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cc130473157e0fba43c15a7cdb7f48e7669068f4
gtk3/gtk/gtkaccelmap.c
Tadej Borovšak d947178e42 Update and expand GtkAccelMap API docs
2010-09-27 03:04:34 +02:00

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/* GTK - The GIMP Toolkit
* Copyright (C) 1998, 2001 Tim Janik
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
#include "config.h"
#include "gtkaccelmap.h"
#include "gtkmarshalers.h"
#include "gtkwindow.h" /* in lack of GtkAcceleratable */
#include "gtkintl.h"
#include <glib/gstdio.h>
#include <string.h>
#include <errno.h>
#include <fcntl.h>
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#ifdef G_OS_WIN32
#include <io.h>
#endif
/**
* SECTION:gtkaccelmap
* @Short_description: Loadable keyboard accelerator specifications
* @Title: Accelerator Maps
* @See_also: #GtkAccelGroup, #GtkAccelKey, #GtkUIManager, gtk_widget_set_accel_path(), gtk_menu_item_set_accel_path(), #GtkSettings:gtk-can-change-accels
*
* Accelerator maps are used to define runtime configurable accelerators.
* Functions for manipulating them are are usually used by higher level
* convenience mechanisms like #GtkUIManager and are thus considered
* "low-level". You'll want to use them if you're manually creating menus that
* should have user-configurable accelerators.
*
* Accelerator is uniquely defined by:
*
* <itemizedlist>
* <listitem><para>accelerator path</para></listitem>
* <listitem><para>accelerator key</para></listitem>
* <listitem><para>accelerator modifiers</para></listitem>
* </itemizedlist>
*
* The accelerator path must consist of
* "&lt;WINDOWTYPE&gt;/Category1/Category2/.../Action", where WINDOWTYPE
* should be a unique application-specific identifier that corresponds to the
* kind of window the accelerator is being used in, e.g. "Gimp-Image",
* "Abiword-Document" or "Gnumeric-Settings".
* The "Category1/.../Action" portion is most appropriately chosen by the action
* the accelerator triggers, i.e. for accelerators on menu items, choose the
* item's menu path, e.g. "File/Save As", "Image/View/Zoom" or
* "Edit/Select All". So a full valid accelerator path may look like:
* "&lt;Gimp-Toolbox&gt;/File/Dialogs/Tool Options...".
*
* All accelerators are stored inside one global #GtkAccelMap that can be
* obtained using gtk_accel_map_get(). See <link
* linkend="monitoring-changes">Monitoring changes</link> for additional
* details.
*
* <refsect2 id="manipulating-accelerators">
* <title>Manipulating accelerators</title>
* <para>
* New accelerators can be added using gtk_accel_map_add_entry(). To search for
* specific accelerator, use gtk_accel_map_lookup_entry(). Modifications of
* existing accelerators should be done using gtk_accel_map_change_entry().
*
* In order to avoid having some accelerators changed, they can be locked using
* gtk_accel_map_lock_path(). Unlocking is done using
* gtk_accel_map_unlock_path().
* </para>
* </refsect2>
* <refsect2 id="saving-and-loading">
* <title>Saving and loading accelerator maps</title>
* <para>
* Accelerator maps can be saved to and loaded from some external resource. For
* simple saving and loading from file, gtk_accel_map_save() and
* gtk_accel_map_load() are provided. Saving and loading can also be done by
* providing file descriptor to gtk_accel_map_save_fd() and
* gtk_accel_map_load_fd().
* </para>
* </refsect2>
* <refsect2 id="monitoring-changes">
* <title>Monitoring changes</title>
* <para>
* #GtkAccelMap object is only useful for monitoring changes of accelerators. By
* connecting to #GtkAccelMap::changed signal, one can monitor changes of all
* accelerators. It is also possible to monitor only single accelerator path by
* using it as a detail of the #GtkAccelMap::changed signal.
* </para>
* </refsect2>
*/
/* --- structures --- */
struct _GtkAccelMap
{
GObject parent_instance;
};
struct _GtkAccelMapClass
{
GObjectClass parent_class;
};
typedef struct {
const gchar *accel_path;
guint accel_key;
guint accel_mods;
guint std_accel_key;
guint std_accel_mods;
guint changed : 1;
guint lock_count : 15;
GSList *groups;
} AccelEntry;
/* --- signals --- */
enum {
CHANGED,
LAST_SIGNAL
};
/* --- variables --- */
static GHashTable *accel_entry_ht = NULL; /* accel_path -> AccelEntry */
static GSList *accel_filters = NULL;
static gulong accel_map_signals[LAST_SIGNAL] = { 0, };
static GtkAccelMap *accel_map;
/* --- prototypes --- */
static void do_accel_map_changed (AccelEntry *entry);
/* --- functions --- */
static guint
accel_entry_hash (gconstpointer key)
{
const AccelEntry *entry = key;
return g_str_hash (entry->accel_path);
}
static gboolean
accel_entry_equal (gconstpointer key1,
gconstpointer key2)
{
const AccelEntry *entry1 = key1;
const AccelEntry *entry2 = key2;
return g_str_equal (entry1->accel_path, entry2->accel_path);
}
static inline AccelEntry*
accel_path_lookup (const gchar *accel_path)
{
AccelEntry ekey;
ekey.accel_path = accel_path;
/* safety NULL check for return_if_fail()s */
return accel_path ? g_hash_table_lookup (accel_entry_ht, &ekey) : NULL;
}
void
_gtk_accel_map_init (void)
{
g_assert (accel_entry_ht == NULL);
accel_entry_ht = g_hash_table_new (accel_entry_hash, accel_entry_equal);
}
gboolean
_gtk_accel_path_is_valid (const gchar *accel_path)
{
gchar *p;
if (!accel_path || accel_path[0] != '<' ||
accel_path[1] == '<' || accel_path[1] == '>' || !accel_path[1])
return FALSE;
p = strchr (accel_path, '>');
if (!p || (p[1] != 0 && p[1] != '/'))
return FALSE;
return TRUE;
}
/**
* gtk_accel_map_add_entry:
* @accel_path: valid accelerator path
* @accel_key: the accelerator key
* @accel_mods: the accelerator modifiers
*
* Registers a new accelerator with the global accelerator map.
* This function should only be called once per @accel_path
* with the canonical @accel_key and @accel_mods for this path.
* To change the accelerator during runtime programatically, use
* gtk_accel_map_change_entry().
*
* Note that @accel_path string will be stored in a #GQuark. Therefore, if you
* pass a static string, you can save some memory by interning it first with
* g_intern_static_string().
*/
void
gtk_accel_map_add_entry (const gchar *accel_path,
guint accel_key,
GdkModifierType accel_mods)
{
AccelEntry *entry;
g_return_if_fail (_gtk_accel_path_is_valid (accel_path));
if (!accel_key)
accel_mods = 0;
else
accel_mods &= gtk_accelerator_get_default_mod_mask ();
entry = accel_path_lookup (accel_path);
if (entry)
{
if (!entry->std_accel_key && !entry->std_accel_mods &&
(accel_key || accel_mods))
{
entry->std_accel_key = accel_key;
entry->std_accel_mods = accel_mods;
if (!entry->changed)
gtk_accel_map_change_entry (entry->accel_path, accel_key, accel_mods, TRUE);
}
}
else
{
entry = g_slice_new0 (AccelEntry);
entry->accel_path = g_intern_string (accel_path);
entry->std_accel_key = accel_key;
entry->std_accel_mods = accel_mods;
entry->accel_key = accel_key;
entry->accel_mods = accel_mods;
entry->changed = FALSE;
entry->lock_count = 0;
g_hash_table_insert (accel_entry_ht, entry, entry);
do_accel_map_changed (entry);
}
}
/**
* gtk_accel_map_lookup_entry:
* @accel_path: a valid accelerator path
* @key: (allow-none) (out): the accelerator key to be filled in (optional)
* @returns: %TRUE if @accel_path is known, %FALSE otherwise
*
* Looks up the accelerator entry for @accel_path and fills in @key.
*/
gboolean
gtk_accel_map_lookup_entry (const gchar *accel_path,
GtkAccelKey *key)
{
AccelEntry *entry;
g_return_val_if_fail (_gtk_accel_path_is_valid (accel_path), FALSE);
entry = accel_path_lookup (accel_path);
if (entry && key)
{
key->accel_key = entry->accel_key;
key->accel_mods = entry->accel_mods;
key->accel_flags = 0;
}
return entry ? TRUE : FALSE;
}
static void
hash2slist_foreach (gpointer key,
gpointer value,
gpointer user_data)
{
GSList **slist_p = user_data;
*slist_p = g_slist_prepend (*slist_p, value);
}
static GSList*
g_hash_table_slist_values (GHashTable *hash_table)
{
GSList *slist = NULL;
g_return_val_if_fail (hash_table != NULL, NULL);
g_hash_table_foreach (hash_table, hash2slist_foreach, &slist);
return slist;
}
/* if simulate==TRUE, return whether accel_path can be changed to
* accel_key && accel_mods. otherwise, return whether accel_path
* was actually changed.
*/
static gboolean
internal_change_entry (const gchar *accel_path,
guint accel_key,
GdkModifierType accel_mods,
gboolean replace,
gboolean simulate)
{
GSList *node, *slist, *win_list, *group_list, *replace_list = NULL;
GHashTable *group_hm, *window_hm;
gboolean change_accel, removable, can_change = TRUE, seen_accel = FALSE;
GQuark entry_quark;
AccelEntry *entry = accel_path_lookup (accel_path);
/* not much todo if there's no entry yet */
if (!entry)
{
if (!simulate)
{
gtk_accel_map_add_entry (accel_path, 0, 0);
entry = accel_path_lookup (accel_path);
entry->accel_key = accel_key;
entry->accel_mods = accel_mods;
entry->changed = TRUE;
do_accel_map_changed (entry);
}
return TRUE;
}
/* if there's nothing to change, not much todo either */
if (entry->accel_key == accel_key && entry->accel_mods == accel_mods)
{
if (!simulate)
entry->changed = TRUE;
return simulate ? TRUE : FALSE;
}
/* The no-change case has already been handled, so
* simulate doesn't make a difference here.
*/
if (entry->lock_count > 0)
return FALSE;
/* nobody's interested, easy going */
if (!entry->groups)
{
if (!simulate)
{
entry->accel_key = accel_key;
entry->accel_mods = accel_mods;
entry->changed = TRUE;
do_accel_map_changed (entry);
}
return TRUE;
}
/* 1) fetch all accel groups affected by this entry */
entry_quark = g_quark_try_string (entry->accel_path);
group_hm = g_hash_table_new (NULL, NULL);
window_hm = g_hash_table_new (NULL, NULL);
for (slist = entry->groups; slist; slist = slist->next)
g_hash_table_insert (group_hm, slist->data, slist->data);
/* 2) collect acceleratables affected */
group_list = g_hash_table_slist_values (group_hm);
for (slist = group_list; slist; slist = slist->next)
{
GtkAccelGroup *group = slist->data;
for (node = _gtk_accel_group_get_accelerables (group); node; node = node->next)
g_hash_table_insert (window_hm, node->data, node->data);
}
g_slist_free (group_list);
/* 3) include all accel groups used by acceleratables */
win_list = g_hash_table_slist_values (window_hm);
g_hash_table_destroy (window_hm);
for (slist = win_list; slist; slist = slist->next)
for (node = gtk_accel_groups_from_object (slist->data); node; node = node->next)
g_hash_table_insert (group_hm, node->data, node->data);
group_list = g_hash_table_slist_values (group_hm);
g_hash_table_destroy (group_hm);
/* 4) walk the acceleratables and figure whether they occupy accel_key&accel_mods */
if (accel_key)
for (slist = win_list; slist; slist = slist->next)
if (GTK_IS_WINDOW (slist->data)) /* bad kludge in lack of a GtkAcceleratable */
if (_gtk_window_query_nonaccels (slist->data, accel_key, accel_mods))
{
seen_accel = TRUE;
break;
}
removable = !seen_accel;
/* 5) walk all accel groups and search for locks */
if (removable)
for (slist = group_list; slist; slist = slist->next)
{
GtkAccelGroup *group = slist->data;
GtkAccelGroupEntry *ag_entry;
guint i, n;
n = 0;
ag_entry = entry->accel_key ? gtk_accel_group_query (group, entry->accel_key, entry->accel_mods, &n) : NULL;
for (i = 0; i < n; i++)
if (ag_entry[i].accel_path_quark == entry_quark)
{
can_change = !(ag_entry[i].key.accel_flags & GTK_ACCEL_LOCKED);
if (!can_change)
goto break_loop_step5;
}
n = 0;
ag_entry = accel_key ? gtk_accel_group_query (group, accel_key, accel_mods, &n) : NULL;
for (i = 0; i < n; i++)
{
seen_accel = TRUE;
removable = !gtk_accel_group_get_is_locked (group) && !(ag_entry[i].key.accel_flags & GTK_ACCEL_LOCKED);
if (!removable)
goto break_loop_step5;
if (ag_entry[i].accel_path_quark)
replace_list = g_slist_prepend (replace_list, GUINT_TO_POINTER (ag_entry[i].accel_path_quark));
}
}
break_loop_step5:
/* 6) check whether we can remove existing accelerators */
if (removable && can_change)
for (slist = replace_list; slist; slist = slist->next)
if (!internal_change_entry (g_quark_to_string (GPOINTER_TO_UINT (slist->data)), 0, 0, FALSE, TRUE))
{
removable = FALSE;
break;
}
/* 7) check conditions and proceed if possible */
change_accel = can_change && (!seen_accel || (removable && replace));
if (change_accel && !simulate)
{
/* ref accel groups */
for (slist = group_list; slist; slist = slist->next)
g_object_ref (slist->data);
/* 8) remove existing accelerators */
for (slist = replace_list; slist; slist = slist->next)
internal_change_entry (g_quark_to_string (GPOINTER_TO_UINT (slist->data)), 0, 0, FALSE, FALSE);
/* 9) install new accelerator */
entry->accel_key = accel_key;
entry->accel_mods = accel_mods;
entry->changed = TRUE;
for (slist = group_list; slist; slist = slist->next)
_gtk_accel_group_reconnect (slist->data, g_quark_from_string (entry->accel_path));
/* unref accel groups */
for (slist = group_list; slist; slist = slist->next)
g_object_unref (slist->data);
do_accel_map_changed (entry);
}
g_slist_free (replace_list);
g_slist_free (group_list);
g_slist_free (win_list);
return change_accel;
}
/**
* gtk_accel_map_change_entry:
* @accel_path: a valid accelerator path
* @accel_key: the new accelerator key
* @accel_mods: the new accelerator modifiers
* @replace: %TRUE if other accelerators may be deleted upon conflicts
* @returns: %TRUE if the accelerator could be changed, %FALSE otherwise
*
* Changes the @accel_key and @accel_mods currently associated with @accel_path.
* Due to conflicts with other accelerators, a change may not always be possible,
* @replace indicates whether other accelerators may be deleted to resolve such
* conflicts. A change will only occur if all conflicts could be resolved (which
* might not be the case if conflicting accelerators are locked). Successful
* changes are indicated by a %TRUE return value.
*
* Note that @accel_path string will be stored in a #GQuark. Therefore, if you
* pass a static string, you can save some memory by interning it first with
* g_intern_static_string().
*/
gboolean
gtk_accel_map_change_entry (const gchar *accel_path,
guint accel_key,
GdkModifierType accel_mods,
gboolean replace)
{
g_return_val_if_fail (_gtk_accel_path_is_valid (accel_path), FALSE);
return internal_change_entry (accel_path, accel_key, accel_key ? accel_mods : 0, replace, FALSE);
}
static guint
accel_map_parse_accel_path (GScanner *scanner)
{
guint accel_key = 0;
GdkModifierType accel_mods = 0;
gchar *path, *accel;
/* parse accel path */
g_scanner_get_next_token (scanner);
if (scanner->token != G_TOKEN_STRING)
return G_TOKEN_STRING;
/* test if the next token is an accelerator */
g_scanner_peek_next_token (scanner);
if (scanner->next_token != G_TOKEN_STRING)
{
/* if not so, eat that token and error out */
g_scanner_get_next_token (scanner);
return G_TOKEN_STRING;
}
/* get the full accelerator specification */
path = g_strdup (scanner->value.v_string);
g_scanner_get_next_token (scanner);
accel = g_strdup (scanner->value.v_string);
/* ensure the entry is present */
gtk_accel_map_add_entry (path, 0, 0);
/* and propagate it */
gtk_accelerator_parse (accel, &accel_key, &accel_mods);
gtk_accel_map_change_entry (path, accel_key, accel_mods, TRUE);
g_free (accel);
g_free (path);
/* check correct statement end */
g_scanner_get_next_token (scanner);
if (scanner->token != ')')
return ')';
else
return G_TOKEN_NONE;
}
static void
accel_map_parse_statement (GScanner *scanner)
{
guint expected_token;
g_scanner_get_next_token (scanner);
if (scanner->token == G_TOKEN_SYMBOL)
{
guint (*parser_func) (GScanner*);
parser_func = (guint (*) (GScanner *))scanner->value.v_symbol;
expected_token = parser_func (scanner);
}
else
expected_token = G_TOKEN_SYMBOL;
/* skip rest of statement on errrors
*/
if (expected_token != G_TOKEN_NONE)
{
register guint level;
level = 1;
if (scanner->token == ')')
level--;
if (scanner->token == '(')
level++;
while (!g_scanner_eof (scanner) && level > 0)
{
g_scanner_get_next_token (scanner);
if (scanner->token == '(')
level++;
else if (scanner->token == ')')
level--;
}
}
}
/**
* gtk_accel_map_load_scanner:
* @scanner: a #GScanner which has already been provided with an input file
*
* #GScanner variant of gtk_accel_map_load().
*/
void
gtk_accel_map_load_scanner (GScanner *scanner)
{
gboolean skip_comment_single;
gboolean symbol_2_token;
gchar *cpair_comment_single;
gpointer saved_symbol;
g_return_if_fail (scanner != NULL);
/* configure scanner */
skip_comment_single = scanner->config->skip_comment_single;
scanner->config->skip_comment_single = TRUE;
cpair_comment_single = scanner->config->cpair_comment_single;
scanner->config->cpair_comment_single = ";\n";
symbol_2_token = scanner->config->symbol_2_token;
scanner->config->symbol_2_token = FALSE;
saved_symbol = g_scanner_lookup_symbol (scanner, "gtk_accel_path");
g_scanner_scope_add_symbol (scanner, 0, "gtk_accel_path",
accel_map_parse_accel_path);
/* outer parsing loop
*/
g_scanner_peek_next_token (scanner);
while (scanner->next_token == '(')
{
g_scanner_get_next_token (scanner);
accel_map_parse_statement (scanner);
g_scanner_peek_next_token (scanner);
}
/* restore config */
scanner->config->skip_comment_single = skip_comment_single;
scanner->config->cpair_comment_single = cpair_comment_single;
scanner->config->symbol_2_token = symbol_2_token;
g_scanner_scope_remove_symbol (scanner, 0, "gtk_accel_path");
if (saved_symbol)
g_scanner_scope_add_symbol (scanner, 0, "gtk_accel_path", saved_symbol);
}
/**
* gtk_accel_map_load_fd:
* @fd: a valid readable file descriptor
*
* Filedescriptor variant of gtk_accel_map_load().
*
* Note that the file descriptor will not be closed by this function.
*/
void
gtk_accel_map_load_fd (gint fd)
{
GScanner *scanner;
g_return_if_fail (fd >= 0);
/* create and setup scanner */
scanner = g_scanner_new (NULL);
g_scanner_input_file (scanner, fd);
gtk_accel_map_load_scanner (scanner);
g_scanner_destroy (scanner);
}
/**
* gtk_accel_map_load:
* @file_name: a file containing accelerator specifications,
* in the GLib file name encoding
*
* Parses a file previously saved with gtk_accel_map_save() for
* accelerator specifications, and propagates them accordingly.
*/
void
gtk_accel_map_load (const gchar *file_name)
{
gint fd;
g_return_if_fail (file_name != NULL);
if (!g_file_test (file_name, G_FILE_TEST_IS_REGULAR))
return;
fd = g_open (file_name, O_RDONLY, 0);
if (fd < 0)
return;
gtk_accel_map_load_fd (fd);
close (fd);
}
static gboolean
write_all (gint fd,
gchar *buf,
gsize to_write)
{
while (to_write > 0)
{
gssize count = write (fd, buf, to_write);
if (count < 0)
{
if (errno != EINTR)
return FALSE;
}
else
{
to_write -= count;
buf += count;
}
}
return TRUE;
}
static void
accel_map_print (gpointer data,
const gchar *accel_path,
guint accel_key,
GdkModifierType accel_mods,
gboolean changed)
{
GString *gstring = g_string_new (changed ? NULL : "; ");
gint fd = GPOINTER_TO_INT (data);
gchar *tmp, *name;
g_string_append (gstring, "(gtk_accel_path \"");
tmp = g_strescape (accel_path, NULL);
g_string_append (gstring, tmp);
g_free (tmp);
g_string_append (gstring, "\" \"");
name = gtk_accelerator_name (accel_key, accel_mods);
tmp = g_strescape (name, NULL);
g_free (name);
g_string_append (gstring, tmp);
g_free (tmp);
g_string_append (gstring, "\")\n");
write_all (fd, gstring->str, gstring->len);
g_string_free (gstring, TRUE);
}
/**
* gtk_accel_map_save_fd:
* @fd: a valid writable file descriptor
*
* Filedescriptor variant of gtk_accel_map_save().
*
* Note that the file descriptor will not be closed by this function.
*/
void
gtk_accel_map_save_fd (gint fd)
{
GString *gstring;
g_return_if_fail (fd >= 0);
gstring = g_string_new ("; ");
if (g_get_prgname ())
g_string_append (gstring, g_get_prgname ());
g_string_append (gstring, " GtkAccelMap rc-file -*- scheme -*-\n");
g_string_append (gstring, "; this file is an automated accelerator map dump\n");
g_string_append (gstring, ";\n");
write_all (fd, gstring->str, gstring->len);
g_string_free (gstring, TRUE);
gtk_accel_map_foreach (GINT_TO_POINTER (fd), accel_map_print);
}
/**
* gtk_accel_map_save:
* @file_name: the name of the file to contain accelerator specifications,
* in the GLib file name encoding
*
* Saves current accelerator specifications (accelerator path, key
* and modifiers) to @file_name.
* The file is written in a format suitable to be read back in by
* gtk_accel_map_load().
*/
void
gtk_accel_map_save (const gchar *file_name)
{
gint fd;
g_return_if_fail (file_name != NULL);
fd = g_open (file_name, O_CREAT | O_TRUNC | O_WRONLY, 0644);
if (fd < 0)
return;
gtk_accel_map_save_fd (fd);
close (fd);
}
/**
* gtk_accel_map_foreach:
* @data: data to be passed into @foreach_func
* @foreach_func: function to be executed for each accel map entry which
* is not filtered out
*
* Loops over the entries in the accelerator map whose accel path
* doesn't match any of the filters added with gtk_accel_map_add_filter(),
* and execute @foreach_func on each. The signature of @foreach_func is
* that of #GtkAccelMapForeach, the @changed parameter indicates whether
* this accelerator was changed during runtime (thus, would need
* saving during an accelerator map dump).
*/
void
gtk_accel_map_foreach (gpointer data,
GtkAccelMapForeach foreach_func)
{
GSList *entries, *slist, *node;
g_return_if_fail (foreach_func != NULL);
entries = g_hash_table_slist_values (accel_entry_ht);
for (slist = entries; slist; slist = slist->next)
{
AccelEntry *entry = slist->data;
gboolean changed = entry->accel_key != entry->std_accel_key || entry->accel_mods != entry->std_accel_mods;
for (node = accel_filters; node; node = node->next)
if (g_pattern_match_string (node->data, entry->accel_path))
goto skip_accel;
foreach_func (data, entry->accel_path, entry->accel_key, entry->accel_mods, changed);
skip_accel:
/* noop */;
}
g_slist_free (entries);
}
/**
* gtk_accel_map_foreach_unfiltered:
* @data: data to be passed into @foreach_func
* @foreach_func: function to be executed for each accel map entry
*
* Loops over all entries in the accelerator map, and execute
* @foreach_func on each. The signature of @foreach_func is that of
* #GtkAccelMapForeach, the @changed parameter indicates whether
* this accelerator was changed during runtime (thus, would need
* saving during an accelerator map dump).
*/
void
gtk_accel_map_foreach_unfiltered (gpointer data,
GtkAccelMapForeach foreach_func)
{
GSList *entries, *slist;
g_return_if_fail (foreach_func != NULL);
entries = g_hash_table_slist_values (accel_entry_ht);
for (slist = entries; slist; slist = slist->next)
{
AccelEntry *entry = slist->data;
gboolean changed = entry->accel_key != entry->std_accel_key || entry->accel_mods != entry->std_accel_mods;
foreach_func (data, entry->accel_path, entry->accel_key, entry->accel_mods, changed);
}
g_slist_free (entries);
}
/**
* gtk_accel_map_add_filter:
* @filter_pattern: a pattern (see #GPatternSpec)
*
* Adds a filter to the global list of accel path filters.
*
* Accel map entries whose accel path matches one of the filters
* are skipped by gtk_accel_map_foreach().
*
* This function is intended for GTK+ modules that create their own
* menus, but don't want them to be saved into the applications accelerator
* map dump.
*/
void
gtk_accel_map_add_filter (const gchar *filter_pattern)
{
GPatternSpec *pspec;
GSList *slist;
g_return_if_fail (filter_pattern != NULL);
pspec = g_pattern_spec_new (filter_pattern);
for (slist = accel_filters; slist; slist = slist->next)
if (g_pattern_spec_equal (pspec, slist->data))
{
g_pattern_spec_free (pspec);
return;
}
accel_filters = g_slist_prepend (accel_filters, pspec);
}
void
_gtk_accel_map_add_group (const gchar *accel_path,
GtkAccelGroup *accel_group)
{
AccelEntry *entry;
g_return_if_fail (_gtk_accel_path_is_valid (accel_path));
g_return_if_fail (GTK_IS_ACCEL_GROUP (accel_group));
entry = accel_path_lookup (accel_path);
if (!entry)
{
gtk_accel_map_add_entry (accel_path, 0, 0);
entry = accel_path_lookup (accel_path);
}
entry->groups = g_slist_prepend (entry->groups, accel_group);
}
void
_gtk_accel_map_remove_group (const gchar *accel_path,
GtkAccelGroup *accel_group)
{
AccelEntry *entry;
entry = accel_path_lookup (accel_path);
g_return_if_fail (entry != NULL);
g_return_if_fail (g_slist_find (entry->groups, accel_group));
entry->groups = g_slist_remove (entry->groups, accel_group);
}
/**
* gtk_accel_map_lock_path:
* @accel_path: a valid accelerator path
*
* Locks the given accelerator path. If the accelerator map doesn't yet contain
* an entry for @accel_path, a new one is created.
*
* Locking an accelerator path prevents its accelerator from being changed
* during runtime. A locked accelerator path can be unlocked by
* gtk_accel_map_unlock_path(). Refer to gtk_accel_map_change_entry()
* for information about runtime accelerator changes.
*
* If called more than once, @accel_path remains locked until
* gtk_accel_map_unlock_path() has been called an equivalent number
* of times.
*
* Note that locking of individual accelerator paths is independent from
* locking the #GtkAccelGroup containing them. For runtime accelerator
* changes to be possible both the accelerator path and its #GtkAccelGroup
* have to be unlocked.
*
* Since: 2.4
**/
void
gtk_accel_map_lock_path (const gchar *accel_path)
{
AccelEntry *entry;
g_return_if_fail (_gtk_accel_path_is_valid (accel_path));
entry = accel_path_lookup (accel_path);
if (!entry)
{
gtk_accel_map_add_entry (accel_path, 0, 0);
entry = accel_path_lookup (accel_path);
}
entry->lock_count += 1;
}
/**
* gtk_accel_map_unlock_path:
* @accel_path: a valid accelerator path
*
* Undoes the last call to gtk_accel_map_lock_path() on this @accel_path.
* Refer to gtk_accel_map_lock_path() for information about accelerator path locking.
*
* Since: 2.4
**/
void
gtk_accel_map_unlock_path (const gchar *accel_path)
{
AccelEntry *entry;
g_return_if_fail (_gtk_accel_path_is_valid (accel_path));
entry = accel_path_lookup (accel_path);
g_return_if_fail (entry != NULL && entry->lock_count > 0);
entry->lock_count -= 1;
}
G_DEFINE_TYPE (GtkAccelMap, gtk_accel_map, G_TYPE_OBJECT)
static void
gtk_accel_map_class_init (GtkAccelMapClass *accel_map_class)
{
/**
* GtkAccelMap::changed:
* @object: the global accel map object
* @accel_path: the path of the accelerator that changed
* @accel_key: the key value for the new accelerator
* @accel_mods: the modifier mask for the new accelerator
*
* Notifies of a change in the global accelerator map.
* The path is also used as the detail for the signal,
* so it is possible to connect to
* changed::<replaceable>accel_path</replaceable>.
*
* Since: 2.4
*/
accel_map_signals[CHANGED] = g_signal_new (I_("changed"),
G_TYPE_FROM_CLASS (accel_map_class),
G_SIGNAL_DETAILED|G_SIGNAL_RUN_LAST,
0,
NULL, NULL,
_gtk_marshal_VOID__STRING_UINT_FLAGS,
G_TYPE_NONE, 3,
G_TYPE_STRING, G_TYPE_UINT, GDK_TYPE_MODIFIER_TYPE);
}
static void
gtk_accel_map_init (GtkAccelMap *accel_map)
{
}
/**
* gtk_accel_map_get:
*
* Gets the singleton global #GtkAccelMap object. This object
* is useful only for notification of changes to the accelerator
* map via the ::changed signal; it isn't a parameter to the
* other accelerator map functions.
*
* Return value: (transfer none): the global #GtkAccelMap object
*
* Since: 2.4
**/
GtkAccelMap *
gtk_accel_map_get (void)
{
if (!accel_map)
accel_map = g_object_new (GTK_TYPE_ACCEL_MAP, NULL);
return accel_map;
}
static void
do_accel_map_changed (AccelEntry *entry)
{
if (accel_map)
g_signal_emit (accel_map,
accel_map_signals[CHANGED],
g_quark_from_string (entry->accel_path),
entry->accel_path,
entry->accel_key,
entry->accel_mods);
}
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