libxkbcommon/test/state.c

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/*
* Copyright © 2012 Intel Corporation
*
* 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.
*
* Author: Daniel Stone <daniel@fooishbar.org>
*/
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <linux/input.h>
#include "test.h"
/* Offset between evdev keycodes (where KEY_ESCAPE is 1), and the evdev XKB
* keycode set (where ESC is 9). */
#define EVDEV_OFFSET 8
static void
print_state(struct xkb_state *state)
{
struct xkb_keymap *keymap;
xkb_layout_index_t group;
xkb_mod_index_t mod;
xkb_led_index_t led;
group = xkb_state_serialize_layout(state, XKB_STATE_LAYOUT_EFFECTIVE);
mod = xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE);
/* led = xkb_state_serialize_leds(state, XKB_STATE_LEDS); */
if (!group && !mod /* && !led */) {
fprintf(stderr, "\tno state\n");
return;
}
keymap = xkb_state_get_keymap(state);
for (group = 0; group < xkb_keymap_num_layouts(keymap); group++) {
if (xkb_state_layout_index_is_active(state, group,
XKB_STATE_LAYOUT_EFFECTIVE |
XKB_STATE_LAYOUT_DEPRESSED |
XKB_STATE_LAYOUT_LATCHED |
XKB_STATE_LAYOUT_LOCKED) <= 0)
continue;
fprintf(stderr, "\tgroup %s (%d): %s%s%s%s\n",
xkb_keymap_layout_get_name(keymap, group),
group,
xkb_state_layout_index_is_active(state, group, XKB_STATE_LAYOUT_EFFECTIVE) > 0 ?
"effective " : "",
xkb_state_layout_index_is_active(state, group, XKB_STATE_LAYOUT_DEPRESSED) > 0 ?
"depressed " : "",
xkb_state_layout_index_is_active(state, group, XKB_STATE_LAYOUT_LATCHED) > 0 ?
"latched " : "",
xkb_state_layout_index_is_active(state, group, XKB_STATE_LAYOUT_LOCKED) > 0 ?
"locked " : "");
}
for (mod = 0; mod < xkb_keymap_num_mods(keymap); mod++) {
if (xkb_state_mod_index_is_active(state, mod,
XKB_STATE_MODS_EFFECTIVE |
XKB_STATE_MODS_DEPRESSED |
XKB_STATE_MODS_LATCHED |
XKB_STATE_MODS_LOCKED) <= 0)
continue;
fprintf(stderr, "\tmod %s (%d): %s%s%s%s\n",
xkb_keymap_mod_get_name(keymap, mod),
mod,
xkb_state_mod_index_is_active(state, mod, XKB_STATE_MODS_EFFECTIVE) > 0 ?
"effective " : "",
xkb_state_mod_index_is_active(state, mod, XKB_STATE_MODS_DEPRESSED) > 0 ?
"depressed " : "",
xkb_state_mod_index_is_active(state, mod, XKB_STATE_MODS_LATCHED) > 0 ?
"latched " : "",
xkb_state_mod_index_is_active(state, mod, XKB_STATE_MODS_LOCKED) > 0 ?
"locked " : "");
}
for (led = 0; led < xkb_keymap_num_leds(keymap); led++) {
if (xkb_state_led_index_is_active(state, led) <= 0)
continue;
fprintf(stderr, "\tled %s (%d): active\n",
xkb_keymap_led_get_name(keymap, led),
led);
}
}
static void
test_update_key(struct xkb_keymap *keymap)
{
struct xkb_state *state = xkb_state_new(keymap);
const xkb_keysym_t *syms;
xkb_keysym_t one_sym;
int num_syms;
assert(state);
/* LCtrl down */
xkb_state_update_key(state, KEY_LEFTCTRL + EVDEV_OFFSET, XKB_KEY_DOWN);
fprintf(stderr, "dumping state for LCtrl down:\n");
print_state(state);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CTRL,
XKB_STATE_MODS_DEPRESSED) > 0);
/* LCtrl + RAlt down */
xkb_state_update_key(state, KEY_RIGHTALT + EVDEV_OFFSET, XKB_KEY_DOWN);
fprintf(stderr, "dumping state for LCtrl + RAlt down:\n");
print_state(state);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CTRL,
XKB_STATE_MODS_DEPRESSED) > 0);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_ALT,
XKB_STATE_MODS_DEPRESSED) > 0);
assert(xkb_state_mod_names_are_active(state, XKB_STATE_MODS_DEPRESSED,
XKB_STATE_MATCH_ALL,
XKB_MOD_NAME_CTRL,
XKB_MOD_NAME_ALT,
NULL) > 0);
assert(xkb_state_mod_indices_are_active(state, XKB_STATE_MODS_DEPRESSED,
XKB_STATE_MATCH_ALL,
xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CTRL),
xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_ALT),
XKB_MOD_INVALID) > 0);
assert(xkb_state_mod_names_are_active(state, XKB_STATE_MODS_DEPRESSED,
XKB_STATE_MATCH_ALL,
XKB_MOD_NAME_ALT,
NULL) == 0);
assert(xkb_state_mod_names_are_active(state, XKB_STATE_MODS_DEPRESSED,
XKB_STATE_MATCH_ALL |
XKB_STATE_MATCH_NON_EXCLUSIVE,
XKB_MOD_NAME_ALT,
NULL) > 0);
assert(xkb_state_mod_names_are_active(state, XKB_STATE_MODS_DEPRESSED,
(XKB_STATE_MATCH_ANY |
XKB_STATE_MATCH_NON_EXCLUSIVE),
XKB_MOD_NAME_ALT,
NULL) > 0);
/* RAlt down */
xkb_state_update_key(state, KEY_LEFTCTRL + EVDEV_OFFSET, XKB_KEY_UP);
fprintf(stderr, "dumping state for RAlt down:\n");
print_state(state);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CTRL,
XKB_STATE_MODS_EFFECTIVE) == 0);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_ALT,
XKB_STATE_MODS_DEPRESSED) > 0);
assert(xkb_state_mod_names_are_active(state, XKB_STATE_MODS_DEPRESSED,
XKB_STATE_MATCH_ANY,
XKB_MOD_NAME_CTRL,
XKB_MOD_NAME_ALT,
NULL) > 0);
assert(xkb_state_mod_names_are_active(state, XKB_STATE_MODS_LATCHED,
XKB_STATE_MATCH_ANY,
XKB_MOD_NAME_CTRL,
XKB_MOD_NAME_ALT,
NULL) == 0);
/* none down */
xkb_state_update_key(state, KEY_RIGHTALT + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_ALT,
XKB_STATE_MODS_EFFECTIVE) == 0);
/* Caps locked */
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CAPS,
XKB_STATE_MODS_DEPRESSED) > 0);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_UP);
fprintf(stderr, "dumping state for Caps Lock:\n");
print_state(state);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CAPS,
XKB_STATE_MODS_DEPRESSED) == 0);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CAPS,
XKB_STATE_MODS_LOCKED) > 0);
assert(xkb_state_led_name_is_active(state, XKB_LED_NAME_CAPS) > 0);
num_syms = xkb_state_key_get_syms(state, KEY_Q + EVDEV_OFFSET, &syms);
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assert(num_syms == 1 && syms[0] == XKB_KEY_Q);
/* Num Lock locked */
xkb_state_update_key(state, KEY_NUMLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_NUMLOCK + EVDEV_OFFSET, XKB_KEY_UP);
fprintf(stderr, "dumping state for Caps Lock + Num Lock:\n");
print_state(state);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CAPS,
XKB_STATE_MODS_LOCKED) > 0);
assert(xkb_state_mod_name_is_active(state, "Mod2",
XKB_STATE_MODS_LOCKED) > 0);
num_syms = xkb_state_key_get_syms(state, KEY_KP1 + EVDEV_OFFSET, &syms);
assert(num_syms == 1 && syms[0] == XKB_KEY_KP_1);
assert(xkb_state_led_name_is_active(state, XKB_LED_NAME_NUM) > 0);
/* Num Lock unlocked */
xkb_state_update_key(state, KEY_NUMLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_NUMLOCK + EVDEV_OFFSET, XKB_KEY_UP);
/* Switch to group 2 */
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_led_name_is_active(state, "Group 2") > 0);
assert(xkb_state_led_name_is_active(state, XKB_LED_NAME_NUM) == 0);
/* Switch back to group 1. */
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_UP);
/* Caps unlocked */
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CAPS,
XKB_STATE_MODS_EFFECTIVE) == 0);
assert(xkb_state_led_name_is_active(state, XKB_LED_NAME_CAPS) == 0);
num_syms = xkb_state_key_get_syms(state, KEY_Q + EVDEV_OFFSET, &syms);
2012-05-09 07:05:00 -06:00
assert(num_syms == 1 && syms[0] == XKB_KEY_q);
/* Multiple symbols */
num_syms = xkb_state_key_get_syms(state, KEY_6 + EVDEV_OFFSET, &syms);
assert(num_syms == 5 &&
syms[0] == XKB_KEY_H && syms[1] == XKB_KEY_E &&
syms[2] == XKB_KEY_L && syms[3] == XKB_KEY_L &&
syms[4] == XKB_KEY_O);
one_sym = xkb_state_key_get_one_sym(state, KEY_6 + EVDEV_OFFSET);
assert(one_sym == XKB_KEY_NoSymbol);
xkb_state_update_key(state, KEY_6 + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_6 + EVDEV_OFFSET, XKB_KEY_UP);
one_sym = xkb_state_key_get_one_sym(state, KEY_5 + EVDEV_OFFSET);
assert(one_sym == XKB_KEY_5);
xkb_state_unref(state);
}
static void
test_serialisation(struct xkb_keymap *keymap)
{
struct xkb_state *state = xkb_state_new(keymap);
xkb_mod_mask_t base_mods;
xkb_mod_mask_t latched_mods;
xkb_mod_mask_t locked_mods;
xkb_mod_mask_t effective_mods;
xkb_mod_index_t caps, shift, ctrl;
xkb_layout_index_t base_group = 0;
xkb_layout_index_t latched_group = 0;
xkb_layout_index_t locked_group = 0;
assert(state);
caps = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CAPS);
assert(caps != XKB_MOD_INVALID);
shift = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_SHIFT);
assert(shift != XKB_MOD_INVALID);
ctrl = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CTRL);
assert(ctrl != XKB_MOD_INVALID);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_UP);
base_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_DEPRESSED);
assert(base_mods == 0);
latched_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_LATCHED);
assert(latched_mods == 0);
locked_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_LOCKED);
assert(locked_mods == (1U << caps));
effective_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE);
assert(effective_mods == locked_mods);
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_DOWN);
base_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_DEPRESSED);
assert(base_mods == (1U << shift));
latched_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_LATCHED);
assert(latched_mods == 0);
locked_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_LOCKED);
assert(locked_mods == (1U << caps));
effective_mods = xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE);
assert(effective_mods == (base_mods | locked_mods));
base_mods |= (1U << ctrl);
xkb_state_update_mask(state, base_mods, latched_mods, locked_mods,
base_group, latched_group, locked_group);
assert(xkb_state_mod_index_is_active(state, ctrl, XKB_STATE_MODS_DEPRESSED) > 0);
assert(xkb_state_mod_index_is_active(state, ctrl, XKB_STATE_MODS_EFFECTIVE) > 0);
xkb_state_unref(state);
}
static void
test_update_mask_mods(struct xkb_keymap *keymap)
{
struct xkb_state *state = xkb_state_new(keymap);
xkb_mod_index_t caps, shift, num, alt, mod1, mod2;
enum xkb_state_component changed;
assert(state);
caps = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CAPS);
assert(caps != XKB_MOD_INVALID);
shift = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_SHIFT);
assert(shift != XKB_MOD_INVALID);
num = xkb_keymap_mod_get_index(keymap, "NumLock");
assert(num != XKB_MOD_INVALID);
alt = xkb_keymap_mod_get_index(keymap, "Alt");
assert(alt != XKB_MOD_INVALID);
mod1 = xkb_keymap_mod_get_index(keymap, "Mod1");
assert(mod1 != XKB_MOD_INVALID);
mod2 = xkb_keymap_mod_get_index(keymap, "Mod2");
assert(mod2 != XKB_MOD_INVALID);
changed = xkb_state_update_mask(state, 1 << caps, 0, 0, 0, 0, 0);
assert(changed == (XKB_STATE_MODS_DEPRESSED | XKB_STATE_MODS_EFFECTIVE));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE) ==
(1u << caps));
changed = xkb_state_update_mask(state, (1 << caps), 0, (1 << shift), 0, 0, 0);
assert(changed == (XKB_STATE_MODS_LOCKED | XKB_STATE_MODS_EFFECTIVE |
XKB_STATE_LEDS));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE) ==
((1u << caps) | (1u << shift)));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_DEPRESSED) ==
(1u << caps));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_LATCHED) == 0);
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_LOCKED) ==
(1u << shift));
changed = xkb_state_update_mask(state, 0, 0, 0, 0, 0, 0);
assert(changed == (XKB_STATE_MODS_DEPRESSED | XKB_STATE_MODS_LOCKED |
XKB_STATE_MODS_EFFECTIVE | XKB_STATE_LEDS));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE) == 0);
changed = xkb_state_update_mask(state, (1 << alt), 0, 0, 0, 0, 0);
assert(changed == (XKB_STATE_MODS_DEPRESSED | XKB_STATE_MODS_EFFECTIVE));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE) ==
((1u << alt) | (1u << mod1)));
changed = xkb_state_update_mask(state, 0, 0, (1 << num), 0, 0, 0);
assert(changed == (XKB_STATE_MODS_DEPRESSED | XKB_STATE_MODS_LOCKED |
XKB_STATE_MODS_EFFECTIVE | XKB_STATE_LEDS));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE) ==
((1u << num) | (1u << mod2)));
xkb_state_update_mask(state, 0, 0, 0, 0, 0, 0);
changed = xkb_state_update_mask(state, (1 << mod2), 0, (1 << num), 0, 0, 0);
assert(changed == (XKB_STATE_MODS_DEPRESSED | XKB_STATE_MODS_LOCKED |
XKB_STATE_MODS_EFFECTIVE | XKB_STATE_LEDS));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE) ==
((1u << mod2) | (1u << num)));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_DEPRESSED) ==
(1u << mod2));
assert(xkb_state_serialize_mods(state, XKB_STATE_MODS_LOCKED) ==
((1u << num) | (1u << mod2)));
xkb_state_unref(state);
}
static void
test_repeat(struct xkb_keymap *keymap)
{
assert(!xkb_keymap_key_repeats(keymap, KEY_LEFTSHIFT + 8));
assert(xkb_keymap_key_repeats(keymap, KEY_A + 8));
assert(xkb_keymap_key_repeats(keymap, KEY_8 + 8));
assert(xkb_keymap_key_repeats(keymap, KEY_DOWN + 8));
assert(xkb_keymap_key_repeats(keymap, KEY_KBDILLUMDOWN + 8));
}
static void
test_consume(struct xkb_keymap *keymap)
{
state: fix consumed modifier calculation The current calculation is in short: entry ? (entry->mask & ~entry->preserve) : 0 This changes it be type->mask & ~(entry ? entry->preserve : 0) This is what Xlib does. While less intuitive, it is actually more correct, if you follow this deduction: - The key group's type->mask defines which modifiers the key even cares about. The others are completely irrelevant (and in fact they are masked out from all sided in the level calculation). Example: NumLock for an alphabetic key. - The type->mask, the mods which are not masked out, are *all* relevant (and in fact in the level calculation they must match *exactly* to the state). These mods affect which level is chosen for the key, whether they are active or not. - Because the type->mask mods are all relevant, they must be considered as consumed by the calculation *even if they are not active*. Therefore we use type->mask instead of entry->mask. The second change is what happens when no entry is found: return 0 or just take preserve to be 0? Let's consider an example, the basic type type "ALPHABETIC" { modifiers = Shift+Lock; map[Shift] = Level2; map[Lock] = Level2; level_name[Level1] = "Base"; level_name[Level2] = "Caps"; }; Suppose Shift+Lock is active - it doesn't match any entry, thus it gets to level 0. The first interpretation would take them both to be unconsumed, the second (new one) would take them both to be consumed. This seems much better: Caps is active, and Shift disables it, they both do something. This change also fixes a pretty lousy bug (since 0.3.2), where Shift appears to apparently *not* disable Caps. What actually happens is that Caps is not consumed (see above) but active, thus the implicit capitalization in get_one_sym() kicks in and capitalizes it anyway. Reported-by: Davinder Pal Singh Bhamra Signed-off-by: Ran Benita <ran234@gmail.com>
2014-03-27 09:42:20 -06:00
struct xkb_state *state;
xkb_mod_index_t alt, shift, caps, ctrl, mod5;
xkb_mod_mask_t mask;
state: fix consumed modifier calculation The current calculation is in short: entry ? (entry->mask & ~entry->preserve) : 0 This changes it be type->mask & ~(entry ? entry->preserve : 0) This is what Xlib does. While less intuitive, it is actually more correct, if you follow this deduction: - The key group's type->mask defines which modifiers the key even cares about. The others are completely irrelevant (and in fact they are masked out from all sided in the level calculation). Example: NumLock for an alphabetic key. - The type->mask, the mods which are not masked out, are *all* relevant (and in fact in the level calculation they must match *exactly* to the state). These mods affect which level is chosen for the key, whether they are active or not. - Because the type->mask mods are all relevant, they must be considered as consumed by the calculation *even if they are not active*. Therefore we use type->mask instead of entry->mask. The second change is what happens when no entry is found: return 0 or just take preserve to be 0? Let's consider an example, the basic type type "ALPHABETIC" { modifiers = Shift+Lock; map[Shift] = Level2; map[Lock] = Level2; level_name[Level1] = "Base"; level_name[Level2] = "Caps"; }; Suppose Shift+Lock is active - it doesn't match any entry, thus it gets to level 0. The first interpretation would take them both to be unconsumed, the second (new one) would take them both to be consumed. This seems much better: Caps is active, and Shift disables it, they both do something. This change also fixes a pretty lousy bug (since 0.3.2), where Shift appears to apparently *not* disable Caps. What actually happens is that Caps is not consumed (see above) but active, thus the implicit capitalization in get_one_sym() kicks in and capitalizes it anyway. Reported-by: Davinder Pal Singh Bhamra Signed-off-by: Ran Benita <ran234@gmail.com>
2014-03-27 09:42:20 -06:00
state = xkb_state_new(keymap);
assert(state);
alt = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_ALT);
assert(alt != XKB_MOD_INVALID);
shift = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_SHIFT);
assert(shift != XKB_MOD_INVALID);
state: fix consumed modifier calculation The current calculation is in short: entry ? (entry->mask & ~entry->preserve) : 0 This changes it be type->mask & ~(entry ? entry->preserve : 0) This is what Xlib does. While less intuitive, it is actually more correct, if you follow this deduction: - The key group's type->mask defines which modifiers the key even cares about. The others are completely irrelevant (and in fact they are masked out from all sided in the level calculation). Example: NumLock for an alphabetic key. - The type->mask, the mods which are not masked out, are *all* relevant (and in fact in the level calculation they must match *exactly* to the state). These mods affect which level is chosen for the key, whether they are active or not. - Because the type->mask mods are all relevant, they must be considered as consumed by the calculation *even if they are not active*. Therefore we use type->mask instead of entry->mask. The second change is what happens when no entry is found: return 0 or just take preserve to be 0? Let's consider an example, the basic type type "ALPHABETIC" { modifiers = Shift+Lock; map[Shift] = Level2; map[Lock] = Level2; level_name[Level1] = "Base"; level_name[Level2] = "Caps"; }; Suppose Shift+Lock is active - it doesn't match any entry, thus it gets to level 0. The first interpretation would take them both to be unconsumed, the second (new one) would take them both to be consumed. This seems much better: Caps is active, and Shift disables it, they both do something. This change also fixes a pretty lousy bug (since 0.3.2), where Shift appears to apparently *not* disable Caps. What actually happens is that Caps is not consumed (see above) but active, thus the implicit capitalization in get_one_sym() kicks in and capitalizes it anyway. Reported-by: Davinder Pal Singh Bhamra Signed-off-by: Ran Benita <ran234@gmail.com>
2014-03-27 09:42:20 -06:00
caps = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CAPS);
assert(caps != XKB_MOD_INVALID);
ctrl = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CTRL);
assert(ctrl != XKB_MOD_INVALID);
mod5 = xkb_keymap_mod_get_index(keymap, "Mod5");
assert(mod5 != XKB_MOD_INVALID);
state: fix consumed modifier calculation The current calculation is in short: entry ? (entry->mask & ~entry->preserve) : 0 This changes it be type->mask & ~(entry ? entry->preserve : 0) This is what Xlib does. While less intuitive, it is actually more correct, if you follow this deduction: - The key group's type->mask defines which modifiers the key even cares about. The others are completely irrelevant (and in fact they are masked out from all sided in the level calculation). Example: NumLock for an alphabetic key. - The type->mask, the mods which are not masked out, are *all* relevant (and in fact in the level calculation they must match *exactly* to the state). These mods affect which level is chosen for the key, whether they are active or not. - Because the type->mask mods are all relevant, they must be considered as consumed by the calculation *even if they are not active*. Therefore we use type->mask instead of entry->mask. The second change is what happens when no entry is found: return 0 or just take preserve to be 0? Let's consider an example, the basic type type "ALPHABETIC" { modifiers = Shift+Lock; map[Shift] = Level2; map[Lock] = Level2; level_name[Level1] = "Base"; level_name[Level2] = "Caps"; }; Suppose Shift+Lock is active - it doesn't match any entry, thus it gets to level 0. The first interpretation would take them both to be unconsumed, the second (new one) would take them both to be consumed. This seems much better: Caps is active, and Shift disables it, they both do something. This change also fixes a pretty lousy bug (since 0.3.2), where Shift appears to apparently *not* disable Caps. What actually happens is that Caps is not consumed (see above) but active, thus the implicit capitalization in get_one_sym() kicks in and capitalizes it anyway. Reported-by: Davinder Pal Singh Bhamra Signed-off-by: Ran Benita <ran234@gmail.com>
2014-03-27 09:42:20 -06:00
/* Test remove_consumed() */
xkb_state_update_key(state, KEY_LEFTALT + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_EQUAL + EVDEV_OFFSET, XKB_KEY_DOWN);
fprintf(stderr, "dumping state for Alt-Shift-+\n");
print_state(state);
mask = xkb_state_serialize_mods(state, XKB_STATE_MODS_EFFECTIVE);
assert(mask == ((1U << alt) | (1U << shift)));
mask = xkb_state_mod_mask_remove_consumed(state, KEY_EQUAL + EVDEV_OFFSET,
mask);
assert(mask == (1U << alt));
state: fix consumed modifier calculation The current calculation is in short: entry ? (entry->mask & ~entry->preserve) : 0 This changes it be type->mask & ~(entry ? entry->preserve : 0) This is what Xlib does. While less intuitive, it is actually more correct, if you follow this deduction: - The key group's type->mask defines which modifiers the key even cares about. The others are completely irrelevant (and in fact they are masked out from all sided in the level calculation). Example: NumLock for an alphabetic key. - The type->mask, the mods which are not masked out, are *all* relevant (and in fact in the level calculation they must match *exactly* to the state). These mods affect which level is chosen for the key, whether they are active or not. - Because the type->mask mods are all relevant, they must be considered as consumed by the calculation *even if they are not active*. Therefore we use type->mask instead of entry->mask. The second change is what happens when no entry is found: return 0 or just take preserve to be 0? Let's consider an example, the basic type type "ALPHABETIC" { modifiers = Shift+Lock; map[Shift] = Level2; map[Lock] = Level2; level_name[Level1] = "Base"; level_name[Level2] = "Caps"; }; Suppose Shift+Lock is active - it doesn't match any entry, thus it gets to level 0. The first interpretation would take them both to be unconsumed, the second (new one) would take them both to be consumed. This seems much better: Caps is active, and Shift disables it, they both do something. This change also fixes a pretty lousy bug (since 0.3.2), where Shift appears to apparently *not* disable Caps. What actually happens is that Caps is not consumed (see above) but active, thus the implicit capitalization in get_one_sym() kicks in and capitalizes it anyway. Reported-by: Davinder Pal Singh Bhamra Signed-off-by: Ran Benita <ran234@gmail.com>
2014-03-27 09:42:20 -06:00
/* Test get_consumed_mods() */
mask = xkb_state_key_get_consumed_mods(state, KEY_EQUAL + EVDEV_OFFSET);
assert(mask == (1U << shift));
state: fix consumed modifier calculation The current calculation is in short: entry ? (entry->mask & ~entry->preserve) : 0 This changes it be type->mask & ~(entry ? entry->preserve : 0) This is what Xlib does. While less intuitive, it is actually more correct, if you follow this deduction: - The key group's type->mask defines which modifiers the key even cares about. The others are completely irrelevant (and in fact they are masked out from all sided in the level calculation). Example: NumLock for an alphabetic key. - The type->mask, the mods which are not masked out, are *all* relevant (and in fact in the level calculation they must match *exactly* to the state). These mods affect which level is chosen for the key, whether they are active or not. - Because the type->mask mods are all relevant, they must be considered as consumed by the calculation *even if they are not active*. Therefore we use type->mask instead of entry->mask. The second change is what happens when no entry is found: return 0 or just take preserve to be 0? Let's consider an example, the basic type type "ALPHABETIC" { modifiers = Shift+Lock; map[Shift] = Level2; map[Lock] = Level2; level_name[Level1] = "Base"; level_name[Level2] = "Caps"; }; Suppose Shift+Lock is active - it doesn't match any entry, thus it gets to level 0. The first interpretation would take them both to be unconsumed, the second (new one) would take them both to be consumed. This seems much better: Caps is active, and Shift disables it, they both do something. This change also fixes a pretty lousy bug (since 0.3.2), where Shift appears to apparently *not* disable Caps. What actually happens is that Caps is not consumed (see above) but active, thus the implicit capitalization in get_one_sym() kicks in and capitalizes it anyway. Reported-by: Davinder Pal Singh Bhamra Signed-off-by: Ran Benita <ran234@gmail.com>
2014-03-27 09:42:20 -06:00
mask = xkb_state_key_get_consumed_mods(state, KEY_ESC + EVDEV_OFFSET);
assert(mask == 0);
xkb_state_unref(state);
/* Test is_consumed() - simple ALPHABETIC type. */
state = xkb_state_new(keymap);
assert(state);
mask = xkb_state_key_get_consumed_mods(state, KEY_A + EVDEV_OFFSET);
assert(mask == ((1U << shift) | (1U << caps)));
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, caps) > 0);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, shift) > 0);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, caps) > 0);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, shift) > 0);
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_DOWN);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, caps) > 0);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, shift) > 0);
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_UP);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_CAPSLOCK + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, caps) > 0);
assert(xkb_state_mod_index_is_consumed(state, KEY_A + EVDEV_OFFSET, shift) > 0);
xkb_state_unref(state);
/* More complicated - CTRL+ALT */
state = xkb_state_new(keymap);
mask = xkb_state_key_get_consumed_mods(state, KEY_F1 + EVDEV_OFFSET);
assert(mask == ((1U << shift) | (1U << alt) | (1U << ctrl) | (1U << mod5)));
/* Shift is preserved. */
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_DOWN);
mask = xkb_state_key_get_consumed_mods(state, KEY_F1 + EVDEV_OFFSET);
assert(mask == ((1U << alt) | (1U << ctrl) | (1U << mod5)));
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_UP);
mask = xkb_state_key_get_consumed_mods(state, KEY_F1 + EVDEV_OFFSET);
assert(mask == ((1U << shift) | (1U << alt) | (1U << ctrl) | (1U << mod5)));
assert(state);
xkb_state_unref(state);
}
static void
key_iter(struct xkb_keymap *keymap, xkb_keycode_t key, void *data)
{
xkb_keycode_t *counter = data;
assert(*counter == key);
(*counter)++;
}
static void
test_range(struct xkb_keymap *keymap)
{
xkb_keycode_t counter;
assert(xkb_keymap_min_keycode(keymap) == 9);
assert(xkb_keymap_max_keycode(keymap) == 253);
counter = xkb_keymap_min_keycode(keymap);
xkb_keymap_key_for_each(keymap, key_iter, &counter);
assert(counter == xkb_keymap_max_keycode(keymap) + 1);
}
state: apply capitalization transformation on keysyms The xkbproto spec says: http://www.x.org/releases/current/doc/kbproto/xkbproto.html#Interpreting_the_Lock_Modifier If the Lock modifier is not consumed by the symbol lookup process, routines that determine the symbol and string that correspond to an event should capitalize the result. This was not an issue until now, because most xkeyboard-config keymaps do not utilize this "feature", and specify the keysyms for the Lock modifier explicitly instead. However, some keymaps do depend on it, e.g. ch(fr) for eacute and others. The spec goes on to describe two options for doing this transformation: locale-sensitive and locale-insensitive. We opt for the latter; it is less desirable but we don't want *that* headache. Also, only xkb_state_key_get_one_sym() is changed; xkb_state_key_get_syms() is left as-is, and always reports the untransformed keysyms. This is for the following reasons: - The API doesn't allow it, since we return a const pointer directly to the keymap keysyms table and we can't transform that. - The transformation doesn't make sense for multiple-keysyms. - It can be useful for an application to get the "raw" keysyms if it wants to (e.g. maybe it wants to do the transformation itself). Finally, note that xkb_state_mod_index_is_consumed() does *not* report Lock as consumed even if it was used in the transformation. This is what Xlib does. This definitely doesn't fall under the "hard to misuse" API rule but it's the best we can do. https://bugs.freedesktop.org/show_bug.cgi?id=67167 Reported-By: Gatis Paeglis <gatis.paeglis@digia.com> Signed-off-by: Ran Benita <ran234@gmail.com>
2013-08-13 09:57:43 -06:00
static void
test_caps_keysym_transformation(struct xkb_keymap *keymap)
{
struct xkb_state *state = xkb_state_new(keymap);
xkb_mod_index_t caps, shift;
int nsyms;
xkb_keysym_t sym;
const xkb_keysym_t *syms;
assert(state);
/* See xkb_state_key_get_one_sym() for what's this all about. */
caps = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CAPS);
shift = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_SHIFT);
assert(caps != XKB_MOD_INVALID && shift != XKB_MOD_INVALID);
state: apply capitalization transformation on keysyms The xkbproto spec says: http://www.x.org/releases/current/doc/kbproto/xkbproto.html#Interpreting_the_Lock_Modifier If the Lock modifier is not consumed by the symbol lookup process, routines that determine the symbol and string that correspond to an event should capitalize the result. This was not an issue until now, because most xkeyboard-config keymaps do not utilize this "feature", and specify the keysyms for the Lock modifier explicitly instead. However, some keymaps do depend on it, e.g. ch(fr) for eacute and others. The spec goes on to describe two options for doing this transformation: locale-sensitive and locale-insensitive. We opt for the latter; it is less desirable but we don't want *that* headache. Also, only xkb_state_key_get_one_sym() is changed; xkb_state_key_get_syms() is left as-is, and always reports the untransformed keysyms. This is for the following reasons: - The API doesn't allow it, since we return a const pointer directly to the keymap keysyms table and we can't transform that. - The transformation doesn't make sense for multiple-keysyms. - It can be useful for an application to get the "raw" keysyms if it wants to (e.g. maybe it wants to do the transformation itself). Finally, note that xkb_state_mod_index_is_consumed() does *not* report Lock as consumed even if it was used in the transformation. This is what Xlib does. This definitely doesn't fall under the "hard to misuse" API rule but it's the best we can do. https://bugs.freedesktop.org/show_bug.cgi?id=67167 Reported-By: Gatis Paeglis <gatis.paeglis@digia.com> Signed-off-by: Ran Benita <ran234@gmail.com>
2013-08-13 09:57:43 -06:00
assert(xkb_state_key_get_layout(state, KEY_A + 8) == 0);
assert(xkb_state_key_get_layout(state, KEY_SEMICOLON + 8) == 0);
/* Without caps, no transformation. */
assert(xkb_state_mod_index_is_active(state, caps, XKB_STATE_MODS_EFFECTIVE) == 0);
assert(xkb_state_mod_index_is_active(state, shift, XKB_STATE_MODS_EFFECTIVE) == 0);
assert(xkb_state_key_get_level(state, KEY_A + 8, 0) == 0);
sym = xkb_state_key_get_one_sym(state, KEY_A + 8);
assert(sym == XKB_KEY_a);
assert(xkb_state_key_get_level(state, KEY_SEMICOLON + 8, 0) == 0);
sym = xkb_state_key_get_one_sym(state, KEY_SEMICOLON + 8);
assert(sym == XKB_KEY_eacute);
nsyms = xkb_state_key_get_syms(state, KEY_SEMICOLON + 8, &syms);
assert(nsyms == 1 && syms[0] == XKB_KEY_eacute);
/* With shift, no transformation (only different level). */
xkb_state_update_key(state, KEY_LEFTSHIFT + 8, XKB_KEY_DOWN);
assert(xkb_state_mod_index_is_active(state, caps, XKB_STATE_MODS_EFFECTIVE) == 0);
assert(xkb_state_mod_index_is_active(state, shift, XKB_STATE_MODS_EFFECTIVE) > 0);
assert(xkb_state_key_get_level(state, KEY_A + 8, 0) == 1);
sym = xkb_state_key_get_one_sym(state, KEY_A + 8);
assert(sym == XKB_KEY_A);
sym = xkb_state_key_get_one_sym(state, KEY_SEMICOLON + 8);
assert(sym == XKB_KEY_odiaeresis);
nsyms = xkb_state_key_get_syms(state, KEY_SEMICOLON + 8, &syms);
assert(nsyms == 1 && syms[0] == XKB_KEY_odiaeresis);
xkb_state_update_key(state, KEY_LEFTSHIFT + 8, XKB_KEY_UP);
assert(xkb_state_mod_index_is_active(state, shift, XKB_STATE_MODS_EFFECTIVE) == 0);
/* With caps, transform in same level, only with _get_one_sym(). */
xkb_state_update_key(state, KEY_CAPSLOCK + 8, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_CAPSLOCK + 8, XKB_KEY_UP);
assert(xkb_state_mod_index_is_active(state, caps, XKB_STATE_MODS_EFFECTIVE) > 0);
assert(xkb_state_mod_index_is_active(state, shift, XKB_STATE_MODS_EFFECTIVE) == 0);
assert(xkb_state_key_get_level(state, KEY_A + 8, 0) == 1);
sym = xkb_state_key_get_one_sym(state, KEY_A + 8);
assert(sym == XKB_KEY_A);
assert(xkb_state_key_get_level(state, KEY_SEMICOLON + 8, 0) == 0);
sym = xkb_state_key_get_one_sym(state, KEY_SEMICOLON + 8);
assert(sym == XKB_KEY_Eacute);
nsyms = xkb_state_key_get_syms(state, KEY_SEMICOLON + 8, &syms);
assert(nsyms == 1 && syms[0] == XKB_KEY_eacute);
xkb_state_update_key(state, KEY_LEFTSHIFT + 8, XKB_KEY_UP);
assert(xkb_state_mod_index_is_active(state, shift, XKB_STATE_MODS_EFFECTIVE) == 0);
xkb_state_update_key(state, KEY_CAPSLOCK + 8, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_CAPSLOCK + 8, XKB_KEY_UP);
xkb_state_unref(state);
state: apply capitalization transformation on keysyms The xkbproto spec says: http://www.x.org/releases/current/doc/kbproto/xkbproto.html#Interpreting_the_Lock_Modifier If the Lock modifier is not consumed by the symbol lookup process, routines that determine the symbol and string that correspond to an event should capitalize the result. This was not an issue until now, because most xkeyboard-config keymaps do not utilize this "feature", and specify the keysyms for the Lock modifier explicitly instead. However, some keymaps do depend on it, e.g. ch(fr) for eacute and others. The spec goes on to describe two options for doing this transformation: locale-sensitive and locale-insensitive. We opt for the latter; it is less desirable but we don't want *that* headache. Also, only xkb_state_key_get_one_sym() is changed; xkb_state_key_get_syms() is left as-is, and always reports the untransformed keysyms. This is for the following reasons: - The API doesn't allow it, since we return a const pointer directly to the keymap keysyms table and we can't transform that. - The transformation doesn't make sense for multiple-keysyms. - It can be useful for an application to get the "raw" keysyms if it wants to (e.g. maybe it wants to do the transformation itself). Finally, note that xkb_state_mod_index_is_consumed() does *not* report Lock as consumed even if it was used in the transformation. This is what Xlib does. This definitely doesn't fall under the "hard to misuse" API rule but it's the best we can do. https://bugs.freedesktop.org/show_bug.cgi?id=67167 Reported-By: Gatis Paeglis <gatis.paeglis@digia.com> Signed-off-by: Ran Benita <ran234@gmail.com>
2013-08-13 09:57:43 -06:00
}
static void
test_get_utf8_utf32(struct xkb_keymap *keymap)
{
char buf[256];
struct xkb_state *state = xkb_state_new(keymap);
assert(state);
#define TEST_KEY(key, expected_utf8, expected_utf32) do { \
assert(xkb_state_key_get_utf8(state, key + 8, NULL, 0) == strlen(expected_utf8)); \
assert(xkb_state_key_get_utf8(state, key + 8, buf, sizeof(buf)) == strlen(expected_utf8)); \
assert(memcmp(buf, expected_utf8, sizeof(expected_utf8)) == 0); \
assert(xkb_state_key_get_utf32(state, key + 8) == expected_utf32); \
} while (0)
/* Simple ASCII. */
TEST_KEY(KEY_A, "a", 0x61);
TEST_KEY(KEY_ESC, "\x1B", 0x1B);
TEST_KEY(KEY_1, "1", 0x31);
/* Invalid. */
TEST_KEY(XKB_KEYCODE_INVALID - 8, "", 0);
TEST_KEY(300, "", 0);
/* No string. */
TEST_KEY(KEY_LEFTCTRL, "", 0);
TEST_KEY(KEY_NUMLOCK, "", 0);
/* Multiple keysyms. */
TEST_KEY(KEY_6, "HELLO", 0);
TEST_KEY(KEY_7, "YES THIS IS DOG", 0);
/* Check truncation. */
memset(buf, 'X', sizeof(buf));
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 0) == strlen("HELLO"));
assert(memcmp(buf, "X", 1) == 0);
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 1) == strlen("HELLO"));
assert(memcmp(buf, "", 1) == 0);
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 2) == strlen("HELLO"));
assert(memcmp(buf, "H", 2) == 0);
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 3) == strlen("HELLO"));
assert(memcmp(buf, "HE", 3) == 0);
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 5) == strlen("HELLO"));
assert(memcmp(buf, "HELL", 5) == 0);
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 6) == strlen("HELLO"));
assert(memcmp(buf, "HELLO", 6) == 0);
assert(xkb_state_key_get_utf8(state, KEY_6 + 8, buf, 7) == strlen("HELLO"));
assert(memcmp(buf, "HELLO\0X", 7) == 0);
/* Switch to ru layout */
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_key_get_layout(state, KEY_A + 8) == 1);
/* Non ASCII. */
TEST_KEY(KEY_ESC, "\x1B", 0x1B);
TEST_KEY(KEY_A, "ф", 0x0444);
TEST_KEY(KEY_Z, "я", 0x044F);
/* Switch back to us layout */
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_key_get_layout(state, KEY_A + 8) == 0);
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_DOWN);
TEST_KEY(KEY_A, "A", 0x41);
TEST_KEY(KEY_ESC, "\x1B", 0x1B);
TEST_KEY(KEY_1, "!", 0x21);
xkb_state_update_key(state, KEY_LEFTSHIFT + EVDEV_OFFSET, XKB_KEY_UP);
TEST_KEY(KEY_6, "HELLO", 0);
TEST_KEY(KEY_7, "YES THIS IS DOG", 0);
xkb_state_unref(state);
}
static void
test_ctrl_string_transformation(struct xkb_keymap *keymap)
{
char buf[256];
struct xkb_state *state = xkb_state_new(keymap);
xkb_mod_index_t ctrl;
assert(state);
/* See xkb_state_key_get_utf8() for what's this all about. */
ctrl = xkb_keymap_mod_get_index(keymap, XKB_MOD_NAME_CTRL);
assert(ctrl != XKB_MOD_INVALID);
/* First without. */
TEST_KEY(KEY_A, "a", 0x61);
TEST_KEY(KEY_B, "b", 0x62);
TEST_KEY(KEY_C, "c", 0x63);
TEST_KEY(KEY_ESC, "\x1B", 0x1B);
TEST_KEY(KEY_1, "1", 0x31);
/* And with. */
xkb_state_update_key(state, KEY_RIGHTCTRL + EVDEV_OFFSET, XKB_KEY_DOWN);
assert(xkb_state_mod_index_is_active(state, ctrl, XKB_STATE_MODS_EFFECTIVE) > 0);
TEST_KEY(KEY_A, "\x01", 0x01);
TEST_KEY(KEY_B, "\x02", 0x02);
TEST_KEY(KEY_C, "\x03", 0x03);
TEST_KEY(KEY_ESC, "\x1B", 0x1B);
TEST_KEY(KEY_1, "1", 0x31);
xkb_state_update_key(state, KEY_RIGHTCTRL + EVDEV_OFFSET, XKB_KEY_UP);
/* Switch to ru layout */
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_DOWN);
xkb_state_update_key(state, KEY_COMPOSE + EVDEV_OFFSET, XKB_KEY_UP);
assert(xkb_state_key_get_layout(state, KEY_A + 8) == 1);
/* Non ASCII. */
xkb_state_update_key(state, KEY_RIGHTCTRL + EVDEV_OFFSET, XKB_KEY_DOWN);
assert(xkb_state_mod_index_is_active(state, ctrl, XKB_STATE_MODS_EFFECTIVE) > 0);
TEST_KEY(KEY_A, "\x01", 0x01);
TEST_KEY(KEY_B, "\x02", 0x02);
xkb_state_update_key(state, KEY_RIGHTCTRL + EVDEV_OFFSET, XKB_KEY_UP);
xkb_state_unref(state);
}
int
main(void)
{
struct xkb_context *context = test_get_context(0);
struct xkb_keymap *keymap;
assert(context);
/* Make sure these are allowed. */
xkb_context_unref(NULL);
xkb_keymap_unref(NULL);
xkb_state_unref(NULL);
keymap = test_compile_rules(context, "evdev", "pc104", "us,ru", NULL, "grp:menu_toggle");
assert(keymap);
test_update_key(keymap);
test_serialisation(keymap);
test_update_mask_mods(keymap);
test_repeat(keymap);
test_consume(keymap);
test_range(keymap);
test_get_utf8_utf32(keymap);
test_ctrl_string_transformation(keymap);
state: apply capitalization transformation on keysyms The xkbproto spec says: http://www.x.org/releases/current/doc/kbproto/xkbproto.html#Interpreting_the_Lock_Modifier If the Lock modifier is not consumed by the symbol lookup process, routines that determine the symbol and string that correspond to an event should capitalize the result. This was not an issue until now, because most xkeyboard-config keymaps do not utilize this "feature", and specify the keysyms for the Lock modifier explicitly instead. However, some keymaps do depend on it, e.g. ch(fr) for eacute and others. The spec goes on to describe two options for doing this transformation: locale-sensitive and locale-insensitive. We opt for the latter; it is less desirable but we don't want *that* headache. Also, only xkb_state_key_get_one_sym() is changed; xkb_state_key_get_syms() is left as-is, and always reports the untransformed keysyms. This is for the following reasons: - The API doesn't allow it, since we return a const pointer directly to the keymap keysyms table and we can't transform that. - The transformation doesn't make sense for multiple-keysyms. - It can be useful for an application to get the "raw" keysyms if it wants to (e.g. maybe it wants to do the transformation itself). Finally, note that xkb_state_mod_index_is_consumed() does *not* report Lock as consumed even if it was used in the transformation. This is what Xlib does. This definitely doesn't fall under the "hard to misuse" API rule but it's the best we can do. https://bugs.freedesktop.org/show_bug.cgi?id=67167 Reported-By: Gatis Paeglis <gatis.paeglis@digia.com> Signed-off-by: Ran Benita <ran234@gmail.com>
2013-08-13 09:57:43 -06:00
xkb_keymap_unref(keymap);
keymap = test_compile_rules(context, "evdev", NULL, "ch", "fr", NULL);
assert(keymap);
test_caps_keysym_transformation(keymap);
xkb_keymap_unref(keymap);
xkb_context_unref(context);
}