/* * Copyright (C) 2010 Intel Corp. * Copyright (C) 2014 Jonas Ådahl * * 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 . * * Author: Damien Lespiau * Author: Jonas Ådahl */ #include "config.h" #include #include #include "backends/meta-backend-private.h" #include "backends/native/meta-input-thread.h" #include "clutter/clutter-mutter.h" G_DEFINE_TYPE (MetaInputDeviceNative, meta_input_device_native, META_TYPE_INPUT_DEVICE) enum { PROP_0, PROP_DEVICE_MATRIX, PROP_OUTPUT_ASPECT_RATIO, N_PROPS }; static GParamSpec *obj_props[N_PROPS] = { 0 }; typedef struct _SlowKeysEventPending { MetaInputDeviceNative *device; ClutterEvent *event; GSource *timer; } SlowKeysEventPending; typedef struct _PadFeature PadFeature; struct _PadFeature { ClutterInputDevicePadFeature feature; int n_feature; int group; gboolean mode_switch; }; static void clear_slow_keys (MetaInputDeviceNative *device); static void stop_bounce_keys (MetaInputDeviceNative *device); static void stop_toggle_slowkeys (MetaInputDeviceNative *device); static void stop_mousekeys_move (MetaInputDeviceNative *device); static void meta_input_device_native_finalize (GObject *object) { MetaInputDeviceNative *device_evdev = META_INPUT_DEVICE_NATIVE (object); if (device_evdev->libinput_device) libinput_device_unref (device_evdev->libinput_device); clear_slow_keys (device_evdev); stop_bounce_keys (device_evdev); stop_toggle_slowkeys (device_evdev); stop_mousekeys_move (device_evdev); g_clear_pointer (&device_evdev->pad_features, g_array_unref); g_clear_pointer (&device_evdev->modes, g_array_unref); G_OBJECT_CLASS (meta_input_device_native_parent_class)->finalize (object); } static void meta_input_device_native_set_property (GObject *object, guint prop_id, const GValue *value, GParamSpec *pspec) { MetaInputDeviceNative *device = META_INPUT_DEVICE_NATIVE (object); switch (prop_id) { case PROP_DEVICE_MATRIX: { const cairo_matrix_t *matrix = g_value_get_boxed (value); cairo_matrix_init_identity (&device->device_matrix); cairo_matrix_multiply (&device->device_matrix, &device->device_matrix, matrix); break; } case PROP_OUTPUT_ASPECT_RATIO: device->output_ratio = g_value_get_double (value); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); } } static void meta_input_device_native_get_property (GObject *object, guint prop_id, GValue *value, GParamSpec *pspec) { MetaInputDeviceNative *device = META_INPUT_DEVICE_NATIVE (object); switch (prop_id) { case PROP_DEVICE_MATRIX: g_value_set_boxed (value, &device->device_matrix); break; case PROP_OUTPUT_ASPECT_RATIO: g_value_set_double (value, device->output_ratio); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); } } static gboolean meta_input_device_native_is_mode_switch_button (ClutterInputDevice *device, uint32_t group, uint32_t button) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); int i; if (!device_native->pad_features) return FALSE; for (i = 0; i < device_native->pad_features->len; i++) { PadFeature *pad_feature; pad_feature = &g_array_index (device_native->pad_features, PadFeature, i); if (pad_feature->feature == CLUTTER_PAD_FEATURE_BUTTON && pad_feature->group == group && pad_feature->n_feature == button) return pad_feature->mode_switch; } return FALSE; } static int meta_input_device_native_get_group_n_modes (ClutterInputDevice *device, int group) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); if (!device_native->modes || group < device_native->modes->len) return -1; return g_array_index (device_native->modes, int, group); } static gboolean meta_input_device_native_is_grouped (ClutterInputDevice *device, ClutterInputDevice *other_device) { MetaInputDeviceNative *device_native, *other_device_native; device_native = META_INPUT_DEVICE_NATIVE (device); other_device_native = META_INPUT_DEVICE_NATIVE (other_device); return device_native->group == other_device_native->group; } static int meta_input_device_native_get_pad_feature_group (ClutterInputDevice *device, ClutterInputDevicePadFeature feature, int n_feature) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); int i; if (!device_native->pad_features) return -1; for (i = 0; i < device_native->pad_features->len; i++) { PadFeature *pad_feature; pad_feature = &g_array_index (device_native->pad_features, PadFeature, i); if (pad_feature->feature == feature && pad_feature->n_feature == n_feature) return pad_feature->group; } return -1; } static void meta_input_device_native_bell_notify (MetaInputDeviceNative *device) { meta_seat_impl_notify_bell_in_impl (device->seat_impl); } static void meta_input_device_native_free_pending_slow_key (gpointer data) { SlowKeysEventPending *slow_keys_event = data; clutter_event_free (slow_keys_event->event); g_clear_pointer (&slow_keys_event->timer, g_source_destroy); g_free (slow_keys_event); } static void clear_slow_keys (MetaInputDeviceNative *device) { g_list_free_full (device->slow_keys_list, meta_input_device_native_free_pending_slow_key); g_list_free (device->slow_keys_list); device->slow_keys_list = NULL; } static guint get_slow_keys_delay (ClutterInputDevice *device) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); MetaKbdA11ySettings a11y_settings; MetaInputSettings *input_settings; input_settings = meta_seat_impl_get_input_settings (device_native->seat_impl); meta_input_settings_get_kbd_a11y_settings (input_settings, &a11y_settings); /* Settings use int, we use uint, make sure we dont go negative */ return MAX (0, a11y_settings.slowkeys_delay); } static gboolean trigger_slow_keys (gpointer data) { SlowKeysEventPending *slow_keys_event = data; MetaInputDeviceNative *device = slow_keys_event->device; ClutterKeyEvent *key_event = (ClutterKeyEvent *) slow_keys_event->event; /* Alter timestamp and emit the event */ key_event->time = us2ms (g_get_monotonic_time ()); _clutter_event_push (slow_keys_event->event, TRUE); /* Then remote the pending event */ device->slow_keys_list = g_list_remove (device->slow_keys_list, slow_keys_event); meta_input_device_native_free_pending_slow_key (slow_keys_event); if (device->a11y_flags & META_A11Y_SLOW_KEYS_BEEP_ACCEPT) meta_input_device_native_bell_notify (device); return G_SOURCE_REMOVE; } static int find_pending_event_by_keycode (gconstpointer a, gconstpointer b) { const SlowKeysEventPending *pa = a; const ClutterKeyEvent *ka = (ClutterKeyEvent *) pa->event; const ClutterKeyEvent *kb = b; return kb->hardware_keycode - ka->hardware_keycode; } static GSource * timeout_source_new (MetaSeatImpl *seat_impl, guint interval, GSourceFunc func, gpointer user_data) { GSource *source; source = g_timeout_source_new (interval); g_source_set_callback (source, func, user_data, NULL); g_source_attach (source, seat_impl->input_context); g_source_unref (source); return source; } static gboolean start_slow_keys (ClutterEvent *event, MetaInputDeviceNative *device) { SlowKeysEventPending *slow_keys_event; ClutterKeyEvent *key_event = (ClutterKeyEvent *) event; if (key_event->flags & CLUTTER_EVENT_FLAG_REPEATED) return TRUE; slow_keys_event = g_new0 (SlowKeysEventPending, 1); slow_keys_event->device = device; slow_keys_event->event = clutter_event_copy (event); slow_keys_event->timer = timeout_source_new (device->seat_impl, get_slow_keys_delay (CLUTTER_INPUT_DEVICE (device)), trigger_slow_keys, slow_keys_event); device->slow_keys_list = g_list_append (device->slow_keys_list, slow_keys_event); if (device->a11y_flags & META_A11Y_SLOW_KEYS_BEEP_PRESS) meta_input_device_native_bell_notify (device); return TRUE; } static gboolean stop_slow_keys (ClutterEvent *event, MetaInputDeviceNative *device) { GList *item; /* Check if we have a slow key event queued for this key event */ item = g_list_find_custom (device->slow_keys_list, event, find_pending_event_by_keycode); if (item) { SlowKeysEventPending *slow_keys_event = item->data; device->slow_keys_list = g_list_delete_link (device->slow_keys_list, item); meta_input_device_native_free_pending_slow_key (slow_keys_event); if (device->a11y_flags & META_A11Y_SLOW_KEYS_BEEP_REJECT) meta_input_device_native_bell_notify (device); return TRUE; } /* If no key press event was pending, just emit the key release as-is */ return FALSE; } static guint get_debounce_delay (ClutterInputDevice *device) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); MetaKbdA11ySettings a11y_settings; MetaInputSettings *input_settings; input_settings = meta_seat_impl_get_input_settings (device_native->seat_impl); meta_input_settings_get_kbd_a11y_settings (input_settings, &a11y_settings); /* Settings use int, we use uint, make sure we dont go negative */ return MAX (0, a11y_settings.debounce_delay); } static gboolean clear_bounce_keys (gpointer data) { MetaInputDeviceNative *device = data; device->debounce_key = 0; device->debounce_timer = 0; return G_SOURCE_REMOVE; } static void start_bounce_keys (ClutterEvent *event, MetaInputDeviceNative *device) { stop_bounce_keys (device); device->debounce_key = ((ClutterKeyEvent *) event)->hardware_keycode; device->debounce_timer = timeout_source_new (device->seat_impl, get_debounce_delay (CLUTTER_INPUT_DEVICE (device)), clear_bounce_keys, device); } static void stop_bounce_keys (MetaInputDeviceNative *device) { g_clear_pointer (&device->debounce_timer, g_source_destroy); } static void notify_bounce_keys_reject (MetaInputDeviceNative *device) { if (device->a11y_flags & META_A11Y_BOUNCE_KEYS_BEEP_REJECT) meta_input_device_native_bell_notify (device); } static gboolean debounce_key (ClutterEvent *event, MetaInputDeviceNative *device) { return (device->debounce_key == ((ClutterKeyEvent *) event)->hardware_keycode); } static gboolean key_event_is_modifier (ClutterEvent *event) { switch (event->key.keyval) { case XKB_KEY_Shift_L: case XKB_KEY_Shift_R: case XKB_KEY_Control_L: case XKB_KEY_Control_R: case XKB_KEY_Alt_L: case XKB_KEY_Alt_R: case XKB_KEY_Meta_L: case XKB_KEY_Meta_R: case XKB_KEY_Super_L: case XKB_KEY_Super_R: case XKB_KEY_Hyper_L: case XKB_KEY_Hyper_R: case XKB_KEY_Caps_Lock: case XKB_KEY_Shift_Lock: return TRUE; default: return FALSE; } } static void notify_stickykeys_mask (MetaInputDeviceNative *device) { meta_seat_impl_notify_kbd_a11y_mods_state_changed_in_impl (device->seat_impl, device->stickykeys_latched_mask, device->stickykeys_locked_mask); } static void update_internal_xkb_state (MetaInputDeviceNative *device, xkb_mod_mask_t new_latched_mask, xkb_mod_mask_t new_locked_mask) { MetaSeatImpl *seat_impl = device->seat_impl; xkb_mod_mask_t depressed_mods; xkb_mod_mask_t latched_mods; xkb_mod_mask_t locked_mods; xkb_mod_mask_t group_mods; struct xkb_state *xkb_state; g_rw_lock_writer_lock (&seat_impl->state_lock); xkb_state = meta_seat_impl_get_xkb_state_in_impl (seat_impl); depressed_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_DEPRESSED); latched_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_LATCHED); locked_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_LOCKED); latched_mods &= ~device->stickykeys_latched_mask; locked_mods &= ~device->stickykeys_locked_mask; device->stickykeys_latched_mask = new_latched_mask; device->stickykeys_locked_mask = new_locked_mask; latched_mods |= device->stickykeys_latched_mask; locked_mods |= device->stickykeys_locked_mask; group_mods = xkb_state_serialize_layout (xkb_state, XKB_STATE_LAYOUT_EFFECTIVE); xkb_state_update_mask (xkb_state, depressed_mods, latched_mods, locked_mods, 0, 0, group_mods); notify_stickykeys_mask (device); g_rw_lock_writer_unlock (&seat_impl->state_lock); } static void update_stickykeys_event (ClutterEvent *event, MetaInputDeviceNative *device, xkb_mod_mask_t new_latched_mask, xkb_mod_mask_t new_locked_mask) { MetaSeatImpl *seat_impl = device->seat_impl; xkb_mod_mask_t effective_mods; xkb_mod_mask_t latched_mods; xkb_mod_mask_t locked_mods; struct xkb_state *xkb_state; update_internal_xkb_state (device, new_latched_mask, new_locked_mask); xkb_state = meta_seat_impl_get_xkb_state_in_impl (seat_impl); effective_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_EFFECTIVE); latched_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_LATCHED); locked_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_LOCKED); _clutter_event_set_state_full (event, seat_impl->button_state, device->stickykeys_depressed_mask, latched_mods, locked_mods, effective_mods | seat_impl->button_state); } static void notify_stickykeys_change (MetaInputDeviceNative *device) { /* Every time sticky keys setting is changed, clear the masks */ device->stickykeys_depressed_mask = 0; update_internal_xkb_state (device, 0, 0); meta_seat_impl_notify_kbd_a11y_flags_changed_in_impl (device->seat_impl, device->a11y_flags, META_A11Y_STICKY_KEYS_ENABLED); } static void set_stickykeys_off (MetaInputDeviceNative *device) { device->a11y_flags &= ~META_A11Y_STICKY_KEYS_ENABLED; notify_stickykeys_change (device); } static void set_stickykeys_on (MetaInputDeviceNative *device) { device->a11y_flags |= META_A11Y_STICKY_KEYS_ENABLED; notify_stickykeys_change (device); } static void clear_stickykeys_event (ClutterEvent *event, MetaInputDeviceNative *device) { set_stickykeys_off (device); update_stickykeys_event (event, device, 0, 0); } static void set_slowkeys_off (MetaInputDeviceNative *device) { device->a11y_flags &= ~META_A11Y_SLOW_KEYS_ENABLED; meta_seat_impl_notify_kbd_a11y_flags_changed_in_impl (device->seat_impl, device->a11y_flags, META_A11Y_SLOW_KEYS_ENABLED); } static void set_slowkeys_on (MetaInputDeviceNative *device) { device->a11y_flags |= META_A11Y_SLOW_KEYS_ENABLED; meta_seat_impl_notify_kbd_a11y_flags_changed_in_impl (device->seat_impl, device->a11y_flags, META_A11Y_SLOW_KEYS_ENABLED); } static void handle_stickykeys_press (ClutterEvent *event, MetaInputDeviceNative *device) { MetaSeatImpl *seat_impl = device->seat_impl; xkb_mod_mask_t depressed_mods; xkb_mod_mask_t new_latched_mask; xkb_mod_mask_t new_locked_mask; struct xkb_state *xkb_state; if (!key_event_is_modifier (event)) return; if (device->stickykeys_depressed_mask && (device->a11y_flags & META_A11Y_STICKY_KEYS_TWO_KEY_OFF)) { clear_stickykeys_event (event, device); return; } xkb_state = meta_seat_impl_get_xkb_state_in_impl (seat_impl); depressed_mods = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_DEPRESSED); /* Ignore the lock modifier mask, that one cannot be sticky, yet the * CAPS_LOCK key itself counts as a modifier as it might be remapped * to some other modifier which can be sticky. */ depressed_mods &= ~CLUTTER_LOCK_MASK; new_latched_mask = device->stickykeys_latched_mask; new_locked_mask = device->stickykeys_locked_mask; device->stickykeys_depressed_mask = depressed_mods; if (new_locked_mask & depressed_mods) { new_locked_mask &= ~depressed_mods; } else if (new_latched_mask & depressed_mods) { new_locked_mask |= depressed_mods; new_latched_mask &= ~depressed_mods; } else { new_latched_mask |= depressed_mods; } update_stickykeys_event (event, device, new_latched_mask, new_locked_mask); } static void handle_stickykeys_release (ClutterEvent *event, MetaInputDeviceNative *device) { MetaSeatImpl *seat_impl = device->seat_impl; struct xkb_state *xkb_state; xkb_state = meta_seat_impl_get_xkb_state_in_impl (seat_impl); device->stickykeys_depressed_mask = xkb_state_serialize_mods (xkb_state, XKB_STATE_MODS_DEPRESSED); if (key_event_is_modifier (event)) { if (device->a11y_flags & META_A11Y_STICKY_KEYS_BEEP) meta_input_device_native_bell_notify (device); return; } if (device->stickykeys_latched_mask == 0) return; update_stickykeys_event (event, device, 0, device->stickykeys_locked_mask); } static gboolean trigger_toggle_slowkeys (gpointer data) { MetaInputDeviceNative *device = data; device->toggle_slowkeys_timer = 0; if (device->a11y_flags & META_A11Y_FEATURE_STATE_CHANGE_BEEP) meta_input_device_native_bell_notify (device); if (device->a11y_flags & META_A11Y_SLOW_KEYS_ENABLED) set_slowkeys_off (device); else set_slowkeys_on (device); return G_SOURCE_REMOVE; } static void start_toggle_slowkeys (MetaInputDeviceNative *device) { if (device->toggle_slowkeys_timer != 0) return; device->toggle_slowkeys_timer = timeout_source_new (device->seat_impl, 8 * 1000 /* 8 secs */, trigger_toggle_slowkeys, device); } static void stop_toggle_slowkeys (MetaInputDeviceNative *device) { g_clear_pointer (&device->toggle_slowkeys_timer, g_source_destroy); } static void handle_enablekeys_press (ClutterEvent *event, MetaInputDeviceNative *device) { if (event->key.keyval == XKB_KEY_Shift_L || event->key.keyval == XKB_KEY_Shift_R) { start_toggle_slowkeys (device); if (event->key.time > device->last_shift_time + 15 * 1000 /* 15 secs */) device->shift_count = 1; else device->shift_count++; device->last_shift_time = event->key.time; } else { device->shift_count = 0; stop_toggle_slowkeys (device); } } static void handle_enablekeys_release (ClutterEvent *event, MetaInputDeviceNative *device) { if (event->key.keyval == XKB_KEY_Shift_L || event->key.keyval == XKB_KEY_Shift_R) { stop_toggle_slowkeys (device); if (device->shift_count >= 5) { device->shift_count = 0; if (device->a11y_flags & META_A11Y_FEATURE_STATE_CHANGE_BEEP) meta_input_device_native_bell_notify (device); if (device->a11y_flags & META_A11Y_STICKY_KEYS_ENABLED) set_stickykeys_off (device); else set_stickykeys_on (device); } } } static int get_button_index (int button) { switch (button) { case CLUTTER_BUTTON_PRIMARY: return 0; case CLUTTER_BUTTON_MIDDLE: return 1; case CLUTTER_BUTTON_SECONDARY: return 2; default: break; } g_warn_if_reached (); return 0; } static void emulate_button_press (MetaInputDeviceNative *device_evdev) { ClutterInputDevice *device = CLUTTER_INPUT_DEVICE (device_evdev); int btn = device_evdev->mousekeys_btn; if (device_evdev->mousekeys_btn_states[get_button_index (btn)]) return; clutter_virtual_input_device_notify_button (device->accessibility_virtual_device, g_get_monotonic_time (), btn, CLUTTER_BUTTON_STATE_PRESSED); device_evdev->mousekeys_btn_states[get_button_index (btn)] = CLUTTER_BUTTON_STATE_PRESSED; } static void emulate_button_release (MetaInputDeviceNative *device_evdev) { ClutterInputDevice *device = CLUTTER_INPUT_DEVICE (device_evdev); int btn = device_evdev->mousekeys_btn; if (device_evdev->mousekeys_btn_states[get_button_index (btn)] == CLUTTER_BUTTON_STATE_RELEASED) return; clutter_virtual_input_device_notify_button (device->accessibility_virtual_device, g_get_monotonic_time (), btn, CLUTTER_BUTTON_STATE_RELEASED); device_evdev->mousekeys_btn_states[get_button_index (btn)] = CLUTTER_BUTTON_STATE_RELEASED; } static void emulate_button_click (MetaInputDeviceNative *device) { emulate_button_press (device); emulate_button_release (device); } #define MOUSEKEYS_CURVE (1.0 + (((double) 50.0) * 0.001)) static void update_mousekeys_params (MetaInputDeviceNative *device, MetaKbdA11ySettings *settings) { /* Prevent us from broken settings values */ device->mousekeys_max_speed = MAX (1, settings->mousekeys_max_speed); device->mousekeys_accel_time = MAX (1, settings->mousekeys_accel_time); device->mousekeys_init_delay = MAX (0, settings->mousekeys_init_delay); device->mousekeys_curve_factor = (((double) device->mousekeys_max_speed) / pow ((double) device->mousekeys_accel_time, MOUSEKEYS_CURVE)); } static double mousekeys_get_speed_factor (MetaInputDeviceNative *device, uint64_t time_us) { uint32_t time; int64_t delta_t; int64_t init_time; double speed; time = us2ms (time_us); if (device->mousekeys_first_motion_time == 0) { /* Start acceleration _after_ the first move, so take * mousekeys_init_delay into account for t0 */ device->mousekeys_first_motion_time = time + device->mousekeys_init_delay; device->mousekeys_last_motion_time = device->mousekeys_first_motion_time; return 1.0; } init_time = time - device->mousekeys_first_motion_time; delta_t = time - device->mousekeys_last_motion_time; if (delta_t < 0) return 0.0; if (init_time < device->mousekeys_accel_time) speed = (double) (device->mousekeys_curve_factor * pow ((double) init_time, MOUSEKEYS_CURVE) * delta_t / 1000.0); else speed = (double) (device->mousekeys_max_speed * delta_t / 1000.0); device->mousekeys_last_motion_time = time; return speed; } #undef MOUSEKEYS_CURVE static void emulate_pointer_motion (MetaInputDeviceNative *device_evdev, int dx, int dy) { ClutterInputDevice *device = CLUTTER_INPUT_DEVICE (device_evdev); double dx_motion; double dy_motion; double speed; int64_t time_us; time_us = g_get_monotonic_time (); speed = mousekeys_get_speed_factor (device_evdev, time_us); if (dx < 0) dx_motion = floor (((double) dx) * speed); else dx_motion = ceil (((double) dx) * speed); if (dy < 0) dy_motion = floor (((double) dy) * speed); else dy_motion = ceil (((double) dy) * speed); clutter_virtual_input_device_notify_relative_motion (device->accessibility_virtual_device, time_us, dx_motion, dy_motion); } static gboolean is_numlock_active (MetaInputDeviceNative *device) { MetaSeatImpl *seat_impl = device->seat_impl; struct xkb_state *xkb_state; xkb_state = meta_seat_impl_get_xkb_state_in_impl (seat_impl); return xkb_state_mod_name_is_active (xkb_state, "Mod2", XKB_STATE_MODS_LOCKED); } static void enable_mousekeys (MetaInputDeviceNative *device_evdev) { ClutterInputDevice *device = CLUTTER_INPUT_DEVICE (device_evdev); device_evdev->mousekeys_btn = CLUTTER_BUTTON_PRIMARY; device_evdev->move_mousekeys_timer = 0; device_evdev->mousekeys_first_motion_time = 0; device_evdev->mousekeys_last_motion_time = 0; device_evdev->last_mousekeys_key = 0; if (device->accessibility_virtual_device) return; device->accessibility_virtual_device = clutter_seat_create_virtual_device (clutter_input_device_get_seat (device), CLUTTER_POINTER_DEVICE); } static void disable_mousekeys (MetaInputDeviceNative *device_evdev) { ClutterInputDevice *device = CLUTTER_INPUT_DEVICE (device_evdev); stop_mousekeys_move (device_evdev); /* Make sure we don't leave button pressed behind... */ if (device_evdev->mousekeys_btn_states[get_button_index (CLUTTER_BUTTON_PRIMARY)]) { device_evdev->mousekeys_btn = CLUTTER_BUTTON_PRIMARY; emulate_button_release (device_evdev); } if (device_evdev->mousekeys_btn_states[get_button_index (CLUTTER_BUTTON_MIDDLE)]) { device_evdev->mousekeys_btn = CLUTTER_BUTTON_MIDDLE; emulate_button_release (device_evdev); } if (device_evdev->mousekeys_btn_states[get_button_index (CLUTTER_BUTTON_SECONDARY)]) { device_evdev->mousekeys_btn = CLUTTER_BUTTON_SECONDARY; emulate_button_release (device_evdev); } if (device->accessibility_virtual_device) g_clear_object (&device->accessibility_virtual_device); } static gboolean trigger_mousekeys_move (gpointer data) { MetaInputDeviceNative *device = data; int dx = 0; int dy = 0; if (device->mousekeys_first_motion_time == 0) { /* This is the first move, Secdule at mk_init_delay */ device->move_mousekeys_timer = timeout_source_new (device->seat_impl, device->mousekeys_init_delay, trigger_mousekeys_move, device); } else { /* More moves, reschedule at mk_interval */ device->move_mousekeys_timer = timeout_source_new (device->seat_impl, 100, /* msec between mousekey events */ trigger_mousekeys_move, device); } /* Pointer motion */ switch (device->last_mousekeys_key) { case XKB_KEY_KP_Home: case XKB_KEY_KP_7: case XKB_KEY_KP_Up: case XKB_KEY_KP_8: case XKB_KEY_KP_Page_Up: case XKB_KEY_KP_9: dy = -1; break; case XKB_KEY_KP_End: case XKB_KEY_KP_1: case XKB_KEY_KP_Down: case XKB_KEY_KP_2: case XKB_KEY_KP_Page_Down: case XKB_KEY_KP_3: dy = 1; break; default: break; } switch (device->last_mousekeys_key) { case XKB_KEY_KP_Home: case XKB_KEY_KP_7: case XKB_KEY_KP_Left: case XKB_KEY_KP_4: case XKB_KEY_KP_End: case XKB_KEY_KP_1: dx = -1; break; case XKB_KEY_KP_Page_Up: case XKB_KEY_KP_9: case XKB_KEY_KP_Right: case XKB_KEY_KP_6: case XKB_KEY_KP_Page_Down: case XKB_KEY_KP_3: dx = 1; break; default: break; } if (dx != 0 || dy != 0) emulate_pointer_motion (device, dx, dy); /* We reschedule each time */ return G_SOURCE_REMOVE; } static void stop_mousekeys_move (MetaInputDeviceNative *device) { device->mousekeys_first_motion_time = 0; device->mousekeys_last_motion_time = 0; g_clear_pointer (&device->move_mousekeys_timer, g_source_destroy); } static void start_mousekeys_move (ClutterEvent *event, MetaInputDeviceNative *device) { device->last_mousekeys_key = event->key.keyval; if (device->move_mousekeys_timer != 0) return; trigger_mousekeys_move (device); } static gboolean handle_mousekeys_press (ClutterEvent *event, MetaInputDeviceNative *device) { if (!(event->key.flags & CLUTTER_EVENT_FLAG_SYNTHETIC)) stop_mousekeys_move (device); /* Do not handle mousekeys if NumLock is ON */ if (is_numlock_active (device)) return FALSE; /* Button selection */ switch (event->key.keyval) { case XKB_KEY_KP_Divide: device->mousekeys_btn = CLUTTER_BUTTON_PRIMARY; return TRUE; case XKB_KEY_KP_Multiply: device->mousekeys_btn = CLUTTER_BUTTON_MIDDLE; return TRUE; case XKB_KEY_KP_Subtract: device->mousekeys_btn = CLUTTER_BUTTON_SECONDARY; return TRUE; default: break; } /* Button events */ switch (event->key.keyval) { case XKB_KEY_KP_Begin: case XKB_KEY_KP_5: emulate_button_click (device); return TRUE; case XKB_KEY_KP_Insert: case XKB_KEY_KP_0: emulate_button_press (device); return TRUE; case XKB_KEY_KP_Decimal: case XKB_KEY_KP_Delete: emulate_button_release (device); return TRUE; case XKB_KEY_KP_Add: emulate_button_click (device); emulate_button_click (device); return TRUE; default: break; } /* Pointer motion */ switch (event->key.keyval) { case XKB_KEY_KP_1: case XKB_KEY_KP_2: case XKB_KEY_KP_3: case XKB_KEY_KP_4: case XKB_KEY_KP_6: case XKB_KEY_KP_7: case XKB_KEY_KP_8: case XKB_KEY_KP_9: case XKB_KEY_KP_Down: case XKB_KEY_KP_End: case XKB_KEY_KP_Home: case XKB_KEY_KP_Left: case XKB_KEY_KP_Page_Down: case XKB_KEY_KP_Page_Up: case XKB_KEY_KP_Right: case XKB_KEY_KP_Up: start_mousekeys_move (event, device); return TRUE; default: break; } return FALSE; } static gboolean handle_mousekeys_release (ClutterEvent *event, MetaInputDeviceNative *device) { /* Do not handle mousekeys if NumLock is ON */ if (is_numlock_active (device)) return FALSE; switch (event->key.keyval) { case XKB_KEY_KP_0: case XKB_KEY_KP_1: case XKB_KEY_KP_2: case XKB_KEY_KP_3: case XKB_KEY_KP_4: case XKB_KEY_KP_5: case XKB_KEY_KP_6: case XKB_KEY_KP_7: case XKB_KEY_KP_8: case XKB_KEY_KP_9: case XKB_KEY_KP_Add: case XKB_KEY_KP_Begin: case XKB_KEY_KP_Decimal: case XKB_KEY_KP_Delete: case XKB_KEY_KP_Divide: case XKB_KEY_KP_Down: case XKB_KEY_KP_End: case XKB_KEY_KP_Home: case XKB_KEY_KP_Insert: case XKB_KEY_KP_Left: case XKB_KEY_KP_Multiply: case XKB_KEY_KP_Page_Down: case XKB_KEY_KP_Page_Up: case XKB_KEY_KP_Right: case XKB_KEY_KP_Subtract: case XKB_KEY_KP_Up: stop_mousekeys_move (device); return TRUE; default: break; } return FALSE; } gboolean meta_input_device_native_process_kbd_a11y_event_in_impl (ClutterInputDevice *device, ClutterEvent *event) { MetaInputDeviceNative *device_evdev = META_INPUT_DEVICE_NATIVE (device); if (device_evdev->a11y_flags & META_A11Y_KEYBOARD_ENABLED) { if (event->type == CLUTTER_KEY_PRESS) handle_enablekeys_press (event, device_evdev); else handle_enablekeys_release (event, device_evdev); } if (device_evdev->a11y_flags & META_A11Y_MOUSE_KEYS_ENABLED) { if (event->type == CLUTTER_KEY_PRESS && handle_mousekeys_press (event, device_evdev)) return TRUE; /* swallow event */ if (event->type == CLUTTER_KEY_RELEASE && handle_mousekeys_release (event, device_evdev)) return TRUE; /* swallow event */ } if ((device_evdev->a11y_flags & META_A11Y_BOUNCE_KEYS_ENABLED) && (get_debounce_delay (device) != 0)) { if ((event->type == CLUTTER_KEY_PRESS) && debounce_key (event, device_evdev)) { notify_bounce_keys_reject (device_evdev); return TRUE; } else if (event->type == CLUTTER_KEY_RELEASE) start_bounce_keys (event, device_evdev); } if ((device_evdev->a11y_flags & META_A11Y_SLOW_KEYS_ENABLED) && (get_slow_keys_delay (device) != 0)) { if (event->type == CLUTTER_KEY_PRESS) return start_slow_keys (event, device_evdev); else if (event->type == CLUTTER_KEY_RELEASE) return stop_slow_keys (event, device_evdev); } if (device_evdev->a11y_flags & META_A11Y_STICKY_KEYS_ENABLED) { if (event->type == CLUTTER_KEY_PRESS) handle_stickykeys_press (event, device_evdev); else if (event->type == CLUTTER_KEY_RELEASE) handle_stickykeys_release (event, device_evdev); } return FALSE; } void meta_input_device_native_apply_kbd_a11y_settings_in_impl (MetaInputDeviceNative *device, MetaKbdA11ySettings *settings) { MetaKeyboardA11yFlags changed_flags = (device->a11y_flags ^ settings->controls); if (changed_flags & (META_A11Y_KEYBOARD_ENABLED | META_A11Y_SLOW_KEYS_ENABLED)) clear_slow_keys (device); if (changed_flags & (META_A11Y_KEYBOARD_ENABLED | META_A11Y_BOUNCE_KEYS_ENABLED)) device->debounce_key = 0; if (changed_flags & (META_A11Y_KEYBOARD_ENABLED | META_A11Y_STICKY_KEYS_ENABLED)) { device->stickykeys_depressed_mask = 0; update_internal_xkb_state (device, 0, 0); } if (changed_flags & META_A11Y_KEYBOARD_ENABLED) { device->toggle_slowkeys_timer = 0; device->shift_count = 0; device->last_shift_time = 0; } if (changed_flags & (META_A11Y_KEYBOARD_ENABLED | META_A11Y_MOUSE_KEYS_ENABLED)) { if (settings->controls & (META_A11Y_KEYBOARD_ENABLED | META_A11Y_MOUSE_KEYS_ENABLED)) enable_mousekeys (device); else disable_mousekeys (device); } update_mousekeys_params (device, settings); /* Keep our own copy of keyboard a11y features flags to see what changes */ device->a11y_flags = settings->controls; } void meta_input_device_native_a11y_maybe_notify_toggle_keys_in_impl (MetaInputDeviceNative *device) { if (device->a11y_flags & META_A11Y_TOGGLE_KEYS_ENABLED) meta_input_device_native_bell_notify (device); } static void meta_input_device_native_class_init (MetaInputDeviceNativeClass *klass) { ClutterInputDeviceClass *device_class = CLUTTER_INPUT_DEVICE_CLASS (klass); GObjectClass *object_class = G_OBJECT_CLASS (klass); object_class->finalize = meta_input_device_native_finalize; object_class->set_property = meta_input_device_native_set_property; object_class->get_property = meta_input_device_native_get_property; device_class->is_mode_switch_button = meta_input_device_native_is_mode_switch_button; device_class->get_group_n_modes = meta_input_device_native_get_group_n_modes; device_class->is_grouped = meta_input_device_native_is_grouped; device_class->get_pad_feature_group = meta_input_device_native_get_pad_feature_group; obj_props[PROP_DEVICE_MATRIX] = g_param_spec_boxed ("device-matrix", "Device input matrix", "Device input matrix", CAIRO_GOBJECT_TYPE_MATRIX, CLUTTER_PARAM_READWRITE); obj_props[PROP_OUTPUT_ASPECT_RATIO] = g_param_spec_double ("output-aspect-ratio", "Output aspect ratio", "Output aspect ratio", 0, G_MAXDOUBLE, 0, CLUTTER_PARAM_READWRITE); g_object_class_install_properties (object_class, N_PROPS, obj_props); } static void meta_input_device_native_init (MetaInputDeviceNative *self) { cairo_matrix_init_identity (&self->device_matrix); self->device_aspect_ratio = 0; self->output_ratio = 0; } static void update_pad_features (MetaInputDeviceNative *device_native) { ClutterInputDevice *device = CLUTTER_INPUT_DEVICE (device_native); struct libinput_device *libinput_device; struct libinput_tablet_pad_mode_group *mode_group; int n_groups, n_buttons, n_rings, n_strips, n_modes, i, j; libinput_device = meta_input_device_native_get_libinput_device (device); n_rings = libinput_device_tablet_pad_get_num_rings (libinput_device); n_strips = libinput_device_tablet_pad_get_num_strips (libinput_device); n_groups = libinput_device_tablet_pad_get_num_mode_groups (libinput_device); n_buttons = libinput_device_tablet_pad_get_num_buttons (libinput_device); device_native->pad_features = g_array_new (FALSE, FALSE, sizeof (PadFeature)); device_native->modes = g_array_sized_new (FALSE, FALSE, sizeof (int), n_groups); for (i = 0; i < n_groups; i++) { mode_group = libinput_device_tablet_pad_get_mode_group (libinput_device, i); n_modes = libinput_tablet_pad_mode_group_get_num_modes (mode_group); g_array_append_val (device_native->modes, n_modes); for (j = 0; j < n_buttons; j++) { gboolean is_mode_switch = libinput_tablet_pad_mode_group_button_is_toggle (mode_group, j) != 0; PadFeature feature = { CLUTTER_PAD_FEATURE_BUTTON, j, i, is_mode_switch }; if (libinput_tablet_pad_mode_group_has_button (mode_group, j)) g_array_append_val (device_native->pad_features, feature); } for (j = 0; j < n_rings; j++) { PadFeature feature = { CLUTTER_PAD_FEATURE_RING, j, i }; if (libinput_tablet_pad_mode_group_has_ring (mode_group, j)) g_array_append_val (device_native->pad_features, feature); } for (j = 0; j < n_strips; j++) { PadFeature feature = { CLUTTER_PAD_FEATURE_STRIP, j, i }; if (libinput_tablet_pad_mode_group_has_strip (mode_group, j)) g_array_append_val (device_native->pad_features, feature); } } } /* * meta_input_device_native_new: * @manager: the device manager * @seat: the seat the device will belong to * @libinput_device: the libinput device * * Create a new ClutterInputDevice given a libinput device and associate * it with the provided seat. */ ClutterInputDevice * meta_input_device_native_new_in_impl (MetaSeatImpl *seat_impl, struct libinput_device *libinput_device) { MetaInputDeviceNative *device; ClutterInputDeviceType type; char *vendor, *product; int n_rings = 0, n_strips = 0, n_groups = 1, n_buttons = 0; char *node_path; double width, height; type = meta_input_device_native_determine_type_in_impl (libinput_device); vendor = g_strdup_printf ("%.4x", libinput_device_get_id_vendor (libinput_device)); product = g_strdup_printf ("%.4x", libinput_device_get_id_product (libinput_device)); node_path = g_strdup_printf ("/dev/input/%s", libinput_device_get_sysname (libinput_device)); if (libinput_device_has_capability (libinput_device, LIBINPUT_DEVICE_CAP_TABLET_PAD)) { n_rings = libinput_device_tablet_pad_get_num_rings (libinput_device); n_strips = libinput_device_tablet_pad_get_num_strips (libinput_device); n_groups = libinput_device_tablet_pad_get_num_mode_groups (libinput_device); n_buttons = libinput_device_tablet_pad_get_num_buttons (libinput_device); } device = g_object_new (META_TYPE_INPUT_DEVICE_NATIVE, "name", libinput_device_get_name (libinput_device), "device-type", type, "device-mode", CLUTTER_INPUT_MODE_PHYSICAL, "vendor-id", vendor, "product-id", product, "n-rings", n_rings, "n-strips", n_strips, "n-mode-groups", n_groups, "n-buttons", n_buttons, "device-node", node_path, "seat", seat_impl->seat_native, NULL); device->seat_impl = seat_impl; device->libinput_device = libinput_device; libinput_device_set_user_data (libinput_device, device); libinput_device_ref (libinput_device); g_free (vendor); g_free (product); g_free (node_path); if (libinput_device_has_capability (libinput_device, LIBINPUT_DEVICE_CAP_TABLET_PAD)) update_pad_features (device); if (libinput_device_get_size (libinput_device, &width, &height) == 0) device->device_aspect_ratio = width / height; device->group = (intptr_t) libinput_device_get_device_group (libinput_device); return CLUTTER_INPUT_DEVICE (device); } /* * meta_input_device_native_new_virtual: * @seat: the seat the device will belong to * @type: the input device type * * Create a new virtual ClutterInputDevice of the given type. */ ClutterInputDevice * meta_input_device_native_new_virtual (MetaSeatImpl *seat_impl, ClutterInputDeviceType type, ClutterInputMode mode) { MetaInputDeviceNative *device; const char *name; switch (type) { case CLUTTER_KEYBOARD_DEVICE: name = "Virtual keyboard device for seat"; break; case CLUTTER_POINTER_DEVICE: name = "Virtual pointer device for seat"; break; case CLUTTER_TOUCHSCREEN_DEVICE: name = "Virtual touchscreen device for seat"; break; default: name = "Virtual device for seat"; break; }; device = g_object_new (META_TYPE_INPUT_DEVICE_NATIVE, "name", name, "device-type", type, "device-mode", mode, "seat", seat_impl->seat_native, NULL); device->seat_impl = seat_impl; return CLUTTER_INPUT_DEVICE (device); } MetaSeatImpl * meta_input_device_native_get_seat_impl (MetaInputDeviceNative *device) { return device->seat_impl; } void meta_input_device_native_update_leds_in_impl (MetaInputDeviceNative *device, enum libinput_led leds) { if (!device->libinput_device) return; libinput_device_led_update (device->libinput_device, leds); } ClutterInputDeviceType meta_input_device_native_determine_type_in_impl (struct libinput_device *ldev) { /* This setting is specific to touchpads and alike, only in these * devices there is this additional layer of touch event interpretation. */ if (libinput_device_config_tap_get_finger_count (ldev) > 0) return CLUTTER_TOUCHPAD_DEVICE; else if (libinput_device_has_capability (ldev, LIBINPUT_DEVICE_CAP_TABLET_TOOL)) return CLUTTER_TABLET_DEVICE; else if (libinput_device_has_capability (ldev, LIBINPUT_DEVICE_CAP_TABLET_PAD)) return CLUTTER_PAD_DEVICE; else if (libinput_device_has_capability (ldev, LIBINPUT_DEVICE_CAP_POINTER)) return CLUTTER_POINTER_DEVICE; else if (libinput_device_has_capability (ldev, LIBINPUT_DEVICE_CAP_TOUCH)) return CLUTTER_TOUCHSCREEN_DEVICE; else if (libinput_device_has_capability (ldev, LIBINPUT_DEVICE_CAP_KEYBOARD)) return CLUTTER_KEYBOARD_DEVICE; else return CLUTTER_EXTENSION_DEVICE; } /** * meta_input_device_native_get_libinput_device: * @device: a #ClutterInputDevice * * Retrieves the libinput_device struct held in @device. * * Returns: The libinput_device struct * * Since: 1.20 * Stability: unstable **/ struct libinput_device * meta_input_device_native_get_libinput_device (ClutterInputDevice *device) { MetaInputDeviceNative *device_evdev; g_return_val_if_fail (META_IS_INPUT_DEVICE_NATIVE (device), NULL); device_evdev = META_INPUT_DEVICE_NATIVE (device); return device_evdev->libinput_device; } void meta_input_device_native_translate_coordinates_in_impl (ClutterInputDevice *device, MetaViewportInfo *viewports, float *x, float *y) { MetaInputDeviceNative *device_evdev = META_INPUT_DEVICE_NATIVE (device); double min_x = 0, min_y = 0, max_x = 1, max_y = 1; float stage_width, stage_height; double x_d, y_d; meta_viewport_info_get_extents (viewports, &stage_width, &stage_height); x_d = *x / stage_width; y_d = *y / stage_height; /* Apply aspect ratio */ if (device_evdev->output_ratio > 0 && device_evdev->device_aspect_ratio > 0) { double ratio = device_evdev->device_aspect_ratio / device_evdev->output_ratio; if (ratio > 1) x_d *= ratio; else if (ratio < 1) y_d *= 1 / ratio; } cairo_matrix_transform_point (&device_evdev->device_matrix, &min_x, &min_y); cairo_matrix_transform_point (&device_evdev->device_matrix, &max_x, &max_y); cairo_matrix_transform_point (&device_evdev->device_matrix, &x_d, &y_d); *x = CLAMP (x_d, MIN (min_x, max_x), MAX (min_x, max_x)) * stage_width; *y = CLAMP (y_d, MIN (min_y, max_y), MAX (min_y, max_y)) * stage_height; } MetaInputDeviceMapping meta_input_device_native_get_mapping_mode_in_impl (ClutterInputDevice *device) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); ClutterInputDeviceType device_type; g_return_val_if_fail (CLUTTER_IS_INPUT_DEVICE (device), META_INPUT_DEVICE_MAPPING_ABSOLUTE); device_type = clutter_input_device_get_device_type (device); g_return_val_if_fail (device_type == CLUTTER_TABLET_DEVICE || device_type == CLUTTER_PEN_DEVICE || device_type == CLUTTER_ERASER_DEVICE, META_INPUT_DEVICE_MAPPING_ABSOLUTE); return device_native->mapping_mode; } void meta_input_device_native_set_mapping_mode_in_impl (ClutterInputDevice *device, MetaInputDeviceMapping mapping) { MetaInputDeviceNative *device_native = META_INPUT_DEVICE_NATIVE (device); ClutterInputDeviceType device_type; g_return_if_fail (CLUTTER_IS_INPUT_DEVICE (device)); device_type = clutter_input_device_get_device_type (device); g_return_if_fail (device_type == CLUTTER_TABLET_DEVICE || device_type == CLUTTER_PEN_DEVICE || device_type == CLUTTER_ERASER_DEVICE); device_native->mapping_mode = mapping; } void meta_input_device_native_set_coords_in_impl (MetaInputDeviceNative *device_native, float x, float y) { device_native->pointer_x = x; device_native->pointer_y = y; } void meta_input_device_native_get_coords_in_impl (MetaInputDeviceNative *device_native, float *x, float *y) { if (x) *x = device_native->pointer_x; if (y) *y = device_native->pointer_y; } void meta_input_device_native_detach_libinput_in_impl (MetaInputDeviceNative *device_native) { g_clear_pointer (&device_native->libinput_device, libinput_device_unref); }