/* * Copyright © 2014 Jonas Ådahl * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ #include "config.h" #include #include #include "libinput-util.h" #include "litest.h" START_TEST(keyboard_seat_key_count) { const int num_devices = 4; struct litest_device *devices[num_devices]; struct libinput *libinput; struct libinput_event *ev; struct libinput_event_keyboard *kev; int i; int seat_key_count = 0; int expected_key_button_count = 0; char device_name[255]; libinput = litest_create_context(); for (i = 0; i < num_devices; ++i) { sprintf(device_name, "litest Generic keyboard (%d)", i); devices[i] = litest_add_device_with_overrides(libinput, LITEST_KEYBOARD, device_name, NULL, NULL, NULL); } litest_drain_events(libinput); for (i = 0; i < num_devices; ++i) litest_keyboard_key(devices[i], KEY_A, true); libinput_dispatch(libinput); while ((ev = libinput_get_event(libinput))) { kev = litest_is_keyboard_event(ev, KEY_A, LIBINPUT_KEY_STATE_PRESSED); ++expected_key_button_count; seat_key_count = libinput_event_keyboard_get_seat_key_count(kev); ck_assert_int_eq(expected_key_button_count, seat_key_count); libinput_event_destroy(ev); libinput_dispatch(libinput); } ck_assert_int_eq(seat_key_count, num_devices); for (i = 0; i < num_devices; ++i) litest_keyboard_key(devices[i], KEY_A, false); libinput_dispatch(libinput); while ((ev = libinput_get_event(libinput))) { kev = libinput_event_get_keyboard_event(ev); ck_assert_notnull(kev); ck_assert_int_eq(libinput_event_keyboard_get_key(kev), KEY_A); ck_assert_int_eq(libinput_event_keyboard_get_key_state(kev), LIBINPUT_KEY_STATE_RELEASED); --expected_key_button_count; seat_key_count = libinput_event_keyboard_get_seat_key_count(kev); ck_assert_int_eq(expected_key_button_count, seat_key_count); libinput_event_destroy(ev); libinput_dispatch(libinput); } ck_assert_int_eq(seat_key_count, 0); for (i = 0; i < num_devices; ++i) litest_delete_device(devices[i]); libinput_unref(libinput); } END_TEST START_TEST(keyboard_ignore_no_pressed_release) { struct litest_device *dev; struct libinput *unused_libinput; struct libinput *libinput; struct libinput_event *event; struct libinput_event_keyboard *kevent; int events[] = { EV_KEY, KEY_A, -1, -1, }; enum libinput_key_state *state; enum libinput_key_state expected_states[] = { LIBINPUT_KEY_STATE_PRESSED, LIBINPUT_KEY_STATE_RELEASED, }; /* We can't send pressed -> released -> pressed events using uinput * as such non-symmetric events are dropped. Work-around this by first * adding the test device to the tested context after having sent an * initial pressed event. */ unused_libinput = litest_create_context(); dev = litest_add_device_with_overrides(unused_libinput, LITEST_KEYBOARD, "Generic keyboard", NULL, NULL, events); litest_keyboard_key(dev, KEY_A, true); litest_drain_events(unused_libinput); libinput = litest_create_context(); libinput_path_add_device(libinput, libevdev_uinput_get_devnode(dev->uinput)); litest_drain_events(libinput); litest_keyboard_key(dev, KEY_A, false); litest_keyboard_key(dev, KEY_A, true); litest_keyboard_key(dev, KEY_A, false); libinput_dispatch(libinput); ARRAY_FOR_EACH(expected_states, state) { event = libinput_get_event(libinput); ck_assert_notnull(event); ck_assert_int_eq(libinput_event_get_type(event), LIBINPUT_EVENT_KEYBOARD_KEY); kevent = libinput_event_get_keyboard_event(event); ck_assert_int_eq(libinput_event_keyboard_get_key(kevent), KEY_A); ck_assert_int_eq(libinput_event_keyboard_get_key_state(kevent), *state); libinput_event_destroy(event); libinput_dispatch(libinput); } litest_assert_empty_queue(libinput); litest_delete_device(dev); libinput_unref(libinput); libinput_unref(unused_libinput); } END_TEST START_TEST(keyboard_key_auto_release) { struct libinput *libinput; struct litest_device *dev; struct libinput_event *event; enum libinput_event_type type; struct libinput_event_keyboard *kevent; struct { int code; int released; } keys[] = { { .code = KEY_A, }, { .code = KEY_S, }, { .code = KEY_D, }, { .code = KEY_G, }, { .code = KEY_Z, }, { .code = KEY_DELETE, }, { .code = KEY_F24, }, }; int events[2 * (ARRAY_LENGTH(keys) + 1)]; unsigned i; int key; int valid_code; /* Enable all tested keys on the device */ i = 0; while (i < 2 * ARRAY_LENGTH(keys)) { key = keys[i / 2].code; events[i++] = EV_KEY; events[i++] = key; } events[i++] = -1; events[i++] = -1; libinput = litest_create_context(); dev = litest_add_device_with_overrides(libinput, LITEST_KEYBOARD, "Generic keyboard", NULL, NULL, events); litest_drain_events(libinput); /* Send pressed events, without releasing */ for (i = 0; i < ARRAY_LENGTH(keys); ++i) { key = keys[i].code; litest_event(dev, EV_KEY, key, 1); litest_event(dev, EV_SYN, SYN_REPORT, 0); libinput_dispatch(libinput); event = libinput_get_event(libinput); kevent = litest_is_keyboard_event(event, key, LIBINPUT_KEY_STATE_PRESSED); libinput_event_destroy(event); } litest_drain_events(libinput); /* "Disconnect" device */ litest_delete_device(dev); /* Mark all released keys until device is removed */ while (1) { event = libinput_get_event(libinput); ck_assert_notnull(event); type = libinput_event_get_type(event); if (type == LIBINPUT_EVENT_DEVICE_REMOVED) { libinput_event_destroy(event); break; } ck_assert_int_eq(type, LIBINPUT_EVENT_KEYBOARD_KEY); kevent = libinput_event_get_keyboard_event(event); ck_assert_int_eq(libinput_event_keyboard_get_key_state(kevent), LIBINPUT_KEY_STATE_RELEASED); key = libinput_event_keyboard_get_key(kevent); valid_code = 0; for (i = 0; i < ARRAY_LENGTH(keys); ++i) { if (keys[i].code == key) { ck_assert_int_eq(keys[i].released, 0); keys[i].released = 1; valid_code = 1; } } ck_assert_int_eq(valid_code, 1); libinput_event_destroy(event); } /* Check that all pressed keys has been released. */ for (i = 0; i < ARRAY_LENGTH(keys); ++i) { ck_assert_int_eq(keys[i].released, 1); } libinput_unref(libinput); } END_TEST START_TEST(keyboard_has_key) { struct litest_device *dev = litest_current_device(); struct libinput_device *device = dev->libinput_device; unsigned int code; int evdev_has, libinput_has; ck_assert(libinput_device_has_capability( device, LIBINPUT_DEVICE_CAP_KEYBOARD)); for (code = 0; code < KEY_CNT; code++) { evdev_has = libevdev_has_event_code(dev->evdev, EV_KEY, code); libinput_has = libinput_device_keyboard_has_key(device, code); ck_assert_int_eq(evdev_has, libinput_has); } } END_TEST START_TEST(keyboard_keys_bad_device) { struct litest_device *dev = litest_current_device(); struct libinput_device *device = dev->libinput_device; unsigned int code; int has_key; if (libinput_device_has_capability(device, LIBINPUT_DEVICE_CAP_KEYBOARD)) return; for (code = 0; code < KEY_CNT; code++) { has_key = libinput_device_keyboard_has_key(device, code); ck_assert_int_eq(has_key, -1); } } END_TEST START_TEST(keyboard_time_usec) { struct litest_device *dev = litest_current_device(); struct libinput *li = dev->libinput; struct libinput_event_keyboard *kev; struct libinput_event *event; uint64_t time_usec; if (!libevdev_has_event_code(dev->evdev, EV_KEY, KEY_A)) return; litest_drain_events(dev->libinput); litest_keyboard_key(dev, KEY_A, true); litest_wait_for_event(li); event = libinput_get_event(li); kev = litest_is_keyboard_event(event, KEY_A, LIBINPUT_KEY_STATE_PRESSED); time_usec = libinput_event_keyboard_get_time_usec(kev); ck_assert_int_eq(libinput_event_keyboard_get_time(kev), (uint32_t) (time_usec / 1000)); libinput_event_destroy(event); litest_drain_events(dev->libinput); } END_TEST START_TEST(keyboard_no_buttons) { struct litest_device *dev = litest_current_device(); struct libinput *li = dev->libinput; struct libinput_event *event; int code; const char *name; litest_drain_events(dev->libinput); for (code = 0; code < KEY_MAX; code++) { if (!libevdev_has_event_code(dev->evdev, EV_KEY, code)) continue; name = libevdev_event_code_get_name(EV_KEY, code); if (!name || !strneq(name, "KEY_", 4)) continue; litest_keyboard_key(dev, code, true); litest_keyboard_key(dev, code, false); libinput_dispatch(li); event = libinput_get_event(li); litest_is_keyboard_event(event, code, LIBINPUT_KEY_STATE_PRESSED); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_keyboard_event(event, code, LIBINPUT_KEY_STATE_RELEASED); libinput_event_destroy(event); } } END_TEST START_TEST(keyboard_leds) { struct litest_device *dev = litest_current_device(); struct libinput_device *device = dev->libinput_device; /* we can't actually test the results here without physically * looking at the LEDs. So all we do is trigger the code for devices * with and without LEDs and check that it doesn't go boom */ libinput_device_led_update(device, LIBINPUT_LED_NUM_LOCK); libinput_device_led_update(device, LIBINPUT_LED_CAPS_LOCK); libinput_device_led_update(device, LIBINPUT_LED_SCROLL_LOCK); libinput_device_led_update(device, LIBINPUT_LED_NUM_LOCK| LIBINPUT_LED_CAPS_LOCK); libinput_device_led_update(device, LIBINPUT_LED_NUM_LOCK| LIBINPUT_LED_CAPS_LOCK | LIBINPUT_LED_SCROLL_LOCK); libinput_device_led_update(device, 0); libinput_device_led_update(device, -1); } END_TEST START_TEST(keyboard_no_scroll) { struct litest_device *dev = litest_current_device(); struct libinput_device *device = dev->libinput_device; enum libinput_config_scroll_method method; enum libinput_config_status status; method = libinput_device_config_scroll_get_method(device); ck_assert_int_eq(method, LIBINPUT_CONFIG_SCROLL_NO_SCROLL); method = libinput_device_config_scroll_get_default_method(device); ck_assert_int_eq(method, LIBINPUT_CONFIG_SCROLL_NO_SCROLL); status = libinput_device_config_scroll_set_method(device, LIBINPUT_CONFIG_SCROLL_2FG); ck_assert_int_eq(status, LIBINPUT_CONFIG_STATUS_UNSUPPORTED); status = libinput_device_config_scroll_set_method(device, LIBINPUT_CONFIG_SCROLL_EDGE); ck_assert_int_eq(status, LIBINPUT_CONFIG_STATUS_UNSUPPORTED); status = libinput_device_config_scroll_set_method(device, LIBINPUT_CONFIG_SCROLL_ON_BUTTON_DOWN); ck_assert_int_eq(status, LIBINPUT_CONFIG_STATUS_UNSUPPORTED); status = libinput_device_config_scroll_set_method(device, LIBINPUT_CONFIG_SCROLL_NO_SCROLL); ck_assert_int_eq(status, LIBINPUT_CONFIG_STATUS_SUCCESS); } END_TEST void litest_setup_tests_keyboard(void) { litest_add_no_device("keyboard:seat key count", keyboard_seat_key_count); litest_add_no_device("keyboard:key counting", keyboard_ignore_no_pressed_release); litest_add_no_device("keyboard:key counting", keyboard_key_auto_release); litest_add("keyboard:keys", keyboard_has_key, LITEST_KEYS, LITEST_ANY); litest_add("keyboard:keys", keyboard_keys_bad_device, LITEST_ANY, LITEST_ANY); litest_add("keyboard:time", keyboard_time_usec, LITEST_KEYS, LITEST_ANY); litest_add("keyboard:events", keyboard_no_buttons, LITEST_KEYS, LITEST_ANY); litest_add("keyboard:leds", keyboard_leds, LITEST_ANY, LITEST_ANY); litest_add("keyboard:scroll", keyboard_no_scroll, LITEST_KEYS, LITEST_WHEEL); }