/* GTK - The GIMP Toolkit * Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald * * GtkBindingSet: Keybinding manager for GObjects. * Copyright (C) 1998 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, see . */ /* * Modified by the GTK+ Team and others 1997-2000. See the AUTHORS * file for a list of people on the GTK+ Team. See the ChangeLog * files for a list of changes. These files are distributed with * GTK+ at ftp://ftp.gtk.org/pub/gtk/. */ #include "config.h" #include #include #include "gtkbindingsprivate.h" #include "gtkkeyhash.h" #include "gtkstylecontext.h" #include "gtkwidget.h" #include "gtkintl.h" /** * SECTION:gtkbindings * @Title: Bindings * @Short_description: Key bindings for individual widgets * @See_also: Keyboard Accelerators, Mnemonics, #GtkCssProvider * * #GtkBindingSet provides a mechanism for configuring GTK+ key bindings * through CSS files. This eases key binding adjustments for application * developers as well as users and provides GTK+ users or administrators * with high key binding configurability which requires no application * or toolkit side changes. * * # Installing a key binding * * A CSS file binding consists of a “binding-set” definition and a match * statement to apply the binding set to specific widget types. Details * on the matching mechanism are described under * [Selectors][gtkcssprovider-selectors] * in the #GtkCssProvider documentation. Inside the binding set * definition, key combinations are bound to one or more specific * signal emissions on the target widget. Key combinations are strings * consisting of an optional #GdkModifierType name and * [key names][gdk3-Keyboard-Handling] * such as those defined in `gdk/gdkkeysyms.h` * or returned from gdk_keyval_name(), they have to be parsable by * gtk_accelerator_parse(). Specifications of signal emissions consist * of a string identifying the signal name, and a list of signal specific * arguments in parenthesis. * * For example for binding Control and the left or right cursor keys * of a #GtkEntry widget to the #GtkEntry::move-cursor signal (so * movement occurs in 3-character steps), the following binding can be * used: * * |[ * @binding-set MoveCursor3 * { * bind "Right" { "move-cursor" (visual-positions, 3, 0) }; * bind "Left" { "move-cursor" (visual-positions, -3, 0) }; * } * GtkEntry * { * gtk-key-bindings: MoveCursor3; * } * ]| * * # Unbinding existing key bindings * * GTK+ already defines a number of useful bindings for the widgets * it provides. Because custom bindings set up in CSS files take * precedence over the default bindings shipped with GTK+, overriding * existing bindings as demonstrated in * [Installing a key binding][gtk-bindings-install] * works as expected. The same mechanism can not be used to “unbind” * existing bindings, however. * * |[ * @binding-set MoveCursor3 * { * bind "Right" { }; * bind "Left" { }; * } * GtkEntry * { * gtk-key-bindings: MoveCursor3; * } * ]| * * The above example will not have the desired effect of causing * “Right” and “Left” key presses to be ignored by GTK+. * Instead, it just causes any existing bindings from the bindings set * “MoveCursor3” to be deleted, so when “Right” or * “Left” are pressed, no binding for these keys is found in * binding set “MoveCursor3”. GTK+ will thus continue to search for * matching key bindings, and will eventually lookup and find the default * GTK+ bindings for entries which implement word movement. To keep GTK+ * from activating its default bindings, the “unbind” keyword can be used * like this: * * |[ * @binding-set MoveCursor3 * { * unbind "Right"; * unbind "Left"; * } * GtkEntry * { * gtk-key-bindings: MoveCursor3; * } * ]| * * Now, GTK+ will find a match when looking up “Right” and * “Left” key presses before it resorts to its default bindings, * and the match instructs it to abort (“unbind”) the search, so the key * presses are not consumed by this widget. As usual, further processing * of the key presses, e.g. by an entry’s parent widget, is now possible. */ /* --- defines --- */ #define BINDING_MOD_MASK() (gtk_accelerator_get_default_mod_mask () | GDK_RELEASE_MASK) #define GTK_TYPE_IDENTIFIER (gtk_identifier_get_type ()) _GDK_EXTERN GType gtk_identifier_get_type (void) G_GNUC_CONST; /* --- structures --- */ typedef struct { GtkPathType type; GPatternSpec *pspec; gpointer user_data; guint seq_id; } PatternSpec; typedef enum { GTK_BINDING_TOKEN_BIND, GTK_BINDING_TOKEN_UNBIND } GtkBindingTokens; /* --- variables --- */ static GHashTable *binding_entry_hash_table = NULL; static GSList *binding_key_hashes = NULL; static GSList *binding_set_list = NULL; static const gchar key_class_binding_set[] = "gtk-class-binding-set"; static GQuark key_id_class_binding_set = 0; /* --- functions --- */ GType gtk_identifier_get_type (void) { static GType our_type = 0; if (our_type == 0) { GTypeInfo tinfo = { 0, }; our_type = g_type_register_static (G_TYPE_STRING, I_("GtkIdentifier"), &tinfo, 0); } return our_type; } static void pattern_spec_free (PatternSpec *pspec) { if (pspec->pspec) g_pattern_spec_free (pspec->pspec); g_free (pspec); } static GtkBindingSignal* binding_signal_new (const gchar *signal_name, guint n_args) { GtkBindingSignal *signal; signal = (GtkBindingSignal *) g_slice_alloc0 (sizeof (GtkBindingSignal) + n_args * sizeof (GtkBindingArg)); signal->next = NULL; signal->signal_name = (gchar *)g_intern_string (signal_name); signal->n_args = n_args; signal->args = (GtkBindingArg *)(signal + 1); return signal; } static void binding_signal_free (GtkBindingSignal *sig) { guint i; for (i = 0; i < sig->n_args; i++) { if (G_TYPE_FUNDAMENTAL (sig->args[i].arg_type) == G_TYPE_STRING) g_free (sig->args[i].d.string_data); } g_slice_free1 (sizeof (GtkBindingSignal) + sig->n_args * sizeof (GtkBindingArg), sig); } static guint binding_entry_hash (gconstpointer key) { register const GtkBindingEntry *e = key; register guint h; h = e->keyval; h ^= e->modifiers; return h; } static gint binding_entries_compare (gconstpointer a, gconstpointer b) { register const GtkBindingEntry *ea = a; register const GtkBindingEntry *eb = b; return (ea->keyval == eb->keyval && ea->modifiers == eb->modifiers); } static void binding_key_hash_insert_entry (GtkKeyHash *key_hash, GtkBindingEntry *entry) { guint keyval = entry->keyval; /* We store lowercased accelerators. To deal with this, if * was specified, uppercase. */ if (entry->modifiers & GDK_SHIFT_MASK) { if (keyval == GDK_KEY_Tab) keyval = GDK_KEY_ISO_Left_Tab; else keyval = gdk_keyval_to_upper (keyval); } _gtk_key_hash_add_entry (key_hash, keyval, entry->modifiers & ~GDK_RELEASE_MASK, entry); } static void binding_key_hash_destroy (gpointer data) { GtkKeyHash *key_hash = data; binding_key_hashes = g_slist_remove (binding_key_hashes, key_hash); _gtk_key_hash_free (key_hash); } static void insert_entries_into_key_hash (gpointer key, gpointer value, gpointer data) { GtkKeyHash *key_hash = data; GtkBindingEntry *entry = value; for (; entry; entry = entry->hash_next) binding_key_hash_insert_entry (key_hash, entry); } static GtkKeyHash * binding_key_hash_for_keymap (GdkKeymap *keymap) { static GQuark key_hash_quark = 0; GtkKeyHash *key_hash; if (!key_hash_quark) key_hash_quark = g_quark_from_static_string ("gtk-binding-key-hash"); key_hash = g_object_get_qdata (G_OBJECT (keymap), key_hash_quark); if (!key_hash) { key_hash = _gtk_key_hash_new (keymap, NULL); g_object_set_qdata_full (G_OBJECT (keymap), key_hash_quark, key_hash, binding_key_hash_destroy); if (binding_entry_hash_table) g_hash_table_foreach (binding_entry_hash_table, insert_entries_into_key_hash, key_hash); binding_key_hashes = g_slist_prepend (binding_key_hashes, key_hash); } return key_hash; } static GtkBindingEntry* binding_entry_new (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers) { GSList *tmp_list; GtkBindingEntry *entry; if (!binding_entry_hash_table) binding_entry_hash_table = g_hash_table_new (binding_entry_hash, binding_entries_compare); entry = g_new (GtkBindingEntry, 1); entry->keyval = keyval; entry->modifiers = modifiers; entry->binding_set = binding_set, entry->destroyed = FALSE; entry->in_emission = FALSE; entry->marks_unbound = FALSE; entry->signals = NULL; entry->set_next = binding_set->entries; binding_set->entries = entry; entry->hash_next = g_hash_table_lookup (binding_entry_hash_table, entry); if (entry->hash_next) g_hash_table_remove (binding_entry_hash_table, entry->hash_next); g_hash_table_insert (binding_entry_hash_table, entry, entry); for (tmp_list = binding_key_hashes; tmp_list; tmp_list = tmp_list->next) { GtkKeyHash *key_hash = tmp_list->data; binding_key_hash_insert_entry (key_hash, entry); } return entry; } static void binding_entry_free (GtkBindingEntry *entry) { GtkBindingSignal *sig; g_assert (entry->set_next == NULL && entry->hash_next == NULL && entry->in_emission == FALSE && entry->destroyed == TRUE); entry->destroyed = FALSE; sig = entry->signals; while (sig) { GtkBindingSignal *prev; prev = sig; sig = prev->next; binding_signal_free (prev); } g_free (entry); } static void binding_entry_destroy (GtkBindingEntry *entry) { GtkBindingEntry *o_entry; register GtkBindingEntry *tmp; GtkBindingEntry *begin; register GtkBindingEntry *last; GSList *tmp_list; /* unlink from binding set */ last = NULL; tmp = entry->binding_set->entries; while (tmp) { if (tmp == entry) { if (last) last->set_next = entry->set_next; else entry->binding_set->entries = entry->set_next; break; } last = tmp; tmp = last->set_next; } entry->set_next = NULL; o_entry = g_hash_table_lookup (binding_entry_hash_table, entry); begin = o_entry; last = NULL; tmp = begin; while (tmp) { if (tmp == entry) { if (last) last->hash_next = entry->hash_next; else begin = entry->hash_next; break; } last = tmp; tmp = last->hash_next; } entry->hash_next = NULL; if (!begin) g_hash_table_remove (binding_entry_hash_table, entry); else if (begin != o_entry) { g_hash_table_remove (binding_entry_hash_table, entry); g_hash_table_insert (binding_entry_hash_table, begin, begin); } for (tmp_list = binding_key_hashes; tmp_list; tmp_list = tmp_list->next) { GtkKeyHash *key_hash = tmp_list->data; _gtk_key_hash_remove_entry (key_hash, entry); } entry->destroyed = TRUE; if (!entry->in_emission) binding_entry_free (entry); } static GtkBindingEntry* binding_ht_lookup_entry (GtkBindingSet *set, guint keyval, GdkModifierType modifiers) { GtkBindingEntry lookup_entry = { 0 }; GtkBindingEntry *entry; if (!binding_entry_hash_table) return NULL; lookup_entry.keyval = keyval; lookup_entry.modifiers = modifiers; entry = g_hash_table_lookup (binding_entry_hash_table, &lookup_entry); for (; entry; entry = entry->hash_next) if (entry->binding_set == set) return entry; return NULL; } static gboolean binding_compose_params (GObject *object, GtkBindingArg *args, GSignalQuery *query, GValue **params_p) { GValue *params; const GType *types; guint i; gboolean valid; params = g_new0 (GValue, query->n_params + 1); *params_p = params; /* The instance we emit on is the first object in the array */ g_value_init (params, G_TYPE_OBJECT); g_value_set_object (params, G_OBJECT (object)); params++; types = query->param_types; valid = TRUE; for (i = 1; i < query->n_params + 1 && valid; i++) { GValue tmp_value = G_VALUE_INIT; g_value_init (params, *types); switch (G_TYPE_FUNDAMENTAL (args->arg_type)) { case G_TYPE_DOUBLE: g_value_init (&tmp_value, G_TYPE_DOUBLE); g_value_set_double (&tmp_value, args->d.double_data); break; case G_TYPE_LONG: g_value_init (&tmp_value, G_TYPE_LONG); g_value_set_long (&tmp_value, args->d.long_data); break; case G_TYPE_STRING: /* gtk_rc_parse_flags/enum() has fancier parsing for this; we can't call * that since we don't have a GParamSpec, so just do something simple */ if (G_TYPE_FUNDAMENTAL (*types) == G_TYPE_ENUM) { GEnumClass *class = G_ENUM_CLASS (g_type_class_ref (*types)); valid = FALSE; if (args->arg_type == GTK_TYPE_IDENTIFIER) { GEnumValue *enum_value = NULL; enum_value = g_enum_get_value_by_name (class, args->d.string_data); if (!enum_value) enum_value = g_enum_get_value_by_nick (class, args->d.string_data); if (enum_value) { g_value_init (&tmp_value, *types); g_value_set_enum (&tmp_value, enum_value->value); valid = TRUE; } } g_type_class_unref (class); } /* This is just a hack for compatibility with GTK+-1.2 where a string * could be used for a single flag value / without the support for multiple * values in gtk_rc_parse_flags(), this isn't very useful. */ else if (G_TYPE_FUNDAMENTAL (*types) == G_TYPE_FLAGS) { GFlagsClass *class = G_FLAGS_CLASS (g_type_class_ref (*types)); valid = FALSE; if (args->arg_type == GTK_TYPE_IDENTIFIER) { GFlagsValue *flags_value = NULL; flags_value = g_flags_get_value_by_name (class, args->d.string_data); if (!flags_value) flags_value = g_flags_get_value_by_nick (class, args->d.string_data); if (flags_value) { g_value_init (&tmp_value, *types); g_value_set_flags (&tmp_value, flags_value->value); valid = TRUE; } } g_type_class_unref (class); } else { g_value_init (&tmp_value, G_TYPE_STRING); g_value_set_static_string (&tmp_value, args->d.string_data); } break; default: valid = FALSE; break; } if (valid) { if (!g_value_transform (&tmp_value, params)) valid = FALSE; g_value_unset (&tmp_value); } types++; params++; args++; } if (!valid) { guint j; for (j = 0; j < i; j++) g_value_unset (&(*params_p)[j]); g_free (*params_p); *params_p = NULL; } return valid; } static gboolean gtk_binding_entry_activate (GtkBindingEntry *entry, GObject *object) { GtkBindingSignal *sig; gboolean old_emission; gboolean handled = FALSE; gint i; old_emission = entry->in_emission; entry->in_emission = TRUE; g_object_ref (object); for (sig = entry->signals; sig; sig = sig->next) { GSignalQuery query; guint signal_id; GValue *params = NULL; GValue return_val = G_VALUE_INIT; gchar *accelerator = NULL; signal_id = g_signal_lookup (sig->signal_name, G_OBJECT_TYPE (object)); if (!signal_id) { accelerator = gtk_accelerator_name (entry->keyval, entry->modifiers); g_warning ("gtk_binding_entry_activate(): binding \"%s::%s\": " "could not find signal \"%s\" in the `%s' class ancestry", entry->binding_set->set_name, accelerator, sig->signal_name, g_type_name (G_OBJECT_TYPE (object))); g_free (accelerator); continue; } g_signal_query (signal_id, &query); if (query.n_params != sig->n_args || (query.return_type != G_TYPE_NONE && query.return_type != G_TYPE_BOOLEAN) || !binding_compose_params (object, sig->args, &query, ¶ms)) { accelerator = gtk_accelerator_name (entry->keyval, entry->modifiers); g_warning ("gtk_binding_entry_activate(): binding \"%s::%s\": " "signature mismatch for signal \"%s\" in the `%s' class ancestry", entry->binding_set->set_name, accelerator, sig->signal_name, g_type_name (G_OBJECT_TYPE (object))); } else if (!(query.signal_flags & G_SIGNAL_ACTION)) { accelerator = gtk_accelerator_name (entry->keyval, entry->modifiers); g_warning ("gtk_binding_entry_activate(): binding \"%s::%s\": " "signal \"%s\" in the `%s' class ancestry cannot be used for action emissions", entry->binding_set->set_name, accelerator, sig->signal_name, g_type_name (G_OBJECT_TYPE (object))); } g_free (accelerator); if (accelerator) continue; if (query.return_type == G_TYPE_BOOLEAN) g_value_init (&return_val, G_TYPE_BOOLEAN); g_signal_emitv (params, signal_id, 0, &return_val); if (query.return_type == G_TYPE_BOOLEAN) { if (g_value_get_boolean (&return_val)) handled = TRUE; g_value_unset (&return_val); } else handled = TRUE; for (i = 0; i < query.n_params + 1; i++) g_value_unset (¶ms[i]); g_free (params); if (entry->destroyed) break; } g_object_unref (object); entry->in_emission = old_emission; if (entry->destroyed && !entry->in_emission) binding_entry_free (entry); return handled; } /** * gtk_binding_set_new: (skip) * @set_name: unique name of this binding set * * GTK+ maintains a global list of binding sets. Each binding set has * a unique name which needs to be specified upon creation. * * Return value: (transfer full): new binding set */ GtkBindingSet* gtk_binding_set_new (const gchar *set_name) { GtkBindingSet *binding_set; g_return_val_if_fail (set_name != NULL, NULL); binding_set = g_new (GtkBindingSet, 1); binding_set->set_name = (gchar *) g_intern_string (set_name); binding_set->widget_path_pspecs = NULL; binding_set->widget_class_pspecs = NULL; binding_set->class_branch_pspecs = NULL; binding_set->entries = NULL; binding_set->current = NULL; binding_set->parsed = FALSE; binding_set_list = g_slist_prepend (binding_set_list, binding_set); return binding_set; } /** * gtk_binding_set_by_class: (skip) * @object_class: a valid #GObject class * * This function returns the binding set named after the type name of * the passed in class structure. New binding sets are created on * demand by this function. * * Return value: (transfer full): the binding set corresponding to * @object_class */ GtkBindingSet* gtk_binding_set_by_class (gpointer object_class) { GObjectClass *class = object_class; GtkBindingSet* binding_set; g_return_val_if_fail (G_IS_OBJECT_CLASS (class), NULL); if (!key_id_class_binding_set) key_id_class_binding_set = g_quark_from_static_string (key_class_binding_set); binding_set = g_dataset_id_get_data (class, key_id_class_binding_set); if (binding_set) return binding_set; binding_set = gtk_binding_set_new (g_type_name (G_OBJECT_CLASS_TYPE (class))); g_dataset_id_set_data (class, key_id_class_binding_set, binding_set); return binding_set; } static GtkBindingSet* gtk_binding_set_find_interned (const gchar *set_name) { GSList *slist; for (slist = binding_set_list; slist; slist = slist->next) { GtkBindingSet *binding_set; binding_set = slist->data; if (binding_set->set_name == set_name) return binding_set; } return NULL; } /** * gtk_binding_set_find: * @set_name: unique binding set name * * Find a binding set by its globally unique name. * * The @set_name can either be a name used for gtk_binding_set_new() * or the type name of a class used in gtk_binding_set_by_class(). * * Return value: (transfer none): %NULL or the specified binding set */ GtkBindingSet* gtk_binding_set_find (const gchar *set_name) { g_return_val_if_fail (set_name != NULL, NULL); return gtk_binding_set_find_interned (g_intern_string (set_name)); } /** * gtk_binding_set_activate: * @binding_set: a #GtkBindingSet set to activate * @keyval: key value of the binding * @modifiers: key modifier of the binding * @object: object to activate when binding found * * Find a key binding matching @keyval and @modifiers within * @binding_set and activate the binding on @object. * * Return value: %TRUE if a binding was found and activated */ gboolean gtk_binding_set_activate (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers, GObject *object) { GtkBindingEntry *entry; g_return_val_if_fail (binding_set != NULL, FALSE); g_return_val_if_fail (G_IS_OBJECT (object), FALSE); keyval = gdk_keyval_to_lower (keyval); modifiers = modifiers & BINDING_MOD_MASK (); entry = binding_ht_lookup_entry (binding_set, keyval, modifiers); if (entry) return gtk_binding_entry_activate (entry, object); return FALSE; } static void gtk_binding_entry_clear_internal (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers) { GtkBindingEntry *entry; keyval = gdk_keyval_to_lower (keyval); modifiers = modifiers & BINDING_MOD_MASK (); entry = binding_ht_lookup_entry (binding_set, keyval, modifiers); if (entry) binding_entry_destroy (entry); entry = binding_entry_new (binding_set, keyval, modifiers); } /** * gtk_binding_entry_skip: * @binding_set: a #GtkBindingSet to skip an entry of * @keyval: key value of binding to skip * @modifiers: key modifier of binding to skip * * Install a binding on @binding_set which causes key lookups * to be aborted, to prevent bindings from lower priority sets * to be activated. * * Since: 2.12 */ void gtk_binding_entry_skip (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers) { GtkBindingEntry *entry; g_return_if_fail (binding_set != NULL); keyval = gdk_keyval_to_lower (keyval); modifiers = modifiers & BINDING_MOD_MASK (); entry = binding_ht_lookup_entry (binding_set, keyval, modifiers); if (entry) binding_entry_destroy (entry); entry = binding_entry_new (binding_set, keyval, modifiers); entry->marks_unbound = TRUE; } /** * gtk_binding_entry_remove: * @binding_set: a #GtkBindingSet to remove an entry of * @keyval: key value of binding to remove * @modifiers: key modifier of binding to remove * * Remove a binding previously installed via * gtk_binding_entry_add_signal() on @binding_set. */ void gtk_binding_entry_remove (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers) { GtkBindingEntry *entry; g_return_if_fail (binding_set != NULL); keyval = gdk_keyval_to_lower (keyval); modifiers = modifiers & BINDING_MOD_MASK (); entry = binding_ht_lookup_entry (binding_set, keyval, modifiers); if (entry) binding_entry_destroy (entry); } /** * gtk_binding_entry_add_signall: * @binding_set: a #GtkBindingSet to add a signal to * @keyval: key value * @modifiers: key modifier * @signal_name: signal name to be bound * @binding_args: (transfer none) (element-type GtkBindingArg): * list of #GtkBindingArg signal arguments * * Override or install a new key binding for @keyval with @modifiers on * @binding_set. */ void gtk_binding_entry_add_signall (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers, const gchar *signal_name, GSList *binding_args) { _gtk_binding_entry_add_signall (binding_set, keyval, modifiers, signal_name, binding_args); } void _gtk_binding_entry_add_signall (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers, const gchar *signal_name, GSList *binding_args) { GtkBindingEntry *entry; GtkBindingSignal *signal, **signal_p; GSList *slist; guint n = 0; GtkBindingArg *arg; g_return_if_fail (binding_set != NULL); g_return_if_fail (signal_name != NULL); keyval = gdk_keyval_to_lower (keyval); modifiers = modifiers & BINDING_MOD_MASK (); signal = binding_signal_new (signal_name, g_slist_length (binding_args)); arg = signal->args; for (slist = binding_args; slist; slist = slist->next) { GtkBindingArg *tmp_arg; tmp_arg = slist->data; if (!tmp_arg) { g_warning ("gtk_binding_entry_add_signall(): arg[%u] is `NULL'", n); binding_signal_free (signal); return; } switch (G_TYPE_FUNDAMENTAL (tmp_arg->arg_type)) { case G_TYPE_LONG: arg->arg_type = G_TYPE_LONG; arg->d.long_data = tmp_arg->d.long_data; break; case G_TYPE_DOUBLE: arg->arg_type = G_TYPE_DOUBLE; arg->d.double_data = tmp_arg->d.double_data; break; case G_TYPE_STRING: if (tmp_arg->arg_type != GTK_TYPE_IDENTIFIER) arg->arg_type = G_TYPE_STRING; else arg->arg_type = GTK_TYPE_IDENTIFIER; arg->d.string_data = g_strdup (tmp_arg->d.string_data); if (!arg->d.string_data) { g_warning ("gtk_binding_entry_add_signall(): value of `string' arg[%u] is `NULL'", n); binding_signal_free (signal); return; } break; default: g_warning ("gtk_binding_entry_add_signall(): unsupported type `%s' for arg[%u]", g_type_name (arg->arg_type), n); binding_signal_free (signal); return; } arg++; n++; } entry = binding_ht_lookup_entry (binding_set, keyval, modifiers); if (!entry) { gtk_binding_entry_clear_internal (binding_set, keyval, modifiers); entry = binding_ht_lookup_entry (binding_set, keyval, modifiers); } signal_p = &entry->signals; while (*signal_p) signal_p = &(*signal_p)->next; *signal_p = signal; } /** * gtk_binding_entry_add_signal: * @binding_set: a #GtkBindingSet to install an entry for * @keyval: key value of binding to install * @modifiers: key modifier of binding to install * @signal_name: signal to execute upon activation * @n_args: number of arguments to @signal_name * @...: arguments to @signal_name * * Override or install a new key binding for @keyval with @modifiers on * @binding_set. When the binding is activated, @signal_name will be * emitted on the target widget, with @n_args @Varargs used as * arguments. */ void gtk_binding_entry_add_signal (GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers, const gchar *signal_name, guint n_args, ...) { GSList *slist, *free_slist; va_list args; guint i; g_return_if_fail (binding_set != NULL); g_return_if_fail (signal_name != NULL); va_start (args, n_args); slist = NULL; for (i = 0; i < n_args; i++) { GtkBindingArg *arg; arg = g_slice_new0 (GtkBindingArg); slist = g_slist_prepend (slist, arg); arg->arg_type = va_arg (args, GType); switch (G_TYPE_FUNDAMENTAL (arg->arg_type)) { case G_TYPE_CHAR: case G_TYPE_UCHAR: case G_TYPE_INT: case G_TYPE_UINT: case G_TYPE_BOOLEAN: case G_TYPE_ENUM: case G_TYPE_FLAGS: arg->arg_type = G_TYPE_LONG; arg->d.long_data = va_arg (args, gint); break; case G_TYPE_LONG: case G_TYPE_ULONG: arg->arg_type = G_TYPE_LONG; arg->d.long_data = va_arg (args, glong); break; case G_TYPE_FLOAT: case G_TYPE_DOUBLE: arg->arg_type = G_TYPE_DOUBLE; arg->d.double_data = va_arg (args, gdouble); break; case G_TYPE_STRING: if (arg->arg_type != GTK_TYPE_IDENTIFIER) arg->arg_type = G_TYPE_STRING; arg->d.string_data = va_arg (args, gchar*); if (!arg->d.string_data) { g_warning ("gtk_binding_entry_add_signal(): type `%s' arg[%u] is `NULL'", g_type_name (arg->arg_type), i); i += n_args + 1; } break; default: g_warning ("gtk_binding_entry_add_signal(): unsupported type `%s' for arg[%u]", g_type_name (arg->arg_type), i); i += n_args + 1; break; } } va_end (args); if (i == n_args || i == 0) { slist = g_slist_reverse (slist); _gtk_binding_entry_add_signall (binding_set, keyval, modifiers, signal_name, slist); } free_slist = slist; while (slist) { g_slice_free (GtkBindingArg, slist->data); slist = slist->next; } g_slist_free (free_slist); } static guint gtk_binding_parse_signal (GScanner *scanner, GtkBindingSet *binding_set, guint keyval, GdkModifierType modifiers) { gchar *signal; guint expected_token = 0; GSList *args; GSList *slist; gboolean done; gboolean negate; gboolean need_arg; gboolean seen_comma; g_return_val_if_fail (scanner != NULL, G_TOKEN_ERROR); g_scanner_get_next_token (scanner); if (scanner->token != G_TOKEN_STRING) return G_TOKEN_STRING; g_scanner_peek_next_token (scanner); if (scanner->next_token != '(') { g_scanner_get_next_token (scanner); return '('; } signal = g_strdup (scanner->value.v_string); g_scanner_get_next_token (scanner); negate = FALSE; args = NULL; done = FALSE; need_arg = TRUE; seen_comma = FALSE; scanner->config->scan_symbols = FALSE; do { GtkBindingArg *arg; if (need_arg) expected_token = G_TOKEN_INT; else expected_token = ')'; g_scanner_get_next_token (scanner); switch ((guint) scanner->token) { case G_TOKEN_FLOAT: if (need_arg) { need_arg = FALSE; arg = g_new (GtkBindingArg, 1); arg->arg_type = G_TYPE_DOUBLE; arg->d.double_data = scanner->value.v_float; if (negate) { arg->d.double_data = - arg->d.double_data; negate = FALSE; } args = g_slist_prepend (args, arg); } else done = TRUE; break; case G_TOKEN_INT: if (need_arg) { need_arg = FALSE; arg = g_new (GtkBindingArg, 1); arg->arg_type = G_TYPE_LONG; arg->d.long_data = scanner->value.v_int; if (negate) { arg->d.long_data = - arg->d.long_data; negate = FALSE; } args = g_slist_prepend (args, arg); } else done = TRUE; break; case G_TOKEN_STRING: if (need_arg && !negate) { need_arg = FALSE; arg = g_new (GtkBindingArg, 1); arg->arg_type = G_TYPE_STRING; arg->d.string_data = g_strdup (scanner->value.v_string); args = g_slist_prepend (args, arg); } else done = TRUE; break; case G_TOKEN_IDENTIFIER: if (need_arg && !negate) { need_arg = FALSE; arg = g_new (GtkBindingArg, 1); arg->arg_type = GTK_TYPE_IDENTIFIER; arg->d.string_data = g_strdup (scanner->value.v_identifier); args = g_slist_prepend (args, arg); } else done = TRUE; break; case '-': if (!need_arg) done = TRUE; else if (negate) { expected_token = G_TOKEN_INT; done = TRUE; } else negate = TRUE; break; case ',': seen_comma = TRUE; if (need_arg) done = TRUE; else need_arg = TRUE; break; case ')': if (!(need_arg && seen_comma) && !negate) { args = g_slist_reverse (args); _gtk_binding_entry_add_signall (binding_set, keyval, modifiers, signal, args); expected_token = G_TOKEN_NONE; } done = TRUE; break; default: done = TRUE; break; } } while (!done); scanner->config->scan_symbols = TRUE; for (slist = args; slist; slist = slist->next) { GtkBindingArg *arg; arg = slist->data; if (G_TYPE_FUNDAMENTAL (arg->arg_type) == G_TYPE_STRING) g_free (arg->d.string_data); g_free (arg); } g_slist_free (args); g_free (signal); return expected_token; } static inline guint gtk_binding_parse_bind (GScanner *scanner, GtkBindingSet *binding_set) { guint keyval = 0; GdkModifierType modifiers = 0; gboolean unbind = FALSE; g_return_val_if_fail (scanner != NULL, G_TOKEN_ERROR); g_scanner_get_next_token (scanner); if (scanner->token != G_TOKEN_SYMBOL) return G_TOKEN_SYMBOL; if (scanner->value.v_symbol != GUINT_TO_POINTER (GTK_BINDING_TOKEN_BIND) && scanner->value.v_symbol != GUINT_TO_POINTER (GTK_BINDING_TOKEN_UNBIND)) return G_TOKEN_SYMBOL; unbind = (scanner->value.v_symbol == GUINT_TO_POINTER (GTK_BINDING_TOKEN_UNBIND)); g_scanner_get_next_token (scanner); if (scanner->token != (guint) G_TOKEN_STRING) return G_TOKEN_STRING; gtk_accelerator_parse (scanner->value.v_string, &keyval, &modifiers); modifiers &= BINDING_MOD_MASK (); if (keyval == 0) return G_TOKEN_STRING; if (unbind) { gtk_binding_entry_skip (binding_set, keyval, modifiers); return G_TOKEN_NONE; } g_scanner_get_next_token (scanner); if (scanner->token != '{') return '{'; gtk_binding_entry_clear_internal (binding_set, keyval, modifiers); g_scanner_peek_next_token (scanner); while (scanner->next_token != '}') { guint expected_token; switch (scanner->next_token) { case G_TOKEN_STRING: expected_token = gtk_binding_parse_signal (scanner, binding_set, keyval, modifiers); if (expected_token != G_TOKEN_NONE) return expected_token; break; default: g_scanner_get_next_token (scanner); return '}'; } g_scanner_peek_next_token (scanner); } g_scanner_get_next_token (scanner); return G_TOKEN_NONE; } static GScanner * create_signal_scanner (void) { GScanner *scanner; scanner = g_scanner_new (NULL); scanner->config->cset_identifier_nth = G_CSET_a_2_z G_CSET_A_2_Z G_CSET_DIGITS "-_"; g_scanner_scope_add_symbol (scanner, 0, "bind", GUINT_TO_POINTER (GTK_BINDING_TOKEN_BIND)); g_scanner_scope_add_symbol (scanner, 0, "unbind", GUINT_TO_POINTER (GTK_BINDING_TOKEN_UNBIND)); g_scanner_set_scope (scanner, 0); return scanner; } /** * gtk_binding_entry_add_signal_from_string: * @binding_set: a #GtkBindingSet * @signal_desc: a signal description * * Parses a signal description from @signal_desc and incorporates * it into @binding_set. * * Signal descriptions may either bind a key combination to * one or more signals: * |[ * bind "key" { * "signalname" (param, ...) * ... * } * ]| * * Or they may also unbind a key combination: * |[ * unbind "key" * ]| * * Key combinations must be in a format that can be parsed by * gtk_accelerator_parse(). * * Returns: %G_TOKEN_NONE if the signal was successfully parsed and added, * the expected token otherwise * * Since: 3.0 */ GTokenType gtk_binding_entry_add_signal_from_string (GtkBindingSet *binding_set, const gchar *signal_desc) { static GScanner *scanner = NULL; GTokenType ret; g_return_val_if_fail (binding_set != NULL, G_TOKEN_NONE); g_return_val_if_fail (signal_desc != NULL, G_TOKEN_NONE); if (G_UNLIKELY (!scanner)) scanner = create_signal_scanner (); g_scanner_input_text (scanner, signal_desc, (guint) strlen (signal_desc)); ret = gtk_binding_parse_bind (scanner, binding_set); /* Reset for next use */ g_scanner_set_scope (scanner, 0); return ret; } /** * gtk_binding_set_add_path: * @binding_set: a #GtkBindingSet to add a path to * @path_type: path type the pattern applies to * @path_pattern: the actual match pattern * @priority: binding priority * * This function was used internally by the GtkRC parsing mechanism * to assign match patterns to #GtkBindingSet structures. * * In GTK+ 3, these match patterns are unused. * * Deprecated: 3.0 */ void gtk_binding_set_add_path (GtkBindingSet *binding_set, GtkPathType path_type, const gchar *path_pattern, GtkPathPriorityType priority) { PatternSpec *pspec; GSList **slist_p, *slist; static guint seq_id = 0; g_return_if_fail (binding_set != NULL); g_return_if_fail (path_pattern != NULL); g_return_if_fail (priority <= GTK_PATH_PRIO_MASK); priority &= GTK_PATH_PRIO_MASK; switch (path_type) { case GTK_PATH_WIDGET: slist_p = &binding_set->widget_path_pspecs; break; case GTK_PATH_WIDGET_CLASS: slist_p = &binding_set->widget_class_pspecs; break; case GTK_PATH_CLASS: slist_p = &binding_set->class_branch_pspecs; break; default: g_assert_not_reached (); slist_p = NULL; break; } pspec = g_new (PatternSpec, 1); pspec->type = path_type; if (path_type == GTK_PATH_WIDGET_CLASS) pspec->pspec = NULL; else pspec->pspec = g_pattern_spec_new (path_pattern); pspec->seq_id = priority << 28; pspec->user_data = binding_set; slist = *slist_p; while (slist) { PatternSpec *tmp_pspec; tmp_pspec = slist->data; slist = slist->next; if (g_pattern_spec_equal (tmp_pspec->pspec, pspec->pspec)) { GtkPathPriorityType lprio = tmp_pspec->seq_id >> 28; pattern_spec_free (pspec); pspec = NULL; if (lprio < priority) { tmp_pspec->seq_id &= 0x0fffffff; tmp_pspec->seq_id |= priority << 28; } break; } } if (pspec) { pspec->seq_id |= seq_id++ & 0x0fffffff; *slist_p = g_slist_prepend (*slist_p, pspec); } } static gint find_entry_with_binding (GtkBindingEntry *entry, GtkBindingSet *binding_set) { return (entry->binding_set == binding_set) ? 0 : 1; } static gboolean binding_activate (GtkBindingSet *binding_set, GSList *entries, GObject *object, gboolean is_release, gboolean *unbound) { GtkBindingEntry *entry; GSList *elem; elem = g_slist_find_custom (entries, binding_set, (GCompareFunc) find_entry_with_binding); if (!elem) return FALSE; entry = elem->data; if (is_release != ((entry->modifiers & GDK_RELEASE_MASK) != 0)) return FALSE; if (entry->marks_unbound) { *unbound = TRUE; return FALSE; } if (gtk_binding_entry_activate (entry, object)) return TRUE; return FALSE; } static gboolean gtk_bindings_activate_list (GObject *object, GSList *entries, gboolean is_release) { GtkStyleContext *context; GtkBindingSet *binding_set; GtkStateFlags state; gboolean handled = FALSE; gboolean unbound = FALSE; GPtrArray *array; if (!entries) return FALSE; context = gtk_widget_get_style_context (GTK_WIDGET (object)); state = gtk_widget_get_state_flags (GTK_WIDGET (object)); gtk_style_context_get (context, state, "gtk-key-bindings", &array, NULL); if (array) { gint i; for (i = 0; i < array->len; i++) { binding_set = g_ptr_array_index (array, i); handled = binding_activate (binding_set, entries, object, is_release, &unbound); if (handled || unbound) break; } g_ptr_array_unref (array); if (unbound) return FALSE; } if (!handled) { GType class_type; class_type = G_TYPE_FROM_INSTANCE (object); while (class_type && !handled) { binding_set = gtk_binding_set_find_interned (g_type_name (class_type)); class_type = g_type_parent (class_type); if (!binding_set) continue; handled = binding_activate (binding_set, entries, object, is_release, &unbound); if (unbound) break; } if (unbound) return FALSE; } return handled; } /** * gtk_bindings_activate: * @object: object to activate when binding found * @keyval: key value of the binding * @modifiers: key modifier of the binding * * Find a key binding matching @keyval and @modifiers and activate the * binding on @object. * * Return value: %TRUE if a binding was found and activated */ gboolean gtk_bindings_activate (GObject *object, guint keyval, GdkModifierType modifiers) { GSList *entries = NULL; GdkDisplay *display; GtkKeyHash *key_hash; gboolean handled = FALSE; gboolean is_release; if (!GTK_IS_WIDGET (object)) return FALSE; is_release = (modifiers & GDK_RELEASE_MASK) != 0; modifiers = modifiers & BINDING_MOD_MASK () & ~GDK_RELEASE_MASK; display = gtk_widget_get_display (GTK_WIDGET (object)); key_hash = binding_key_hash_for_keymap (gdk_keymap_get_for_display (display)); entries = _gtk_key_hash_lookup_keyval (key_hash, keyval, modifiers); handled = gtk_bindings_activate_list (object, entries, is_release); g_slist_free (entries); return handled; } /** * gtk_bindings_activate_event: * @object: a #GObject (generally must be a widget) * @event: a #GdkEventKey * * Looks up key bindings for @object to find one matching * @event, and if one was found, activate it. * * Return value: %TRUE if a matching key binding was found * * Since: 2.4 */ gboolean gtk_bindings_activate_event (GObject *object, GdkEventKey *event) { GSList *entries = NULL; GdkDisplay *display; GtkKeyHash *key_hash; gboolean handled = FALSE; if (!GTK_IS_WIDGET (object)) return FALSE; display = gtk_widget_get_display (GTK_WIDGET (object)); key_hash = binding_key_hash_for_keymap (gdk_keymap_get_for_display (display)); entries = _gtk_key_hash_lookup (key_hash, event->hardware_keycode, event->state, BINDING_MOD_MASK () & ~GDK_RELEASE_MASK, event->group); handled = gtk_bindings_activate_list (object, entries, event->type == GDK_KEY_RELEASE); g_slist_free (entries); return handled; }