/* -*- Mode: C; tab-width: 8; indent-tabs-mode: t; c-basic-offset: 8 -*- */
/*
* e-tree-model.c: a Tree Model
*
* Author:
* Chris Toshok (toshok@helixcode.com)
*
* Adapted from the gtree code and ETableModel.
*
* (C) 2000 Helix Code, Inc.
*/
#include <config.h>
#include <gtk/gtksignal.h>
#include "e-util/e-util.h"
#include "e-tree-model.h"
#define ETM_CLASS(e) ((ETreeModelClass *)((GtkObject *)e)->klass)
#define PARENT_TYPE E_TABLE_MODEL_TYPE
static ETableModel *e_tree_model_parent_class;
typedef struct {
gboolean expanded;
guint visible_descendents;
gpointer node_data;
} ENode;
enum {
NODE_CHANGED,
NODE_INSERTED,
NODE_REMOVED,
LAST_SIGNAL
};
static guint e_tree_model_signals [LAST_SIGNAL] = {0, };
static void add_visible_descendents_to_array (ETreeModel *etm, GNode *gnode, int *row, int *count);
/* virtual methods */
static void
etree_destroy (GtkObject *object)
{
ETreeModel *etree = E_TREE_MODEL (object);
/* XXX lots of stuff to free here */
g_array_free (etree->row_array, TRUE);
GTK_OBJECT_CLASS (e_tree_model_parent_class)->destroy (object);
}
static ETreePath*
etree_get_root (ETreeModel *etm)
{
return etm->root;
}
static ETreePath*
etree_get_parent (ETreeModel *etm, ETreePath *path)
{
g_return_val_if_fail (path, NULL);
return path->parent;
}
static ETreePath*
etree_get_next (ETreeModel *etm, ETreePath *node)
{
g_return_val_if_fail (node, NULL);
return g_node_next_sibling(node);
}
static ETreePath*
etree_get_prev (ETreeModel *etm, ETreePath *node)
{
g_return_val_if_fail (node, NULL);
return g_node_prev_sibling (node);
}
static guint
etree_get_children (ETreeModel *etm, ETreePath* node, ETreePath ***paths)
{
guint n_children;
g_return_val_if_fail (node, 0);
n_children = g_node_n_children (node);
if (paths) {
int i;
(*paths) = g_malloc (sizeof (ETreePath*) * n_children);
for (i = 0; i < n_children; i ++) {
(*paths)[i] = g_node_nth_child (node, i);
}
}
return n_children;
}
static gboolean
etree_is_expanded (ETreeModel *etm, ETreePath* node)
{
g_return_val_if_fail (node && node->data, FALSE);
return ((ENode*)node->data)->expanded;
}
static gboolean
etree_is_visible (ETreeModel *etm, ETreePath* node)
{
g_return_val_if_fail (node, FALSE);
for (node = node->parent; node; node = node->parent) {
if (!((ENode*)node->data)->expanded)
return FALSE;
}
return TRUE;
}
static void
etree_set_expanded (ETreeModel *etm, ETreePath* node, gboolean expanded)
{
GNode *child;
ENode *enode;
int row;
g_return_if_fail (node && node->data);
enode = ((ENode*)node->data);
if (enode->expanded == expanded)
return;
enode->expanded = expanded;
/* if the node wasn't visible at present */
if ((row = e_tree_model_row_of_node (etm, node)) == -1)
return;
row++;
if (expanded) {
GNode *parent;
if (e_tree_model_node_is_visible (etm, node)) {
enode->visible_descendents = 0;
for (child = g_node_first_child (node); child;
child = g_node_next_sibling (child)) {
add_visible_descendents_to_array (etm, child, &row, &enode->visible_descendents);
}
}
/* now iterate back up the tree, adding to our
ancestors' visible descendents */
for (parent = node->parent; parent; parent = parent->parent) {
ENode *parent_enode = (ENode*)parent->data;
parent_enode->visible_descendents += enode->visible_descendents;
}
}
else {
int i;
GNode *parent;
if (e_tree_model_node_is_visible (etm, node)) {
for (i = 0; i < enode->visible_descendents; i ++) {
etm->row_array = g_array_remove_index (etm->row_array, row);
e_table_model_row_deleted (E_TABLE_MODEL (etm), row);
}
}
/* now iterate back up the tree, subtracting from our
ancestors' visible descendents */
for (parent = node->parent; parent; parent = parent->parent) {
ENode *parent_enode = (ENode*)parent->data;
parent_enode->visible_descendents -= enode->visible_descendents;
}
enode->visible_descendents = 0;
}
}
/* fairly naive implementation */
static void
etree_set_expanded_recurse (ETreeModel *etm, ETreePath* node, gboolean expanded)
{
ETreePath **paths;
guint num_children;
int i;
e_tree_model_node_set_expanded (etm, node, expanded);
num_children = e_tree_model_node_get_children (etm, node, &paths);
if (num_children) {
for (i = 0; i < num_children; i ++) {
e_tree_model_node_set_expanded_recurse (etm, paths[i], expanded);
}
g_free (paths);
}
}
static ETreePath *
etree_node_at_row (ETreeModel *etree, int row)
{
g_return_val_if_fail (row < etree->row_array->len, NULL);
return g_array_index (etree->row_array, GNode*, row);
}
/* ETable analogs */
static void*
etree_value_at (ETreeModel *etm, ETreePath* node, int col)
{
/* shouldn't be called */
g_assert (0);
return NULL;
}
static GdkPixbuf*
etree_icon_at (ETreeModel *etm, ETreePath* node)
{
/* shouldn't be called */
g_assert (0);
return NULL;
}
static void
etree_set_value_at (ETreeModel *etm, ETreePath* node, int col, const void *val)
{
/* shouldn't be called */
g_assert (0);
}
static gboolean
etree_is_editable (ETreeModel *etm, ETreePath* node, int col)
{
/* shouldn't be called */
g_assert(0);
return FALSE;
}
/* ETable virtual functions we map */
static int
etable_row_count (ETableModel *etm)
{
ETreeModel *tree = E_TREE_MODEL (etm);
return tree->row_array->len;
}
static void *
etable_value_at (ETableModel *etm, int col, int row)
{
ETreeModel *etree = E_TREE_MODEL(etm);
ETreeModelClass *et_class = ETM_CLASS(etm);
ETreePath* node = e_tree_model_node_at_row (etree, row);
g_return_val_if_fail (node, NULL);
if (col == -1)
return node;
else if (col == -2)
return etm;
else
return et_class->value_at (etree, node, col);
}
static void
etable_set_value_at (ETableModel *etm, int col, int row, const void *val)
{
ETreeModel *etree = E_TREE_MODEL(etm);
ETreeModelClass *et_class = ETM_CLASS(etm);
ETreePath* node = e_tree_model_node_at_row (etree, row);
g_return_if_fail (node);
et_class->set_value_at (etree, node, col, val);
}
static gboolean
etable_is_cell_editable (ETableModel *etm, int col, int row)
{
ETreeModel *etree = E_TREE_MODEL(etm);
ETreeModelClass *et_class = ETM_CLASS(etm);
ETreePath* node = e_tree_model_node_at_row (etree, row);
g_return_val_if_fail (node, FALSE);
return et_class->is_editable (etree, node, col);
}
static void
e_tree_model_class_init (GtkObjectClass *klass)
{
ETableModelClass *table_class = (ETableModelClass *) klass;
ETreeModelClass *tree_class = (ETreeModelClass *) klass;
e_tree_model_parent_class = gtk_type_class (PARENT_TYPE);
klass->destroy = etree_destroy;
e_tree_model_signals [NODE_CHANGED] =
gtk_signal_new ("node_changed",
GTK_RUN_LAST,
klass->type,
GTK_SIGNAL_OFFSET (ETreeModelClass, node_changed),
gtk_marshal_NONE__POINTER,
GTK_TYPE_NONE, 1, GTK_TYPE_POINTER);
e_tree_model_signals [NODE_INSERTED] =
gtk_signal_new ("node_inserted",
GTK_RUN_LAST,
klass->type,
GTK_SIGNAL_OFFSET (ETreeModelClass, node_inserted),
gtk_marshal_NONE__POINTER_POINTER,
GTK_TYPE_NONE, 2, GTK_TYPE_POINTER, GTK_TYPE_POINTER);
e_tree_model_signals [NODE_REMOVED] =
gtk_signal_new ("node_removed",
GTK_RUN_LAST,
klass->type,
GTK_SIGNAL_OFFSET (ETreeModelClass, node_removed),
gtk_marshal_NONE__POINTER_POINTER,
GTK_TYPE_NONE, 2, GTK_TYPE_POINTER, GTK_TYPE_POINTER);
gtk_object_class_add_signals (klass, e_tree_model_signals, LAST_SIGNAL);
table_class->row_count = etable_row_count;
table_class->value_at = etable_value_at;
table_class->set_value_at = etable_set_value_at;
table_class->is_cell_editable = etable_is_cell_editable;
#if 0
/* XX need to pass these through */
table_class->duplicate_value = etable_duplicate_value;
table_class->free_value = etable_free_value;
table_class->initialize_value = etable_initialize_value;
table_class->value_is_empty = etable_value_is_empty;
table_class->value_to_string = etable_value_to_string;
table_class->thaw = etable_thaw;
#endif
tree_class->get_root = etree_get_root;
tree_class->get_prev = etree_get_prev;
tree_class->get_next = etree_get_next;
tree_class->get_parent = etree_get_parent;
tree_class->value_at = etree_value_at;
tree_class->icon_at = etree_icon_at;
tree_class->set_value_at = etree_set_value_at;
tree_class->is_editable = etree_is_editable;
tree_class->get_children = etree_get_children;
tree_class->is_expanded = etree_is_expanded;
tree_class->is_visible = etree_is_visible;
tree_class->set_expanded = etree_set_expanded;
tree_class->set_expanded_recurse = etree_set_expanded_recurse;
tree_class->node_at_row = etree_node_at_row;
}
E_MAKE_TYPE(e_tree_model, "ETreeModel", ETreeModel, e_tree_model_class_init, NULL, PARENT_TYPE)
/* signals */
void
e_tree_model_node_changed (ETreeModel *tree_model, ETreePath *node)
{
g_return_if_fail (tree_model != NULL);
g_return_if_fail (E_IS_TREE_MODEL (tree_model));
gtk_signal_emit (GTK_OBJECT (tree_model),
e_tree_model_signals [NODE_CHANGED]);
}
void
e_tree_model_node_inserted (ETreeModel *tree_model,
ETreePath *parent_node,
ETreePath *inserted_node)
{
g_return_if_fail (tree_model != NULL);
g_return_if_fail (E_IS_TREE_MODEL (tree_model));
gtk_signal_emit (GTK_OBJECT (tree_model),
e_tree_model_signals [NODE_INSERTED],
parent_node, inserted_node);
}
void
e_tree_model_node_removed (ETreeModel *tree_model, ETreePath *parent_node, ETreePath *removed_node)
{
g_return_if_fail (tree_model != NULL);
g_return_if_fail (E_IS_TREE_MODEL (tree_model));
gtk_signal_emit (GTK_OBJECT (tree_model),
e_tree_model_signals [NODE_REMOVED],
parent_node, removed_node);
}
void
e_tree_model_construct (ETreeModel *etree)
{
etree->root = NULL;
etree->root_visible = TRUE;
etree->row_array = g_array_new (FALSE, FALSE, sizeof(GNode*));
}
ETreeModel *
e_tree_model_new ()
{
ETreeModel *et;
et = gtk_type_new (e_tree_model_get_type ());
return et;
}
ETreePath *
e_tree_model_get_root (ETreeModel *etree)
{
return ETM_CLASS(etree)->get_root(etree);
}
ETreePath *
e_tree_model_node_at_row (ETreeModel *etree, int row)
{
return ETM_CLASS(etree)->node_at_row (etree, row);
}
GdkPixbuf *
e_tree_model_icon_of_node (ETreeModel *etree, ETreePath *path)
{
return ETM_CLASS(etree)->icon_at (etree, path);
}
int
e_tree_model_row_of_node (ETreeModel *etree, ETreePath *node)
{
int i;
for (i = 0; i < etree->row_array->len; i ++)
if (g_array_index (etree->row_array, GNode*, i) == node)
return i;
g_warning ("e_tree_model_row_of_node failed for node %p\n", node);
return -1;
}
void
e_tree_model_root_node_set_visible (ETreeModel *etm, gboolean visible)
{
if (visible != etm->root_visible) {
etm->root_visible = visible;
if (etm->root) {
if (visible) {
etm->row_array = g_array_insert_val (etm->row_array, 0, etm->root);
}
else {
ETreePath *root_path = e_tree_model_get_root (etm);
e_tree_model_node_set_expanded (etm, root_path, TRUE);
etm->row_array = g_array_remove_index (etm->row_array, 0);
}
e_table_model_changed (E_TABLE_MODEL (etm));
}
}
}
gboolean
e_tree_model_root_node_is_visible (ETreeModel *etm)
{
return etm->root_visible;
}
ETreePath *
e_tree_model_node_get_next (ETreeModel *etree, ETreePath *node)
{
return ETM_CLASS(etree)->get_next(etree, node);
}
ETreePath *
e_tree_model_node_get_prev (ETreeModel *etree, ETreePath *node)
{
return ETM_CLASS(etree)->get_prev(etree, node);
}
guint
e_tree_model_node_depth (ETreeModel *etree, ETreePath *path)
{
return g_node_depth (path) - 1;
}
ETreePath *
e_tree_model_node_get_parent (ETreeModel *etree, ETreePath *path)
{
return ETM_CLASS(etree)->get_parent(etree, path);
}
gboolean
e_tree_model_node_is_root (ETreeModel *etree, ETreePath *path)
{
return (e_tree_model_node_depth (etree, path) == 0);
}
gboolean
e_tree_model_node_is_expandable (ETreeModel *etree, ETreePath *path)
{
return (e_tree_model_node_get_children (etree, path, NULL) > 0);
}
gboolean
e_tree_model_node_is_expanded (ETreeModel *etree, ETreePath *path)
{
return ETM_CLASS(etree)->is_expanded (etree, path);
}
gboolean
e_tree_model_node_is_visible (ETreeModel *etree, ETreePath *path)
{
return ETM_CLASS(etree)->is_visible (etree, path);
}
void
e_tree_model_node_set_expanded (ETreeModel *etree, ETreePath *path, gboolean expanded)
{
ETM_CLASS(etree)->set_expanded (etree, path, expanded);
}
void
e_tree_model_node_set_expanded_recurse (ETreeModel *etree, ETreePath *path, gboolean expanded)
{
ETM_CLASS(etree)->set_expanded_recurse (etree, path, expanded);
}
guint
e_tree_model_node_get_children (ETreeModel *etree, ETreePath *path, ETreePath ***paths)
{
return ETM_CLASS(etree)->get_children (etree, path, paths);
}
guint
e_tree_model_node_num_visible_descendents (ETreeModel *etm, ETreePath *node)
{
ENode *enode = (ENode*)node->data;
return enode->visible_descendents;
}
gpointer
e_tree_model_node_get_data (ETreeModel *etm, ETreePath *node)
{
ENode *enode;
g_return_val_if_fail (node && node->data, NULL);
enode = (ENode*)node->data;
return enode->node_data;
}
void
e_tree_model_node_set_data (ETreeModel *etm, ETreePath *node, gpointer node_data)
{
ENode *enode;
g_return_if_fail (node && node->data);
enode = (ENode*)node->data;
enode->node_data = node_data;
}
ETreePath*
e_tree_model_node_insert (ETreeModel *tree_model,
ETreePath *parent_path,
int position,
gpointer node_data)
{
ENode *node;
ETreePath *new_path;
g_return_val_if_fail (parent_path != NULL || tree_model->root == NULL, NULL);
node = g_new0 (ENode, 1);
node->expanded = FALSE;
node->node_data = node_data;
if (parent_path != NULL) {
new_path = g_node_new (node);
g_node_insert (parent_path, position, new_path);
if (e_tree_model_node_is_visible (tree_model, new_path)) {
int parent_row;
GNode *n;
/* we need to iterate back up to the root, incrementing the number of visible
descendents */
for (n = parent_path; n; n = n->parent) {
ENode *parent_enode = (ENode*)n->data;
parent_enode->visible_descendents ++;
}
/* finally, insert a row into the table */
if (position == -1)
position = e_tree_model_node_num_visible_descendents (tree_model, parent_path) - 1;
parent_row = e_tree_model_row_of_node (tree_model, parent_path);
tree_model->row_array = g_array_insert_val (tree_model->row_array,
parent_row + position + 1, new_path);
e_table_model_row_inserted (E_TABLE_MODEL(tree_model), parent_row + position + 1);
}
}
else {
tree_model->root = g_node_new (node);
if (tree_model->root_visible) {
tree_model->row_array = g_array_insert_val (tree_model->row_array, 0, tree_model->root);
e_table_model_row_inserted (E_TABLE_MODEL (tree_model), 0);
}
else {
/* need to mark the new node as expanded or
we'll never see it's children */
node->expanded = TRUE;
}
new_path = tree_model->root;
}
return new_path;
}
ETreePath *
e_tree_model_node_insert_before (ETreeModel *etree,
ETreePath *parent,
ETreePath *sibling,
gpointer node_data)
{
return e_tree_model_node_insert (etree, parent,
g_node_child_position (parent, sibling),
node_data);
}
static void
child_remove (GNode *node, gpointer etree)
{
e_tree_model_node_remove (etree, node);
}
gpointer
e_tree_model_node_remove (ETreeModel *etree, ETreePath *path)
{
GNode *parent = path->parent;
ENode *enode = (ENode*)path->data;
gpointer ret = enode->node_data;
/* remove children */
g_node_children_foreach (path, G_TRAVERSE_ALL, child_remove, etree);
/* clean up the display */
if (parent) {
if (e_tree_model_node_is_visible (etree, path)) {
int row = e_tree_model_row_of_node (etree, path);
e_table_model_row_deleted (E_TABLE_MODEL (etree), row);
etree->row_array = g_array_remove_index (etree->row_array, row);
/* we need to iterate back up to the root, incrementing the number of visible
descendents */
for (; parent; parent = parent->parent) {
ENode *parent_enode = (ENode*)parent->data;
parent_enode->visible_descendents --;
}
}
}
else if (path == etree->root) {
etree->root = NULL;
if (etree->root_visible) {
etree->row_array = g_array_remove_index (etree->row_array, 0);
e_table_model_row_deleted (E_TABLE_MODEL (etree), 0);
}
}
else {
/* XXX invalid path */
return NULL;
}
/* now free up the storage from that path */
g_node_destroy (path);
g_free (enode);
return ret;
}
static void
add_visible_descendents_to_array (ETreeModel *etm, GNode *gnode, int *row, int *count)
{
GNode *child;
ENode *enode;
/* add a row for this node */
etm->row_array = g_array_insert_val (etm->row_array, (*row), gnode);
e_table_model_row_inserted (E_TABLE_MODEL (etm), (*row)++);
(*count) ++;
/* then loop over its children, calling this routine for each
of them */
enode = (ENode*)gnode->data;
if (enode->expanded) {
for (child = g_node_first_child (gnode); child;
child = g_node_next_sibling (child)) {
add_visible_descendents_to_array (etm, child, row, count);
}
}
}
void
e_tree_model_node_sort (ETreeModel *tree_model,
ETreePath *node,
GCompareFunc compare)
{
int num_nodes = g_node_n_children (node);
ETreePath **path_array;
int i;
if (num_nodes == 0)
return;
path_array = g_new (ETreePath*, num_nodes);
for (i = 0; i < num_nodes; i ++) {
path_array[i] = g_node_first_child(node);
g_node_unlink (path_array[i]);
}
qsort (path_array, num_nodes, sizeof(ETreePath*), compare);
for (i = 0; i < num_nodes; i ++) {
g_node_append (node, path_array[i]);
}
g_free (path_array);
e_table_model_changed (E_TABLE_MODEL (tree_model));
}