDv); /** * GtkTreeModel::row-has-child-toggled: * @tree_model: the `GtkTreeModel` on which the signal is emitted * @path: a `GtkTreePath` identifying the row * @iter: a valid `GtkTreeIter` pointing to the row * * This signal is emitted when a row has gotten the first child * row or lost its last child row. */ tree_model_signals[ROW_HAS_CHILD_TOGGLED] = g_signal_new (I_("row-has-child-toggled"), GTK_TYPE_TREE_MODEL, G_SIGNAL_RUN_LAST, G_STRUCT_OFFSET (GtkTreeModelIface, row_has_child_toggled), NULL, NULL, _gtk_marshal_VOID__BOXED_BOXED, G_TYPE_NONE, 2, GTK_TYPE_TREE_PATH | G_SIGNAL_TYPE_STATIC_SCOPE, GTK_TYPE_TREE_ITER); g_signal_set_va_marshaller (tree_model_signals[ROW_HAS_CHILD_TOGGLED], G_TYPE_FROM_CLASS (g_class), _gtk_marshal_VOID__BOXED_BOXEDv); /** * GtkTreeModel::row-deleted: * @tree_model: the `GtkTreeModel` on which the signal is emitted * @path: a `GtkTreePath` identifying the row * * 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. */ closure = g_closure_new_simple (sizeof (GClosure), NULL); g_closure_set_marshal (closure, row_deleted_marshal); tree_model_signals[ROW_DELETED] = g_signal_newv (I_("row-deleted"), GTK_TYPE_TREE_MODEL, G_SIGNAL_RUN_FIRST, closure, NULL, NULL, NULL, G_TYPE_NONE, 1, row_deleted_params); /** * GtkTreeModel::rows-reordered: (skip) * @tree_model: the `GtkTreeModel` on which the signal is emitted * @path: a `GtkTreePath` identifying the tree node whose children * have been reordered * @iter: a valid `GtkTreeIter` pointing to the node whose children * have been reordered, or %NULL if the depth of @path is 0 * @new_order: an array of integers mapping the current position * of each child to its old position before the re-ordering, * i.e. @new_order`[newpos] = oldpos` * * This signal is emitted when the children of a node in the * `GtkTreeModel` have been reordered. * * Note that this signal is not emitted * when rows are reordered by DND, since this is implemented * by removing and then reinserting the row. */ closure = g_closure_new_simple (sizeof (GClosure), NULL); g_closure_set_marshal (closure, rows_reordered_marshal); tree_model_signals[ROWS_REORDERED] = g_signal_newv (I_("rows-reordered"), GTK_TYPE_TREE_MODEL, G_SIGNAL_RUN_FIRST, closure, NULL, NULL, _gtk_marshal_VOID__BOXED_BOXED_POINTER, G_TYPE_NONE, 3, rows_reordered_params); g_signal_set_va_marshaller (tree_model_signals[ROWS_REORDERED], G_TYPE_FROM_CLASS (g_class), _gtk_marshal_VOID__BOXED_BOXED_POINTERv); initialized = TRUE; } } static void row_inserted_marshal (GClosure *closure, GValue /* out */ *return_value, guint n_param_values, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data) { GtkTreeModelIface *iface; void (* row_inserted_callback) (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter) = NULL; GObject *model = g_value_get_object (param_values + 0); GtkTreePath *path = (GtkTreePath *)g_value_get_boxed (param_values + 1); GtkTreeIter *iter = (GtkTreeIter *)g_value_get_boxed (param_values + 2); /* first, we need to update internal row references */ gtk_tree_row_ref_inserted ((RowRefList *)g_object_get_data (model, ROW_REF_DATA_STRING), path, iter); /* fetch the interface ->row_inserted implementation */ iface = GTK_TREE_MODEL_GET_IFACE (model); row_inserted_callback = G_STRUCT_MEMBER (gpointer, iface, G_STRUCT_OFFSET (GtkTreeModelIface, row_inserted)); /* Call that default signal handler, it if has been set */ if (row_inserted_callback) row_inserted_callback (GTK_TREE_MODEL (model), path, iter); } static void row_deleted_marshal (GClosure *closure, GValue /* out */ *return_value, guint n_param_values, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data) { GtkTreeModelIface *iface; void (* row_deleted_callback) (GtkTreeModel *tree_model, GtkTreePath *path) = NULL; GObject *model = g_value_get_object (param_values + 0); GtkTreePath *path = (GtkTreePath *)g_value_get_boxed (param_values + 1); /* first, we need to update internal row references */ gtk_tree_row_ref_deleted ((RowRefList *)g_object_get_data (model, ROW_REF_DATA_STRING), path); /* fetch the interface ->row_deleted implementation */ iface = GTK_TREE_MODEL_GET_IFACE (model); row_deleted_callback = G_STRUCT_MEMBER (gpointer, iface, G_STRUCT_OFFSET (GtkTreeModelIface, row_deleted)); /* Call that default signal handler, it if has been set */ if (row_deleted_callback) row_deleted_callback (GTK_TREE_MODEL (model), path); } static void rows_reordered_marshal (GClosure *closure, GValue /* out */ *return_value, guint n_param_values, const GValue *param_values, gpointer invocation_hint, gpointer marshal_data) { GtkTreeModelIface *iface; void (* rows_reordered_callback) (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter, int *new_order); GObject *model = g_value_get_object (param_values + 0); GtkTreePath *path = (GtkTreePath *)g_value_get_boxed (param_values + 1); GtkTreeIter *iter = (GtkTreeIter *)g_value_get_boxed (param_values + 2); int *new_order = (int *)g_value_get_pointer (param_values + 3); /* first, we need to update internal row references */ gtk_tree_row_ref_reordered ((RowRefList *)g_object_get_data (model, ROW_REF_DATA_STRING), path, iter, new_order); /* fetch the interface ->rows_reordered implementation */ iface = GTK_TREE_MODEL_GET_IFACE (model); rows_reordered_callback = G_STRUCT_MEMBER (gpointer, iface, G_STRUCT_OFFSET (GtkTreeModelIface, rows_reordered)); /* Call that default signal handler, it if has been set */ if (rows_reordered_callback) rows_reordered_callback (GTK_TREE_MODEL (model), path, iter, new_order); } /** * gtk_tree_path_new: * * Creates a new `GtkTreePath` * This refers to a row. * * Returns: A newly created `GtkTreePath`. */ GtkTreePath * gtk_tree_path_new (void) { GtkTreePath *retval; retval = g_slice_new (GtkTreePath); retval->depth = 0; retval->alloc = 0; retval->indices = NULL; return retval; } /** * gtk_tree_path_new_from_string: * @path: The string representation of a path * * Creates a new `GtkTreePath` initialized to @path. * * @path is expected to be a colon separated list of numbers. * For example, the string “10:4:0” would create a path of depth * 3 pointing to the 11th child of the root node, the 5th * child of that 11th child, and the 1st child of that 5th child. * If an invalid path string is passed in, %NULL is returned. * * Returns: (nullable): A newly-created `GtkTreePath` */ GtkTreePath * gtk_tree_path_new_from_string (const char *path) { GtkTreePath *retval; const char *orig_path = path; char *ptr; int i; g_return_val_if_fail (path != NULL, NULL); g_return_val_if_fail (*path != '\000', NULL); retval = gtk_tree_path_new (); while (1) { i = strtol (path, &ptr, 10); if (i < 0) { g_warning (G_STRLOC ": Negative numbers in path %s passed to gtk_tree_path_new_from_string", orig_path); gtk_tree_path_free (retval); return NULL; } gtk_tree_path_append_index (retval, i); if (*ptr == '\000') break; if (ptr == path || *ptr != ':') { g_warning (G_STRLOC ": Invalid path %s passed to gtk_tree_path_new_from_string", orig_path); gtk_tree_path_free (retval); return NULL; } path = ptr + 1; } return retval; } /** * gtk_tree_path_new_from_indices: * @first_index: first integer * @...: list of integers terminated by -1 * * Creates a new path with @first_index and @varargs as indices. * * Returns: A newly created `GtkTreePath` */ GtkTreePath * gtk_tree_path_new_from_indices (int first_index, ...) { int arg; va_list args; GtkTreePath *path; path = gtk_tree_path_new (); va_start (args, first_index); arg = first_index; while (arg != -1) { gtk_tree_path_append_index (path, arg); arg = va_arg (args, int); } va_end (args); return path; } /** * gtk_tree_path_new_from_indicesv: (rename-to gtk_tree_path_new_from_indices) * @indices: (array length=length): array of indices * @length: length of @indices array * * Creates a new path with the given @indices array of @length. * * Returns: A newly created `GtkTreePath` */ GtkTreePath * gtk_tree_path_new_from_indicesv (int *indices, gsize length) { GtkTreePath *path; g_return_val_if_fail (indices != NULL && length != 0, NULL); path = gtk_tree_path_new (); path->alloc = length; path->depth = length; path->indices = g_new (int, length); memcpy (path->indices, indices, length * sizeof (int)); return path; } /** * gtk_tree_path_to_string: * @path: a `GtkTreePath` * * Generates a string representation of the path. * * This string is a “:” separated list of numbers. * For example, “4:10:0:3” would be an acceptable * return value for this string. If the path has * depth 0, %NULL is returned. * * Returns: (nullable): A newly-allocated string */ char * gtk_tree_path_to_string (GtkTreePath *path) { char *retval, *ptr, *end; int i, n; g_return_val_if_fail (path != NULL, NULL); if (path->depth == 0) return NULL; n = path->depth * 12; ptr = retval = g_new0 (char, n); end = ptr + n; g_snprintf (retval, end - ptr, "%d", path->indices[0]); while (*ptr != '\000') ptr++; for (i = 1; i < path->depth; i++) { g_snprintf (ptr, end - ptr, ":%d", path->indices[i]); while (*ptr != '\000') ptr++; } return retval; } /** * gtk_tree_path_new_first: * * Creates a new `GtkTreePath`. * * The string representation of this path is “0”. * * Returns: A new `GtkTreePath` */ GtkTreePath * gtk_tree_path_new_first (void) { GtkTreePath *retval; retval = gtk_tree_path_new (); gtk_tree_path_append_index (retval, 0); return retval; } /** * gtk_tree_path_append_index: * @path: a `GtkTreePath` * @index_: the index * * Appends a new index to a path. * * As a result, the depth of the path is increased. */ void gtk_tree_path_append_index (GtkTreePath *path, int index_) { g_return_if_fail (path != NULL); g_return_if_fail (index_ >= 0); if (path->depth == path->alloc) { path->alloc = MAX (path->alloc * 2, 1); path->indices = g_renew (int, path->indices, path->alloc); } path->depth += 1; path->indices[path->depth - 1] = index_; } /** * gtk_tree_path_prepend_index: * @path: a `GtkTreePath` * @index_: the index * * Prepends a new index to a path. * * As a result, the depth of the path is increased. */ void gtk_tree_path_prepend_index (GtkTreePath *path, int index) { if (path->depth == path->alloc) { int *indices; path->alloc = MAX (path->alloc * 2, 1); indices = g_new (int, path->alloc); memcpy (indices + 1, path->indices, path->depth * sizeof (int)); g_free (path->indices); path->indices = indices; } else if (path->depth > 0) memmove (path->indices + 1, path->indices, path->depth * sizeof (int)); path->depth += 1; path->indices[0] = index; } /** * gtk_tree_path_get_depth: * @path: a `GtkTreePath` * * Returns the current depth of @path. * * Returns: The depth of @path */ int gtk_tree_path_get_depth (GtkTreePath *path) { g_return_val_if_fail (path != NULL, 0); return path->depth; } /** * gtk_tree_path_get_indices: (skip) * @path: a `GtkTreePath` * * Returns the current indices of @path. * * This is an array of integers, each representing a node in a tree. * This value should not be freed. * * The length of the array can be obtained with gtk_tree_path_get_depth(). * * Returns: (nullable) (transfer none): The current indices */ int * gtk_tree_path_get_indices (GtkTreePath *path) { g_return_val_if_fail (path != NULL, NULL); return path->indices; } /** * gtk_tree_path_get_indices_with_depth: (rename-to gtk_tree_path_get_indices) * @path: a `GtkTreePath` * @depth: (out) (optional): return location for number of elements * returned in the integer array * * Returns the current indices of @path. * * This is an array of integers, each representing a node in a tree. * It also returns the number of elements in the array. * The array should not be freed. * * Returns: (array length=depth) (transfer none) (nullable): The current * indices */ int * gtk_tree_path_get_indices_with_depth (GtkTreePath *path, int *depth) { g_return_val_if_fail (path != NULL, NULL); if (depth) *depth = path->depth; return path->indices; } /** * gtk_tree_path_free: * @path: (nullable): a `GtkTreePath` * * Frees @path. If @path is %NULL, it simply returns. */ void gtk_tree_path_free (GtkTreePath *path) { if (!path) return; g_free (path->indices); g_slice_free (GtkTreePath, path); } /** * gtk_tree_path_copy: * @path: a `GtkTreePath` * * Creates a new `GtkTreePath` as a copy of @path. * * Returns: a new `GtkTreePath` */ GtkTreePath * gtk_tree_path_copy (const GtkTreePath *path) { GtkTreePath *retval; g_return_val_if_fail (path != NULL, NULL); retval = g_slice_new (GtkTreePath); retval->depth = path->depth; retval->alloc = retval->depth; retval->indices = g_new (int, path->alloc); memcpy (retval->indices, path->indices, path->depth * sizeof (int)); return retval; } G_DEFINE_BOXED_TYPE (GtkTreePath, gtk_tree_path, gtk_tree_path_copy, gtk_tree_path_free) /** * gtk_tree_path_compare: * @a: a `GtkTreePath` * @b: a `GtkTreePath` to compare with * * Compares two paths. * * If @a appears before @b in a tree, then -1 is returned. * If @b appears before @a, then 1 is returned. * If the two nodes are equal, then 0 is returned. * * Returns: the relative positions of @a and @b */ int gtk_tree_path_compare (const GtkTreePath *a, const GtkTreePath *b) { int p = 0, q = 0; g_return_val_if_fail (a != NULL, 0); g_return_val_if_fail (b != NULL, 0); g_return_val_if_fail (a->depth > 0, 0); g_return_val_if_fail (b->depth > 0, 0); do { if (a->indices[p] == b->indices[q]) continue; return (a->indices[p] < b->indices[q]?-1:1); } while (++p < a->depth && ++q < b->depth); if (a->depth == b->depth) return 0; return (a->depth < b->depth?-1:1); } /** * gtk_tree_path_is_ancestor: * @path: a `GtkTreePath` * @descendant: another `GtkTreePath` * * Returns %TRUE if @descendant is a descendant of @path. * * Returns: %TRUE if @descendant is contained inside @path */ gboolean gtk_tree_path_is_ancestor (GtkTreePath *path, GtkTreePath *descendant) { int i; g_return_val_if_fail (path != NULL, FALSE); g_return_val_if_fail (descendant != NULL, FALSE); /* can't be an ancestor if we're deeper */ if (path->depth >= descendant->depth) return FALSE; i = 0; while (i < path->depth) { if (path->indices[i] != descendant->indices[i]) return FALSE; ++i; } return TRUE; } /** * gtk_tree_path_is_descendant: * @path: a `GtkTreePath` * @ancestor: another `GtkTreePath` * * Returns %TRUE if @path is a descendant of @ancestor. * * Returns: %TRUE if @ancestor contains @path somewhere below it */ gboolean gtk_tree_path_is_descendant (GtkTreePath *path, GtkTreePath *ancestor) { int i; g_return_val_if_fail (path != NULL, FALSE); g_return_val_if_fail (ancestor != NULL, FALSE); /* can't be a descendant if we're shallower in the tree */ if (path->depth <= ancestor->depth) return FALSE; i = 0; while (i < ancestor->depth) { if (path->indices[i] != ancestor->indices[i]) return FALSE; ++i; } return TRUE; } /** * gtk_tree_path_next: * @path: a `GtkTreePath` * * Moves the @path to point to the next node at the current depth. */ void gtk_tree_path_next (GtkTreePath *path) { g_return_if_fail (path != NULL); g_return_if_fail (path->depth > 0); path->indices[path->depth - 1] ++; } /** * gtk_tree_path_prev: * @path: a `GtkTreePath` * * Moves the @path to point to the previous node at the * current depth, if it exists. * * Returns: %TRUE if @path has a previous node, and * the move was made */ gboolean gtk_tree_path_prev (GtkTreePath *path) { g_return_val_if_fail (path != NULL, FALSE); if (path->depth == 0) return FALSE; if (path->indices[path->depth - 1] == 0) return FALSE; path->indices[path->depth - 1] -= 1; return TRUE; } /** * gtk_tree_path_up: * @path: a `GtkTreePath` * * Moves the @path to point to its parent node, if it has a parent. * * Returns: %TRUE if @path has a parent, and the move was made */ gboolean gtk_tree_path_up (GtkTreePath *path) { g_return_val_if_fail (path != NULL, FALSE); if (path->depth == 0) return FALSE; path->depth--; return TRUE; } /** * gtk_tree_path_down: * @path: a `GtkTreePath` * * Moves @path to point to the first child of the current path. */ void gtk_tree_path_down (GtkTreePath *path) { g_return_if_fail (path != NULL); gtk_tree_path_append_index (path, 0); } /** * gtk_tree_iter_copy: * @iter: a `GtkTreeIter` * * Creates a dynamically allocated tree iterator as a copy of @iter. * * This function is not intended for use in applications, * because you can just copy the structs by value * (`GtkTreeIter new_iter = iter;`). * You must free this iter with gtk_tree_iter_free(). * * Returns: a newly-allocated copy of @iter */ GtkTreeIter * gtk_tree_iter_copy (GtkTreeIter *iter) { GtkTreeIter *retval; g_return_val_if_fail (iter != NULL, NULL); retval = g_slice_new (GtkTreeIter); *retval = *iter; return retval; } /** * gtk_tree_iter_free: * @iter: a dynamically allocated tree iterator * * Frees an iterator that has been allocated by gtk_tree_iter_copy(). * * This function is mainly used for language bindings. */ void gtk_tree_iter_free (GtkTreeIter *iter) { g_return_if_fail (iter != NULL); g_slice_free (GtkTreeIter, iter); } G_DEFINE_BOXED_TYPE (GtkTreeIter, gtk_tree_iter, gtk_tree_iter_copy, gtk_tree_iter_free) /** * gtk_tree_model_get_flags: * @tree_model: a `GtkTreeModel` * * Returns a set of flags supported by this interface. * * The flags are a bitwise combination of `GtkTreeModel`Flags. * The flags supported should not change during the lifetime * of the @tree_model. * * Returns: the flags supported by this interface */ GtkTreeModelFlags gtk_tree_model_get_flags (GtkTreeModel *tree_model) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), 0); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); if (iface->get_flags) return (* iface->get_flags) (tree_model); return 0; } /** * gtk_tree_model_get_n_columns: * @tree_model: a `GtkTreeModel` * * Returns the number of columns supported by @tree_model. * * Returns: the number of columns */ int gtk_tree_model_get_n_columns (GtkTreeModel *tree_model) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), 0); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->get_n_columns != NULL, 0); return (* iface->get_n_columns) (tree_model); } /** * gtk_tree_model_get_column_type: * @tree_model: a `GtkTreeModel` * @index_: the column index * * Returns the type of the column. * * Returns: the type of the column */ GType gtk_tree_model_get_column_type (GtkTreeModel *tree_model, int index) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), G_TYPE_INVALID); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->get_column_type != NULL, G_TYPE_INVALID); g_return_val_if_fail (index >= 0, G_TYPE_INVALID); return (* iface->get_column_type) (tree_model, index); } /** * gtk_tree_model_get_iter: * @tree_model: a `GtkTreeModel` * @iter: (out): the uninitialized `GtkTreeIter` * @path: the `GtkTreePath` * * 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. * * Returns: %TRUE, if @iter was set */ gboolean gtk_tree_model_get_iter (GtkTreeModel *tree_model, GtkTreeIter *iter, GtkTreePath *path) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); g_return_val_if_fail (path != NULL, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->get_iter != NULL, FALSE); g_return_val_if_fail (path->depth > 0, FALSE); INITIALIZE_TREE_ITER (iter); return (* iface->get_iter) (tree_model, iter, path); } /** * gtk_tree_model_get_iter_from_string: * @tree_model: a `GtkTreeModel` * @iter: (out): an uninitialized `GtkTreeIter` * @path_string: a string representation of a `GtkTreePath` * * Sets @iter to a valid iterator pointing to @path_string, if it * exists. * * Otherwise, @iter is left invalid and %FALSE is returned. * * Returns: %TRUE, if @iter was set */ gboolean gtk_tree_model_get_iter_from_string (GtkTreeModel *tree_model, GtkTreeIter *iter, const char *path_string) { gboolean retval; GtkTreePath *path; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); g_return_val_if_fail (path_string != NULL, FALSE); path = gtk_tree_path_new_from_string (path_string); g_return_val_if_fail (path != NULL, FALSE); retval = gtk_tree_model_get_iter (tree_model, iter, path); gtk_tree_path_free (path); return retval; } /** * gtk_tree_model_get_string_from_iter: * @tree_model: a `GtkTreeModel` * @iter: a `GtkTreeIter` * * 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. * * Returns: (nullable): a newly-allocated string */ char * gtk_tree_model_get_string_from_iter (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreePath *path; char *ret; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), NULL); g_return_val_if_fail (iter != NULL, NULL); path = gtk_tree_model_get_path (tree_model, iter); g_return_val_if_fail (path != NULL, NULL); ret = gtk_tree_path_to_string (path); gtk_tree_path_free (path); return ret; } /** * gtk_tree_model_get_iter_first: * @tree_model: a `GtkTreeModel` * @iter: (out): the uninitialized `GtkTreeIter` * * 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 */ gboolean gtk_tree_model_get_iter_first (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreePath *path; gboolean retval; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); path = gtk_tree_path_new_first (); retval = gtk_tree_model_get_iter (tree_model, iter, path); gtk_tree_path_free (path); return retval; } /** * gtk_tree_model_get_path: * @tree_model: a `GtkTreeModel` * @iter: the `GtkTreeIter` * * Returns a newly-created `GtkTreePath` referenced by @iter. * * This path should be freed with gtk_tree_path_free(). * * Returns: a newly-created `GtkTreePath` */ GtkTreePath * gtk_tree_model_get_path (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), NULL); g_return_val_if_fail (iter != NULL, NULL); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->get_path != NULL, NULL); return (* iface->get_path) (tree_model, iter); } /** * gtk_tree_model_get_value: * @tree_model: a `GtkTreeModel` * @iter: the `GtkTreeIter` * @column: the column to lookup the value at * @value: (out) (transfer none): an empty `GValue` to set * * Initializes and sets @value to that at @column. * * When done with @value, g_value_unset() needs to be called * to free any allocated memory. */ void gtk_tree_model_get_value (GtkTreeModel *tree_model, GtkTreeIter *iter, int column, GValue *value) { GtkTreeModelIface *iface; g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (iter != NULL); g_return_if_fail (value != NULL); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_if_fail (iface->get_value != NULL); (* iface->get_value) (tree_model, iter, column, value); } /** * gtk_tree_model_iter_next: * @tree_model: a `GtkTreeModel` * @iter: (in): the `GtkTreeIter` * * 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. * * Returns: %TRUE if @iter has been changed to the next node */ gboolean gtk_tree_model_iter_next (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->iter_next != NULL, FALSE); return (* iface->iter_next) (tree_model, iter); } static gboolean gtk_tree_model_iter_previous_default (GtkTreeModel *tree_model, GtkTreeIter *iter) { gboolean retval; GtkTreePath *path; path = gtk_tree_model_get_path (tree_model, iter); if (path == NULL) return FALSE; retval = gtk_tree_path_prev (path) && gtk_tree_model_get_iter (tree_model, iter, path); if (retval == FALSE) iter->stamp = 0; gtk_tree_path_free (path); return retval; } /** * gtk_tree_model_iter_previous: * @tree_model: a `GtkTreeModel` * @iter: (in): the `GtkTreeIter` * * 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. * * Returns: %TRUE if @iter has been changed to the previous node */ gboolean gtk_tree_model_iter_previous (GtkTreeModel *tree_model, GtkTreeIter *iter) { gboolean retval; GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); if (iface->iter_previous) retval = (* iface->iter_previous) (tree_model, iter); else retval = gtk_tree_model_iter_previous_default (tree_model, iter); return retval; } /** * gtk_tree_model_iter_children: * @tree_model: a `GtkTreeModel` * @iter: (out): the new `GtkTreeIter` to be set to the child * @parent: (nullable): the `GtkTreeIter` * * 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 %NULL returns the first node, equivalent to * `gtk_tree_model_get_iter_first (tree_model, iter);` * * Returns: %TRUE, if @iter has been set to the first child */ gboolean gtk_tree_model_iter_children (GtkTreeModel *tree_model, GtkTreeIter *iter, GtkTreeIter *parent) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->iter_children != NULL, FALSE); INITIALIZE_TREE_ITER (iter); return (* iface->iter_children) (tree_model, iter, parent); } /** * gtk_tree_model_iter_has_child: * @tree_model: a `GtkTreeModel` * @iter: the `GtkTreeIter` to test for children * * Returns %TRUE if @iter has children, %FALSE otherwise. * * Returns: %TRUE if @iter has children */ gboolean gtk_tree_model_iter_has_child (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->iter_has_child != NULL, FALSE); return (* iface->iter_has_child) (tree_model, iter); } /** * gtk_tree_model_iter_n_children: * @tree_model: a `GtkTreeModel` * @iter: (nullable): the `GtkTreeIter` * * Returns the number of children that @iter has. * * As a special case, if @iter is %NULL, then the number * of toplevel nodes is returned. * * Returns: the number of children of @iter */ int gtk_tree_model_iter_n_children (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), 0); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->iter_n_children != NULL, 0); return (* iface->iter_n_children) (tree_model, iter); } /** * gtk_tree_model_iter_nth_child: * @tree_model: a `GtkTreeModel` * @iter: (out): the `GtkTreeIter` to set to the nth child * @parent: (nullable): the `GtkTreeIter` to get the child from * @n: the index of the desired child * * 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 %NULL, then the @n-th root node * is set. * * Returns: %TRUE, if @parent has an @n-th child */ gboolean gtk_tree_model_iter_nth_child (GtkTreeModel *tree_model, GtkTreeIter *iter, GtkTreeIter *parent, int n) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); g_return_val_if_fail (n >= 0, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->iter_nth_child != NULL, FALSE); INITIALIZE_TREE_ITER (iter); return (* iface->iter_nth_child) (tree_model, iter, parent, n); } /** * gtk_tree_model_iter_parent: * @tree_model: a `GtkTreeModel` * @iter: (out): the new `GtkTreeIter` to set to the parent * @child: the `GtkTreeIter` * * 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. * * Returns: %TRUE, if @iter is set to the parent of @child */ gboolean gtk_tree_model_iter_parent (GtkTreeModel *tree_model, GtkTreeIter *iter, GtkTreeIter *child) { GtkTreeModelIface *iface; g_return_val_if_fail (GTK_IS_TREE_MODEL (tree_model), FALSE); g_return_val_if_fail (iter != NULL, FALSE); g_return_val_if_fail (child != NULL, FALSE); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); g_return_val_if_fail (iface->iter_parent != NULL, FALSE); INITIALIZE_TREE_ITER (iter); return (* iface->iter_parent) (tree_model, iter, child); } /** * gtk_tree_model_ref_node: * @tree_model: a `GtkTreeModel` * @iter: the `GtkTreeIter` * * Lets the tree ref the node. * * This is an optional method for models to implement. * To be more specific, models may ignore this call as it exists * primarily for performance reasons. * * This function is primarily meant as a way for views to let * caching models know when nodes are being displayed (and hence, * whether or not to cache that node). Being displayed means a node * is in an expanded branch, regardless of whether the node is currently * visible in the viewport. For example, a file-system based model * would not want to keep the entire file-hierarchy in memory, * just the sections that are currently being displayed by * every current view. * * A model should be expected to be able to get an iter independent * of its reffed state. */ void gtk_tree_model_ref_node (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreeModelIface *iface; g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); if (iface->ref_node) (* iface->ref_node) (tree_model, iter); } /** * gtk_tree_model_unref_node: * @tree_model: a `GtkTreeModel` * @iter: the `GtkTreeIter` * * Lets the tree unref the node. * * This is an optional method for models to implement. * To be more specific, models may ignore this call as it exists * primarily for performance reasons. For more information on what * this means, see gtk_tree_model_ref_node(). * * Please note that nodes that are deleted are not unreffed. */ void gtk_tree_model_unref_node (GtkTreeModel *tree_model, GtkTreeIter *iter) { GtkTreeModelIface *iface; g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (iter != NULL); iface = GTK_TREE_MODEL_GET_IFACE (tree_model); if (iface->unref_node) (* iface->unref_node) (tree_model, iter); } /** * gtk_tree_model_get: * @tree_model: a `GtkTreeModel` * @iter: a row in @tree_model * @...: pairs of column number and value return locations, * terminated by -1 * * Gets the value of one or more cells in the row referenced by @iter. * * The variable argument list should contain integer column numbers, * each column number followed by a place to store the value being * retrieved. The list is terminated by a -1. For example, to get a * value from column 0 with type %G_TYPE_STRING, you would * write: `gtk_tree_model_get (model, iter, 0, &place_string_here, -1)`, * where `place_string_here` is a #gchararray * to be filled with the string. * * Returned values with type %G_TYPE_OBJECT have to be unreferenced, * values with type %G_TYPE_STRING or %G_TYPE_BOXED have to be freed. * Other values are passed by value. */ void gtk_tree_model_get (GtkTreeModel *tree_model, GtkTreeIter *iter, ...) { va_list var_args; g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (iter != NULL); va_start (var_args, iter); gtk_tree_model_get_valist (tree_model, iter, var_args); va_end (var_args); } /** * gtk_tree_model_get_valist: * @tree_model: a `GtkTreeModel` * @iter: a row in @tree_model * @var_args: va_list of column/return location pairs * * Gets the value of one or more cells in the row referenced by @iter. * * See [method@Gtk.TreeModel.get], this version takes a va_list * for language bindings to use. */ void gtk_tree_model_get_valist (GtkTreeModel *tree_model, GtkTreeIter *iter, va_list var_args) { int column; g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (iter != NULL); column = va_arg (var_args, int); while (column != -1) { GValue value = G_VALUE_INIT; char *error = NULL; if (column >= gtk_tree_model_get_n_columns (tree_model)) { g_warning ("%s: Invalid column number %d accessed (remember to end your list of columns with a -1)", G_STRLOC, column); break; } gtk_tree_model_get_value (GTK_TREE_MODEL (tree_model), iter, column, &value); G_VALUE_LCOPY (&value, var_args, 0, &error); if (error) { g_warning ("%s: %s", G_STRLOC, error); g_free (error); /* we purposely leak the value here, it might not be * in a sane state if an error condition occurred */ break; } g_value_unset (&value); column = va_arg (var_args, int); } } /** * gtk_tree_model_row_changed: * @tree_model: a `GtkTreeModel` * @path: a `GtkTreePath` pointing to the changed row * @iter: a valid `GtkTreeIter` pointing to the changed row * * Emits the ::row-changed signal on @tree_model. * * See [signal@Gtk.TreeModel::row-changed]. */ void gtk_tree_model_row_changed (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter) { g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (path != NULL); g_return_if_fail (iter != NULL); g_signal_emit (tree_model, tree_model_signals[ROW_CHANGED], 0, path, iter); } /** * gtk_tree_model_row_inserted: * @tree_model: a `GtkTreeModel` * @path: a `GtkTreePath` pointing to the inserted row * @iter: a valid `GtkTreeIter` pointing to the inserted row * * Emits the ::row-inserted signal on @tree_model. * * See [signal@Gtk.TreeModel::row-inserted]. */ void gtk_tree_model_row_inserted (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter) { g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (path != NULL); g_return_if_fail (iter != NULL); g_signal_emit (tree_model, tree_model_signals[ROW_INSERTED], 0, path, iter); } /** * gtk_tree_model_row_has_child_toggled: * @tree_model: a `GtkTreeModel` * @path: a `GtkTreePath` pointing to the changed row * @iter: a valid `GtkTreeIter` pointing to the changed row * * Emits the ::row-has-child-toggled signal on @tree_model. * * See [signal@Gtk.TreeModel::row-has-child-toggled]. * * This should be called by models after the child * state of a node changes. */ void gtk_tree_model_row_has_child_toggled (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter) { g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (path != NULL); g_return_if_fail (iter != NULL); g_signal_emit (tree_model, tree_model_signals[ROW_HAS_CHILD_TOGGLED], 0, path, iter); } /** * gtk_tree_model_row_deleted: * @tree_model: a `GtkTreeModel` * @path: a `GtkTreePath` pointing to the previous location of * the deleted row * * Emits the ::row-deleted signal on @tree_model. * * See [signal@Gtk.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. */ void gtk_tree_model_row_deleted (GtkTreeModel *tree_model, GtkTreePath *path) { g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (path != NULL); g_signal_emit (tree_model, tree_model_signals[ROW_DELETED], 0, path); } /** * gtk_tree_model_rows_reordered: (skip) * @tree_model: a `GtkTreeModel` * @path: a `GtkTreePath` pointing to the tree node whose children * have been reordered * @iter: a valid `GtkTreeIter` pointing to the node whose children * have been reordered, or %NULL if the depth of @path is 0 * @new_order: an array of integers mapping the current position of * each child to its old position before the re-ordering, * i.e. @new_order`[newpos] = oldpos` * * Emits the ::rows-reordered signal on @tree_model. * * See [signal@Gtk.TreeModel::rows-reordered]. * * This should be called by models when their rows have been * reordered. */ void gtk_tree_model_rows_reordered (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter, int *new_order) { g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (new_order != NULL); g_signal_emit (tree_model, tree_model_signals[ROWS_REORDERED], 0, path, iter, new_order); } /** * gtk_tree_model_rows_reordered_with_length: (rename-to gtk_tree_model_rows_reordered) * @tree_model: a `GtkTreeModel` * @path: a `GtkTreePath` pointing to the tree node whose children * have been reordered * @iter: (nullable): a valid `GtkTreeIter` pointing to the node * whose children have been reordered, or %NULL if the depth * of @path is 0 * @new_order: (array length=length): an array of integers * mapping the current position of each child to its old * position before the re-ordering, * i.e. @new_order`[newpos] = oldpos` * @length: length of @new_order array * * Emits the ::rows-reordered signal on @tree_model. * * See [signal@Gtk.TreeModel::rows-reordered]. * * This should be called by models when their rows have been * reordered. */ void gtk_tree_model_rows_reordered_with_length (GtkTreeModel *tree_model, GtkTreePath *path, GtkTreeIter *iter, int *new_order, int length) { g_return_if_fail (GTK_IS_TREE_MODEL (tree_model)); g_return_if_fail (new_order != NULL); g_return_if_fail (length == gtk_tree_model_iter_n_children (tree_model, iter)); g_signal_emit (tree_model, tree_model_signals[ROWS_REORDERED], 0, path, iter, new_order); } static gboolean gtk_tree_model_foreach_helper (GtkTreeModel *model, GtkTreeIter *iter, GtkTreePath *path, GtkTreeModelForeachFunc func, gpointer user_data) { gboolean iters_persist; iters_persist = gtk_tree_model_get_flags (model) & GTK_TREE_MODEL_ITERS_PERSIST; do { GtkTreeIter child; if ((* func) (model, path, iter, user_data)) return TRUE; if (!iters_persist) { if (!gtk_tree_model_get_iter (model, iter, path)) return TRUE; } if (gtk_tree_model_iter_children (model, &child, iter)) { gtk_tree_path_down (path); if (gtk_tree_model_foreach_helper (model, &child, path, func, user_data)) return TRUE; gtk_tree_path_up (path); } gtk_tree_path_next (path); } while (gtk_tree_model_iter_next (model, iter)); return FALSE; } /** * gtk_tree_model_foreach: * @model: a `GtkTreeModel` * @func: (scope call): a function to be called on each row * @user_data: (closure): user data to passed to @func * * 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. */ void gtk_tree_model_foreach (GtkTreeModel *model, GtkTreeModelForeachFunc func, gpointer user_data) { GtkTreePath *path; GtkTreeIter iter; g_return_if_fail (GTK_IS_TREE_MODEL (model)); g_return_if_fail (func != NULL); path = gtk_tree_path_new_first (); if (!gtk_tree_model_get_iter (model, &iter, path)) { gtk_tree_path_free (path); return; } gtk_tree_model_foreach_helper (model, &iter, path, func, user_data); gtk_tree_path_free (path); } /* * GtkTreeRowReference */ static void gtk_tree_row_reference_unref_path (GtkTreePath *path, GtkTreeModel *model, int depth); G_DEFINE_BOXED_TYPE (GtkTreeRowReference, gtk_tree_row_reference, gtk_tree_row_reference_copy, gtk_tree_row_reference_free) struct _GtkTreeRowReference { GObject *proxy; GtkTreeModel *model; GtkTreePath *path; }; static void release_row_references (gpointer data) { RowRefList *refs = data; GSList *tmp_list = NULL; tmp_list = refs->list; while (tmp_list != NULL) { GtkTreeRowReference *reference = tmp_list->data; if (reference->proxy == (GObject *)reference->model) reference->model = NULL; reference->proxy = NULL; /* we don't free the reference, users are responsible for that. */ tmp_list = tmp_list->next; } g_slist_free (refs->list); g_free (refs); } static void gtk_tree_row_ref_inserted (RowRefList *refs, GtkTreePath *path, GtkTreeIter *iter) { GSList *tmp_list; if (refs == NULL) return; /* This function corrects the path stored in the reference to * account for an insertion. Note that it's called _after_ the * insertion with the path to the newly-inserted row. Which means * that the inserted path is in a different "coordinate system" than * the old path (e.g. if the inserted path was just before the old * path, then inserted path and old path will be the same, and old * path must be moved down one). */ tmp_list = refs->list; while (tmp_list != NULL) { GtkTreeRowReference *reference = tmp_list->data; if (reference->path == NULL) goto done; if (reference->path->depth >= path->depth) { int i; gboolean ancestor = TRUE; for (i = 0; i < path->depth - 1; i ++) { if (path->indices[i] != reference->path->indices[i]) { ancestor = FALSE; break; } } if (ancestor == FALSE) goto done; if (path->indices[path->depth-1] <= reference->path->indices[path->depth-1]) reference->path->indices[path->depth-1] += 1; } done: tmp_list = tmp_list->next; } } static void gtk_tree_row_ref_deleted (RowRefList *refs, GtkTreePath *path) { GSList *tmp_list; if (refs == NULL) return; /* This function corrects the path stored in the reference to * account for a deletion. Note that it's called _after_ the * deletion with the old path of the just-deleted row. Which means * that the deleted path is the same now-defunct "coordinate system" * as the path saved in the reference, which is what we want to fix. */ tmp_list = refs->list; while (tmp_list != NULL) { GtkTreeRowReference *reference = tmp_list->data; if (reference->path) { int i; if (path->depth > reference->path->depth) goto next; for (i = 0; i < path->depth - 1; i++) { if (path->indices[i] != reference->path->indices[i]) goto next; } /* We know it affects us. */ if (path->indices[i] == reference->path->indices[i]) { if (reference->path->depth > path->depth) /* some parent was deleted, trying to unref any node * between the deleted parent and the node the reference * is pointing to is bad, as those nodes are already gone. */ gtk_tree_row_reference_unref_path (reference->path, reference->model, path->depth - 1); else gtk_tree_row_reference_unref_path (reference->path, reference->model, reference->path->depth - 1); gtk_tree_path_free (reference->path); reference->path = NULL; } else if (path->indices[i] < reference->path->indices[i]) { reference->path->indices[path->depth-1]-=1; } } next: tmp_list = tmp_list->next; } } static void gtk_tree_row_ref_reordered (RowRefList *refs, GtkTreePath *path, GtkTreeIter *iter, int *new_order) { GSList *tmp_list; int length; if (refs == NULL) return; tmp_list = refs->list; while (tmp_list != NULL) { GtkTreeRowReference *reference = tmp_list->data; length = gtk_tree_model_iter_n_children (GTK_TREE_MODEL (reference->model), iter); if (length < 2) return; if ((reference->path) && (gtk_tree_path_is_ancestor (path, reference->path))) { int ref_depth = gtk_tree_path_get_depth (reference->path); int depth = gtk_tree_path_get_depth (path); if (ref_depth > depth) { int i; int *indices = gtk_tree_path_get_indices (reference->path); for (i = 0; i < length; i++) { if (new_order[i] == indices[depth]) { indices[depth] = i; break; } } } } tmp_list = tmp_list->next; } } /* We do this recursively so that we can unref children nodes * before their parent */ static void gtk_tree_row_reference_unref_path_helper (GtkTreePath *path, GtkTreeModel *model, GtkTreeIter *parent_iter, int depth, int current_depth) { GtkTreeIter iter; if (depth == current_depth) return; gtk_tree_model_iter_nth_child (model, &iter, parent_iter, path->indices[current_depth]); gtk_tree_row_reference_unref_path_helper (path, model, &iter, depth, current_depth + 1); gtk_tree_model_unref_node (model, &iter); } static void gtk_tree_row_reference_unref_path (GtkTreePath *path, GtkTreeModel *model, int depth) { GtkTreeIter iter; if (depth <= 0) return; gtk_tree_model_iter_nth_child (model, &iter, NULL, path->indices[0]); gtk_tree_row_reference_unref_path_helper (path, model, &iter, depth, 1); gtk_tree_model_unref_node (model, &iter); } /** * gtk_tree_row_reference_new: * @model: a `GtkTreeModel` * @path: a valid `GtkTreePath` to monitor * * Creates a row reference based on @path. * * This reference will keep pointing to the node pointed to * by @path, so long as it exists. Any changes that occur on @model are * propagated, and the path is updated appropriately. If * @path isn’t a valid path in @model, then %NULL is returned. * * Returns: (nullable): a newly allocated `GtkTreeRowReference` */ GtkTreeRowReference * gtk_tree_row_reference_new (GtkTreeModel *model, GtkTreePath *path) { g_return_val_if_fail (GTK_IS_TREE_MODEL (model), NULL); g_return_val_if_fail (path != NULL, NULL); /* We use the model itself as the proxy object; and call * gtk_tree_row_reference_inserted(), etc, in the * class closure (default handler) marshalers for the signal. */ return gtk_tree_row_reference_new_proxy (G_OBJECT (model), model, path); } /** * gtk_tree_row_reference_new_proxy: * @proxy: a proxy `GObject` * @model: a `GtkTreeModel` * @path: a valid `GtkTreePath` to monitor * * You do not need to use this function. * * Creates a row reference based on @path. * * This reference will keep pointing to the node pointed to * by @path, so long as it exists. If @path isn’t a valid * path in @model, then %NULL is returned. However, unlike * references created with gtk_tree_row_reference_new(), it * does not listen to the model for changes. The creator of * the row reference must do this explicitly using * gtk_tree_row_reference_inserted(), gtk_tree_row_reference_deleted(), * gtk_tree_row_reference_reordered(). * * These functions must be called exactly once per proxy when the * corresponding signal on the model is emitted. This single call * updates all row references for that proxy. Since built-in GTK * objects like `GtkTreeView` already use this mechanism internally, * using them as the proxy object will produce unpredictable results. * Further more, passing the same object as @model and @proxy * doesn’t work for reasons of internal implementation. * * This type of row reference is primarily meant by structures that * need to carefully monitor exactly when a row reference updates * itself, and is not generally needed by most applications. * * Returns: (nullable): a newly allocated `GtkTreeRowReference` */ GtkTreeRowReference * gtk_tree_row_reference_new_proxy (GObject *proxy, GtkTreeModel *model, GtkTreePath *path) { GtkTreeRowReference *reference; RowRefList *refs; GtkTreeIter parent_iter; int i; g_return_val_if_fail (G_IS_OBJECT (proxy), NULL); g_return_val_if_fail (GTK_IS_TREE_MODEL (model), NULL); g_return_val_if_fail (path != NULL, NULL); g_return_val_if_fail (path->depth > 0, NULL); /* check that the path is valid */ if (gtk_tree_model_get_iter (model, &parent_iter, path) == FALSE) return NULL; /* Now we want to ref every node */ gtk_tree_model_iter_nth_child (model, &parent_iter, NULL, path->indices[0]); gtk_tree_model_ref_node (model, &parent_iter); for (i = 1; i < path->depth; i++) { GtkTreeIter iter; gtk_tree_model_iter_nth_child (model, &iter, &parent_iter, path->indices[i]); gtk_tree_model_ref_node (model, &iter); parent_iter = iter; } /* Make the row reference */ reference = g_new (GtkTreeRowReference, 1); g_object_ref (proxy); g_object_ref (model); reference->proxy = proxy; reference->model = model; reference->path = gtk_tree_path_copy (path); refs = g_object_get_data (G_OBJECT (proxy), ROW_REF_DATA_STRING); if (refs == NULL) { refs = g_new (RowRefList, 1); refs->list = NULL; g_object_set_data_full (G_OBJECT (proxy), I_(ROW_REF_DATA_STRING), refs, release_row_references); } refs->list = g_slist_prepend (refs->list, reference); return reference; } /** * gtk_tree_row_reference_get_path: * @reference: a `GtkTreeRowReference` * * Returns a path that the row reference currently points to, * or %NULL if the path pointed to is no longer valid. * * Returns: (nullable) (transfer full): a current path */ GtkTreePath * gtk_tree_row_reference_get_path (GtkTreeRowReference *reference) { g_return_val_if_fail (reference != NULL, NULL); if (reference->proxy == NULL) return NULL; if (reference->path == NULL) return NULL; return gtk_tree_path_copy (reference->path); } /** * gtk_tree_row_reference_get_model: * @reference: a `GtkTreeRowReference` * * Returns the model that the row reference is monitoring. * * Returns: (transfer none): the model */ GtkTreeModel * gtk_tree_row_reference_get_model (GtkTreeRowReference *reference) { g_return_val_if_fail (reference != NULL, NULL); return reference->model; } /** * gtk_tree_row_reference_valid: * @reference: (nullable): a `GtkTreeRowReference` * * Returns %TRUE if the @reference is non-%NULL and refers to * a current valid path. * * Returns: %TRUE if @reference points to a valid path */ gboolean gtk_tree_row_reference_valid (GtkTreeRowReference *reference) { if (reference == NULL || reference->path == NULL) return FALSE; return TRUE; } /** * gtk_tree_row_reference_copy: * @reference: a `GtkTreeRowReference` * * Copies a `GtkTreeRowReference`. * * Returns: a copy of @reference */ GtkTreeRowReference * gtk_tree_row_reference_copy (GtkTreeRowReference *reference) { return gtk_tree_row_reference_new_proxy (reference->proxy, reference->model, reference->path); } /** * gtk_tree_row_reference_free: * @reference: (nullable): a `GtkTreeRowReference` * * Free’s @reference. @reference may be %NULL */ void gtk_tree_row_reference_free (GtkTreeRowReference *reference) { RowRefList *refs; if (reference == NULL) return; refs = g_object_get_data (G_OBJECT (reference->proxy), ROW_REF_DATA_STRING); if (refs == NULL) { g_warning (G_STRLOC": bad row reference, proxy has no outstanding row references"); return; } refs->list = g_slist_remove (refs->list, reference); if (refs->list == NULL) { g_object_set_data (G_OBJECT (reference->proxy), I_(ROW_REF_DATA_STRING), NULL); } if (reference->path) { gtk_tree_row_reference_unref_path (reference->path, reference->model, reference->path->depth); gtk_tree_path_free (reference->path); } g_object_unref (reference->proxy); g_object_unref (reference->model); g_free (reference); } /** * gtk_tree_row_reference_inserted: * @proxy: a `GObject` * @path: the row position that was inserted * * Lets a set of row reference created by * gtk_tree_row_reference_new_proxy() know that the * model emitted the ::row-inserted signal. */ void gtk_tree_row_reference_inserted (GObject *proxy, GtkTreePath *path) { g_return_if_fail (G_IS_OBJECT (proxy)); gtk_tree_row_ref_inserted ((RowRefList *)g_object_get_data (proxy, ROW_REF_DATA_STRING), path, NULL); } /** * gtk_tree_row_reference_deleted: * @proxy: a `GObject` * @path: the path position that was deleted * * Lets a set of row reference created by * gtk_tree_row_reference_new_proxy() know that the * model emitted the ::row-deleted signal. */ void gtk_tree_row_reference_deleted (GObject *proxy, GtkTreePath *path) { g_return_if_fail (G_IS_OBJECT (proxy)); gtk_tree_row_ref_deleted ((RowRefList *)g_object_get_data (proxy, ROW_REF_DATA_STRING), path); } /** * gtk_tree_row_reference_reordered: (skip) * @proxy: a `GObject` * @path: the parent path of the reordered signal * @iter: the iter pointing to the parent of the reordered * @new_order: (array): the new order of rows * * Lets a set of row reference created by * gtk_tree_row_reference_new_proxy() know that the * model emitted the ::rows-reordered signal. */ void gtk_tree_row_reference_reordered (GObject *proxy, GtkTreePath *path, GtkTreeIter *iter, int *new_order) { g_return_if_fail (G_IS_OBJECT (proxy)); gtk_tree_row_ref_reordered ((RowRefList *)g_object_get_data (proxy, ROW_REF_DATA_STRING), path, iter, new_order); }