230 lines
7.0 KiB
Markdown
230 lines
7.0 KiB
Markdown
# Quick Guide
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## Introduction
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This document contains a quick walk-through of the often-used parts of
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the library. We will employ a few use-cases to lead the examples:
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1. An evdev client. "evdev" is the Linux kernel's input subsystem; it
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only reports to the client which keys are pressed and released.
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2. An X11 client, using the XCB library to communicate with the X
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server and the xcb-xkb library for using the XKB protocol.
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3. A Wayland client, using the standard protocol.
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The snippets are not complete, and some support code is omitted. You
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can find complete and more complex examples in the source directory:
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1. tools/interactive-evdev.c contains an interactive evdev client.
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2. tools/interactive-x11.c contains an interactive X11 client.
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3. tools/interactive-wayland.c contains an interactive Wayland client.
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Also, the library contains many more functions for examining and using
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the library context, the keymap and the keyboard state. See the
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hyper-linked reference documentation or go through the header files in
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xkbcommon/ for more details.
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## Code
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Before we can do anything interesting, we need a library context:
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~~~{.c}
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#include <xkbcommon/xkbcommon.h>
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struct xkb_context *ctx;
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ctx = xkb_context_new(XKB_CONTEXT_NO_FLAGS);
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if (!ctx) <error>
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~~~
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The `xkb_context` contains the keymap include paths, the log level and
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functions, and other general customizable administrativia.
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Next we need to create a keymap, `xkb_keymap`. This is an immutable object
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which contains all of the information about the keys, layouts, etc. There
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are different ways to do this.
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If we are an evdev client, we have nothing to go by, so we need to ask
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the user for his/her keymap preferences (for example, an Icelandic
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keyboard with a Dvorak layout). The configuration format is commonly
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called RMLVO (Rules+Model+Layout+Variant+Options), the same format used
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by the X server. With it, we can fill a struct called `xkb_rule_names`;
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passing `NULL` chooses the system's default.
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~~~{.c}
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struct xkb_keymap *keymap;
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/* Example RMLVO for Icelandic Dvorak. */
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struct xkb_rule_names names = {
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.rules = NULL,
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.model = "pc105",
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.layout = "is",
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.variant = "dvorak",
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.options = "terminate:ctrl_alt_bksp"
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};
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keymap = xkb_keymap_new_from_names(ctx, &names,
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XKB_KEYMAP_COMPILE_NO_FLAGS);
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if (!keymap) <error>
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~~~
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If we are a Wayland client, the compositor gives us a string complete
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with a keymap. In this case, we can create the keymap object like this:
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~~~{.c}
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/* From the wl_keyboard::keymap event. */
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const char *keymap_string = <...>;
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struct xkb_keymap *keymap;
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keymap = xkb_keymap_new_from_string(ctx, keymap_string,
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XKB_KEYMAP_FORMAT_TEXT_V1,
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XKB_KEYMAP_COMPILE_NO_FLAGS);
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if (!keymap) <error>
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~~~
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If we are an X11 client, we are better off getting the keymap from the
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X server directly. For this we need to choose the XInput device; here
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we will use the core keyboard device:
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~~~{.c}
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#include <xkbcommon/xkbcommon-x11.h>
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xcb_connection_t *conn = <...>;
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int32_t device_id;
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device_id = xkb_x11_get_core_keyboard_device_id(conn);
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if (device_id == -1) <error>
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keymap = xkb_x11_keymap_new_from_device(ctx, conn, device_id,
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XKB_KEYMAP_COMPILE_NO_FLAGS);
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if (!keymap) <error>
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~~~
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Now that we have the keymap, we are ready to handle the keyboard devices.
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For each device, we create an `xkb_state`, which remembers things like which
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keyboard modifiers and LEDs are active:
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~~~{.c}
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struct xkb_state *state;
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state = xkb_state_new(keymap);
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if (!state) <error>
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~~~
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For X11/XCB clients, this is better:
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~~~{.c}
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state = xkb_x11_state_new_from_device(keymap, conn, device_id);
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if (!state) <error>
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~~~
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When we have an `xkb_state` for a device, we can start handling key events
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from it. Given a keycode for a key, we can get its keysym:
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~~~{.c}
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<key event structure> event;
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xkb_keycode_t keycode;
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xkb_keysym_t keysym;
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keycode = event->keycode;
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keysym = xkb_state_key_get_one_sym(state, keycode);
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~~~
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We can see which keysym we got, and get its name:
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~~~{.c}
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char keysym_name[64];
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if (keysym == XKB_KEY_Space)
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<got a space>
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xkb_keysym_get_name(keysym, keysym_name, sizeof(keysym_name));
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~~~
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libxkbcommon also supports an extension to the classic XKB, whereby a
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single event can result in multiple keysyms. Here's how to use it:
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~~~{.c}
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const xkb_keysym_t *keysyms;
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int num_keysyms;
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num_keysyms = xkb_state_key_get_syms(state, keycode, &keysyms);
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~~~
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We can also get a UTF-8 string representation for this key:
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~~~{.c}
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char *buffer;
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int size;
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// First find the needed size; return value is the same as snprintf(3).
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size = xkb_state_key_get_utf8(state, keycode, NULL, 0) + 1;
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if (size <= 1) <nothing to do>
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buffer = <allocate size bytes>
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xkb_state_key_get_utf8(state, keycode, buffer, size);
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~~~
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Of course, we also need to keep the `xkb_state` up-to-date with the
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keyboard device, if we want to get the correct keysyms in the future.
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If we are an evdev client, we must let the library know whether a key
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is pressed or released at any given time:
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~~~{.c}
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enum xkb_state_component changed;
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if (<key press>)
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changed = xkb_state_update_key(state, keycode, XKB_KEY_DOWN);
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else if (<key release>)
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changed = xkb_state_update_key(state, keycode, XKB_KEY_UP);
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~~~
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The `changed` return value tells us exactly which parts of the state
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have changed.
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If it is a key-repeat event, we can ask the keymap what to do with it:
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~~~{.c}
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if (<key repeat> && !xkb_keymap_key_repeats(keymap, keycode))
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<discard event>
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~~~
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On the other hand, if we are an X or Wayland client, the server already
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does the hard work for us. It notifies us when the device's state
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changes, and we can simply use what it tells us (the necessary
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information usually comes in a form of some "state changed" event):
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~~~{.c}
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changed = xkb_state_update_mask(state,
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event->depressed_mods,
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event->latched_mods,
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event->locked_mods,
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event->depressed_layout,
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event->latched_layout,
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event->locked_layout);
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~~~
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Now that we have an always-up-to-date `xkb_state`, we can examine it.
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For example, we can check whether the Control modifier is active, or
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whether the Num Lock LED is active:
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~~~{.c}
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if (xkb_state_mod_name_is_active(state, XKB_MOD_NAME_CTRL,
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XKB_STATE_MODS_EFFECTIVE) > 0)
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<The Control modifier is active>
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if (xkb_state_led_name_is_active(state, XKB_LED_NAME_NUM) > 0)
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<The Num Lock LED is active>
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~~~
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And that's it! Eventually, we should free the objects we've created:
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~~~{.c}
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xkb_state_unref(state);
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xkb_keymap_unref(keymap);
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xkb_context_unref(ctx);
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~~~
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