/* eggaccelerators.c * Copyright (C) 2002 Red Hat, Inc.; Copyright 1998, 2001 Tim Janik * Developed by Havoc Pennington, Tim Janik * * 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, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ #include "eggaccelerators.h" #include #include #include enum { EGG_MODMAP_ENTRY_SHIFT = 0, EGG_MODMAP_ENTRY_LOCK = 1, EGG_MODMAP_ENTRY_CONTROL = 2, EGG_MODMAP_ENTRY_MOD1 = 3, EGG_MODMAP_ENTRY_MOD2 = 4, EGG_MODMAP_ENTRY_MOD3 = 5, EGG_MODMAP_ENTRY_MOD4 = 6, EGG_MODMAP_ENTRY_MOD5 = 7, EGG_MODMAP_ENTRY_LAST = 8 }; #define MODMAP_ENTRY_TO_MODIFIER(x) (1 << (x)) typedef struct { EggVirtualModifierType mapping[EGG_MODMAP_ENTRY_LAST]; } EggModmap; static const EggModmap* egg_keymap_get_modmap (GdkKeymap *keymap); static inline gboolean is_alt (const gchar *string) { return ((string[0] == '<') && (string[1] == 'a' || string[1] == 'A') && (string[2] == 'l' || string[2] == 'L') && (string[3] == 't' || string[3] == 'T') && (string[4] == '>')); } static inline gboolean is_ctl (const gchar *string) { return ((string[0] == '<') && (string[1] == 'c' || string[1] == 'C') && (string[2] == 't' || string[2] == 'T') && (string[3] == 'l' || string[3] == 'L') && (string[4] == '>')); } static inline gboolean is_modx (const gchar *string) { return ((string[0] == '<') && (string[1] == 'm' || string[1] == 'M') && (string[2] == 'o' || string[2] == 'O') && (string[3] == 'd' || string[3] == 'D') && (string[4] >= '1' && string[4] <= '5') && (string[5] == '>')); } static inline gboolean is_ctrl (const gchar *string) { return ((string[0] == '<') && (string[1] == 'c' || string[1] == 'C') && (string[2] == 't' || string[2] == 'T') && (string[3] == 'r' || string[3] == 'R') && (string[4] == 'l' || string[4] == 'L') && (string[5] == '>')); } static inline gboolean is_shft (const gchar *string) { return ((string[0] == '<') && (string[1] == 's' || string[1] == 'S') && (string[2] == 'h' || string[2] == 'H') && (string[3] == 'f' || string[3] == 'F') && (string[4] == 't' || string[4] == 'T') && (string[5] == '>')); } static inline gboolean is_shift (const gchar *string) { return ((string[0] == '<') && (string[1] == 's' || string[1] == 'S') && (string[2] == 'h' || string[2] == 'H') && (string[3] == 'i' || string[3] == 'I') && (string[4] == 'f' || string[4] == 'F') && (string[5] == 't' || string[5] == 'T') && (string[6] == '>')); } static inline gboolean is_control (const gchar *string) { return ((string[0] == '<') && (string[1] == 'c' || string[1] == 'C') && (string[2] == 'o' || string[2] == 'O') && (string[3] == 'n' || string[3] == 'N') && (string[4] == 't' || string[4] == 'T') && (string[5] == 'r' || string[5] == 'R') && (string[6] == 'o' || string[6] == 'O') && (string[7] == 'l' || string[7] == 'L') && (string[8] == '>')); } static inline gboolean is_release (const gchar *string) { return ((string[0] == '<') && (string[1] == 'r' || string[1] == 'R') && (string[2] == 'e' || string[2] == 'E') && (string[3] == 'l' || string[3] == 'L') && (string[4] == 'e' || string[4] == 'E') && (string[5] == 'a' || string[5] == 'A') && (string[6] == 's' || string[6] == 'S') && (string[7] == 'e' || string[7] == 'E') && (string[8] == '>')); } static inline gboolean is_meta (const gchar *string) { return ((string[0] == '<') && (string[1] == 'm' || string[1] == 'M') && (string[2] == 'e' || string[2] == 'E') && (string[3] == 't' || string[3] == 'T') && (string[4] == 'a' || string[4] == 'A') && (string[5] == '>')); } static inline gboolean is_super (const gchar *string) { return ((string[0] == '<') && (string[1] == 's' || string[1] == 'S') && (string[2] == 'u' || string[2] == 'U') && (string[3] == 'p' || string[3] == 'P') && (string[4] == 'e' || string[4] == 'E') && (string[5] == 'r' || string[5] == 'R') && (string[6] == '>')); } static inline gboolean is_hyper (const gchar *string) { return ((string[0] == '<') && (string[1] == 'h' || string[1] == 'H') && (string[2] == 'y' || string[2] == 'Y') && (string[3] == 'p' || string[3] == 'P') && (string[4] == 'e' || string[4] == 'E') && (string[5] == 'r' || string[5] == 'R') && (string[6] == '>')); } /** * egg_accelerator_parse_virtual: * @accelerator: string representing an accelerator * @accelerator_key: return location for accelerator keyval * @accelerator_mods: return location for accelerator modifier mask * * Parses a string representing a virtual accelerator. The format * looks like "<Control>a" or "<Shift><Alt>F1" or * "<Release>z" (the last one is for key release). The parser * is fairly liberal and allows lower or upper case, and also * abbreviations such as "<Ctl>" and "<Ctrl>". * * If the parse fails, @accelerator_key and @accelerator_mods will * be set to 0 (zero) and %FALSE will be returned. If the string contains * only modifiers, @accelerator_key will be set to 0 but %TRUE will be * returned. * * The virtual vs. concrete accelerator distinction is a relic of * how the X Window System works; there are modifiers Mod2-Mod5 that * can represent various keyboard keys (numlock, meta, hyper, etc.), * the virtual modifier represents the keyboard key, the concrete * modifier the actual Mod2-Mod5 bits in the key press event. * * Returns: %TRUE on success. */ gboolean egg_accelerator_parse_virtual (const gchar *accelerator, guint *accelerator_key, EggVirtualModifierType *accelerator_mods) { guint keyval; GdkModifierType mods; gint len; gboolean bad_keyval; if (accelerator_key) *accelerator_key = 0; if (accelerator_mods) *accelerator_mods = 0; g_return_val_if_fail (accelerator != NULL, FALSE); bad_keyval = FALSE; keyval = 0; mods = 0; len = strlen (accelerator); while (len) { if (*accelerator == '<') { if (len >= 9 && is_release (accelerator)) { accelerator += 9; len -= 9; mods |= EGG_VIRTUAL_RELEASE_MASK; } else if (len >= 9 && is_control (accelerator)) { accelerator += 9; len -= 9; mods |= EGG_VIRTUAL_CONTROL_MASK; } else if (len >= 7 && is_shift (accelerator)) { accelerator += 7; len -= 7; mods |= EGG_VIRTUAL_SHIFT_MASK; } else if (len >= 6 && is_shft (accelerator)) { accelerator += 6; len -= 6; mods |= EGG_VIRTUAL_SHIFT_MASK; } else if (len >= 6 && is_ctrl (accelerator)) { accelerator += 6; len -= 6; mods |= EGG_VIRTUAL_CONTROL_MASK; } else if (len >= 6 && is_modx (accelerator)) { static const guint mod_vals[] = { EGG_VIRTUAL_ALT_MASK, EGG_VIRTUAL_MOD2_MASK, EGG_VIRTUAL_MOD3_MASK, EGG_VIRTUAL_MOD4_MASK, EGG_VIRTUAL_MOD5_MASK }; len -= 6; accelerator += 4; mods |= mod_vals[*accelerator - '1']; accelerator += 2; } else if (len >= 5 && is_ctl (accelerator)) { accelerator += 5; len -= 5; mods |= EGG_VIRTUAL_CONTROL_MASK; } else if (len >= 5 && is_alt (accelerator)) { accelerator += 5; len -= 5; mods |= EGG_VIRTUAL_ALT_MASK; } else if (len >= 6 && is_meta (accelerator)) { accelerator += 6; len -= 6; mods |= EGG_VIRTUAL_META_MASK; } else if (len >= 7 && is_hyper (accelerator)) { accelerator += 7; len -= 7; mods |= EGG_VIRTUAL_HYPER_MASK; } else if (len >= 7 && is_super (accelerator)) { accelerator += 7; len -= 7; mods |= EGG_VIRTUAL_SUPER_MASK; } else { gchar last_ch; last_ch = *accelerator; while (last_ch && last_ch != '>') { last_ch = *accelerator; accelerator += 1; len -= 1; } } } else { keyval = gdk_keyval_from_name (accelerator); if (keyval == 0) bad_keyval = TRUE; accelerator += len; len -= len; } } if (accelerator_key) *accelerator_key = gdk_keyval_to_lower (keyval); if (accelerator_mods) *accelerator_mods = mods; return !bad_keyval; } /** * egg_virtual_accelerator_name: * @accelerator_key: accelerator keyval * @accelerator_mods: accelerator modifier mask * @returns: a newly-allocated accelerator name * * Converts an accelerator keyval and modifier mask * into a string parseable by egg_accelerator_parse_virtual(). * For example, if you pass in #GDK_q and #EGG_VIRTUAL_CONTROL_MASK, * this function returns "<Control>q". * * The caller of this function must free the returned string. */ gchar* egg_virtual_accelerator_name (guint accelerator_key, EggVirtualModifierType accelerator_mods) { static const gchar text_release[] = ""; static const gchar text_shift[] = ""; static const gchar text_control[] = ""; static const gchar text_mod1[] = ""; static const gchar text_mod2[] = ""; static const gchar text_mod3[] = ""; static const gchar text_mod4[] = ""; static const gchar text_mod5[] = ""; static const gchar text_meta[] = ""; static const gchar text_super[] = ""; static const gchar text_hyper[] = ""; guint l; gchar *keyval_name; gchar *accelerator; accelerator_mods &= EGG_VIRTUAL_MODIFIER_MASK; keyval_name = gdk_keyval_name (gdk_keyval_to_lower (accelerator_key)); if (!keyval_name) keyval_name = ""; l = 0; if (accelerator_mods & EGG_VIRTUAL_RELEASE_MASK) l += sizeof (text_release) - 1; if (accelerator_mods & EGG_VIRTUAL_SHIFT_MASK) l += sizeof (text_shift) - 1; if (accelerator_mods & EGG_VIRTUAL_CONTROL_MASK) l += sizeof (text_control) - 1; if (accelerator_mods & EGG_VIRTUAL_ALT_MASK) l += sizeof (text_mod1) - 1; if (accelerator_mods & EGG_VIRTUAL_MOD2_MASK) l += sizeof (text_mod2) - 1; if (accelerator_mods & EGG_VIRTUAL_MOD3_MASK) l += sizeof (text_mod3) - 1; if (accelerator_mods & EGG_VIRTUAL_MOD4_MASK) l += sizeof (text_mod4) - 1; if (accelerator_mods & EGG_VIRTUAL_MOD5_MASK) l += sizeof (text_mod5) - 1; if (accelerator_mods & EGG_VIRTUAL_META_MASK) l += sizeof (text_meta) - 1; if (accelerator_mods & EGG_VIRTUAL_HYPER_MASK) l += sizeof (text_hyper) - 1; if (accelerator_mods & EGG_VIRTUAL_SUPER_MASK) l += sizeof (text_super) - 1; l += strlen (keyval_name); accelerator = g_new (gchar, l + 1); l = 0; accelerator[l] = 0; if (accelerator_mods & EGG_VIRTUAL_RELEASE_MASK) { strcpy (accelerator + l, text_release); l += sizeof (text_release) - 1; } if (accelerator_mods & EGG_VIRTUAL_SHIFT_MASK) { strcpy (accelerator + l, text_shift); l += sizeof (text_shift) - 1; } if (accelerator_mods & EGG_VIRTUAL_CONTROL_MASK) { strcpy (accelerator + l, text_control); l += sizeof (text_control) - 1; } if (accelerator_mods & EGG_VIRTUAL_ALT_MASK) { strcpy (accelerator + l, text_mod1); l += sizeof (text_mod1) - 1; } if (accelerator_mods & EGG_VIRTUAL_MOD2_MASK) { strcpy (accelerator + l, text_mod2); l += sizeof (text_mod2) - 1; } if (accelerator_mods & EGG_VIRTUAL_MOD3_MASK) { strcpy (accelerator + l, text_mod3); l += sizeof (text_mod3) - 1; } if (accelerator_mods & EGG_VIRTUAL_MOD4_MASK) { strcpy (accelerator + l, text_mod4); l += sizeof (text_mod4) - 1; } if (accelerator_mods & EGG_VIRTUAL_MOD5_MASK) { strcpy (accelerator + l, text_mod5); l += sizeof (text_mod5) - 1; } if (accelerator_mods & EGG_VIRTUAL_META_MASK) { strcpy (accelerator + l, text_meta); l += sizeof (text_meta) - 1; } if (accelerator_mods & EGG_VIRTUAL_HYPER_MASK) { strcpy (accelerator + l, text_hyper); l += sizeof (text_hyper) - 1; } if (accelerator_mods & EGG_VIRTUAL_SUPER_MASK) { strcpy (accelerator + l, text_super); l += sizeof (text_super) - 1; } strcpy (accelerator + l, keyval_name); return accelerator; } void egg_keymap_resolve_virtual_modifiers (GdkKeymap *keymap, EggVirtualModifierType virtual_mods, GdkModifierType *concrete_mods) { GdkModifierType concrete; int i; const EggModmap *modmap; g_return_if_fail (GDK_IS_KEYMAP (keymap)); g_return_if_fail (concrete_mods != NULL); modmap = egg_keymap_get_modmap (keymap); /* Not so sure about this algorithm. */ concrete = 0; i = 0; while (i < EGG_MODMAP_ENTRY_LAST) { if (modmap->mapping[i] & virtual_mods) concrete |= (1 << i); ++i; } *concrete_mods = concrete; } void egg_keymap_virtualize_modifiers (GdkKeymap *keymap, GdkModifierType concrete_mods, EggVirtualModifierType *virtual_mods) { GdkModifierType virtual; int i; const EggModmap *modmap; g_return_if_fail (GDK_IS_KEYMAP (keymap)); g_return_if_fail (virtual_mods != NULL); modmap = egg_keymap_get_modmap (keymap); /* Not so sure about this algorithm. */ virtual = 0; i = 0; while (i < EGG_MODMAP_ENTRY_LAST) { if ((1 << i) & concrete_mods) { EggVirtualModifierType cleaned; cleaned = modmap->mapping[i] & ~(EGG_VIRTUAL_MOD2_MASK | EGG_VIRTUAL_MOD3_MASK | EGG_VIRTUAL_MOD4_MASK | EGG_VIRTUAL_MOD5_MASK); if (cleaned != 0) { virtual |= cleaned; } else { /* Rather than dropping mod2->mod5 if not bound, * go ahead and use the concrete names */ virtual |= modmap->mapping[i]; } } ++i; } *virtual_mods = virtual; } static void reload_modmap (GdkKeymap *keymap, EggModmap *modmap) { XModifierKeymap *xmodmap; int map_size; int i; /* FIXME multihead */ xmodmap = XGetModifierMapping (gdk_x11_get_default_xdisplay ()); memset (modmap->mapping, 0, sizeof (modmap->mapping)); /* there are 8 modifiers, and the first 3 are shift, shift lock, * and control */ map_size = 8 * xmodmap->max_keypermod; i = 3 * xmodmap->max_keypermod; while (i < map_size) { /* get the key code at this point in the map, * see if its keysym is one we're interested in */ int keycode = xmodmap->modifiermap[i]; GdkKeymapKey *keys; guint *keyvals; int n_entries; int j; EggVirtualModifierType mask; keys = NULL; keyvals = NULL; n_entries = 0; gdk_keymap_get_entries_for_keycode (keymap, keycode, &keys, &keyvals, &n_entries); mask = 0; j = 0; while (j < n_entries) { if (keyvals[j] == GDK_Num_Lock) mask |= EGG_VIRTUAL_NUM_LOCK_MASK; else if (keyvals[j] == GDK_Scroll_Lock) mask |= EGG_VIRTUAL_SCROLL_LOCK_MASK; else if (keyvals[j] == GDK_Meta_L || keyvals[j] == GDK_Meta_R) mask |= EGG_VIRTUAL_META_MASK; else if (keyvals[j] == GDK_Hyper_L || keyvals[j] == GDK_Hyper_R) mask |= EGG_VIRTUAL_HYPER_MASK; else if (keyvals[j] == GDK_Super_L || keyvals[j] == GDK_Super_R) mask |= EGG_VIRTUAL_SUPER_MASK; else if (keyvals[j] == GDK_Mode_switch) mask |= EGG_VIRTUAL_MODE_SWITCH_MASK; ++j; } /* Mod1Mask is 1 << 3 for example, i.e. the * fourth modifier, i / keyspermod is the modifier * index */ modmap->mapping[i/xmodmap->max_keypermod] |= mask; g_free (keyvals); g_free (keys); ++i; } /* Add in the not-really-virtual fixed entries */ modmap->mapping[EGG_MODMAP_ENTRY_SHIFT] |= EGG_VIRTUAL_SHIFT_MASK; modmap->mapping[EGG_MODMAP_ENTRY_CONTROL] |= EGG_VIRTUAL_CONTROL_MASK; modmap->mapping[EGG_MODMAP_ENTRY_LOCK] |= EGG_VIRTUAL_LOCK_MASK; modmap->mapping[EGG_MODMAP_ENTRY_MOD1] |= EGG_VIRTUAL_ALT_MASK; modmap->mapping[EGG_MODMAP_ENTRY_MOD2] |= EGG_VIRTUAL_MOD2_MASK; modmap->mapping[EGG_MODMAP_ENTRY_MOD3] |= EGG_VIRTUAL_MOD3_MASK; modmap->mapping[EGG_MODMAP_ENTRY_MOD4] |= EGG_VIRTUAL_MOD4_MASK; modmap->mapping[EGG_MODMAP_ENTRY_MOD5] |= EGG_VIRTUAL_MOD5_MASK; XFreeModifiermap (xmodmap); } const EggModmap* egg_keymap_get_modmap (GdkKeymap *keymap) { EggModmap *modmap; /* This is all a hack, much simpler when we can just * modify GDK directly. */ modmap = g_object_get_data (G_OBJECT (keymap), "egg-modmap"); if (modmap == NULL) { modmap = g_new0 (EggModmap, 1); /* FIXME modify keymap change events with an event filter * and force a reload if we get one */ reload_modmap (keymap, modmap); g_object_set_data_full (G_OBJECT (keymap), "egg-modmap", modmap, g_free); } g_assert (modmap != NULL); return modmap; }