~kennylevinsen/wlavu

e1d4afd02853f31f5e4367b46050ddef117ef0f5 — Kenny Levinsen 4 years ago
Initial commit
5 files changed, 2237 insertions(+), 0 deletions(-)

A LICENSE
A main.c
A meson.build
A wlr-layer-shell-unstable-v1.xml
A xdg-shell.xml
A  => LICENSE +7 -0
@@ 1,7 @@
Copyright 2020 Kenny Levinsen

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 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.

A  => main.c +590 -0
@@ 1,590 @@
#define _POSIX_C_SOURCE 200809L
#include <alsa/asoundlib.h>
#include <EGL/egl.h>
#include <GLES2/gl2.h>
#include <GL/glut.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include <unistd.h>
#include <limits.h>
#include <math.h>
#include <wayland-client.h>
#include <wayland-client-protocol.h>
#include <wayland-egl.h>
#ifdef __linux__
#include <linux/input-event-codes.h>
#elif __FreeBSD__
#include <dev/evdev/input-event-codes.h>
#endif

#include "wlr-layer-shell-unstable-v1-client-protocol.h"
#include "xdg-shell-client-protocol.h"

struct context {
	struct wl_compositor *compositor;
	struct wl_surface *surface;
	struct xdg_wm_base *xdg_wm_base;
	struct xdg_surface *xdg_surface;
	struct xdg_toplevel *xdg_toplevel;
	struct zwlr_layer_shell_v1 *layer_shell;
	struct zwlr_layer_surface_v1 *layer_surface;
	struct wl_seat *seat;

	int width;
	int height;

	struct wl_egl_window *wl_egl_window;
	EGLConfig egl_config;
	EGLContext egl_context;
	EGLDisplay egl_display;
	EGLSurface egl_surface;

	bool running;	
};

static void layer_surface_configure(void *data,
		struct zwlr_layer_surface_v1 *surface,
		uint32_t serial, uint32_t width, uint32_t height) {
	struct context *ctx = data;
	ctx->width = width;
	ctx->height = height;
	if (ctx->wl_egl_window) {
		wl_egl_window_resize(ctx->wl_egl_window, width, height, 0, 0);
	}
	if (ctx->egl_surface) {
		eglMakeCurrent(ctx->egl_display, ctx->egl_surface, ctx->egl_surface, ctx->egl_context);
		glViewport(0, 0, width, height);
	}
	zwlr_layer_surface_v1_ack_configure(surface, serial);
}

static void layer_surface_closed(void *data,
		struct zwlr_layer_surface_v1 *surface) {
	(void)surface;
	struct context *ctx = data;
	zwlr_layer_surface_v1_destroy(ctx->layer_surface);
	ctx->running = false;
}

struct zwlr_layer_surface_v1_listener layer_surface_listener = {
	.configure = layer_surface_configure,
	.closed = layer_surface_closed,
};

static void xdg_toplevel_configure(void *data,
		struct xdg_toplevel *xdg_toplevel, int32_t width, int32_t height,
		struct wl_array *states) {
	(void)xdg_toplevel;
	(void)states;
	struct context *ctx = data;
	if (width == 0 || height == 0 ||
			(ctx->width == width && ctx->height == height)) {
		return;
	}
	ctx->width = width;
	ctx->height = height;
	if (ctx->wl_egl_window) {
		wl_egl_window_resize(ctx->wl_egl_window, width, height, 0, 0);
	}
	if (ctx->egl_surface != NULL) {
		eglMakeCurrent(ctx->egl_display, ctx->egl_surface, ctx->egl_surface, ctx->egl_context);
		glViewport(0, 0, width, height);
	}
}

static void xdg_surface_handle_configure(void *data,
		struct xdg_surface *xdg_surface, uint32_t serial) {
	(void)data;
	xdg_surface_ack_configure(xdg_surface, serial);
}

static const struct xdg_surface_listener xdg_surface_listener = {
	.configure = xdg_surface_handle_configure,
};

static void xdg_toplevel_handle_close(void *data,
		struct xdg_toplevel *xdg_toplevel) {
	(void)xdg_toplevel;
	struct context *ctx = data;
	xdg_toplevel_destroy(ctx->xdg_toplevel);
	xdg_surface_destroy(ctx->xdg_surface);
	ctx->running = false;
}

static const struct xdg_toplevel_listener xdg_toplevel_listener = {
	.configure = xdg_toplevel_configure,
	.close = xdg_toplevel_handle_close,
};

static void pointer_handle_button(void *data, struct wl_pointer *pointer,
		uint32_t serial, uint32_t time, uint32_t button, uint32_t state) {
	(void)pointer;
	(void)time;
	struct context *ctx = data;

	if (ctx->xdg_toplevel != NULL && button == BTN_LEFT && state == WL_POINTER_BUTTON_STATE_PRESSED) {
		xdg_toplevel_move(ctx->xdg_toplevel, ctx->seat, serial);
	}
}

static void noop() {
	// noop
}

static const struct wl_pointer_listener pointer_listener = {
	.enter = noop,
	.leave = noop,
	.motion = noop,
	.button = pointer_handle_button,
	.axis = noop,
};

static void seat_handle_capabilities(void *data, struct wl_seat *seat,
		uint32_t capabilities) {
	struct context *ctx = data;
	if (capabilities & WL_SEAT_CAPABILITY_POINTER) {
		struct wl_pointer *pointer = wl_seat_get_pointer(seat);
		wl_pointer_add_listener(pointer, &pointer_listener, ctx);
	}
}

static const struct wl_seat_listener seat_listener = {
	.capabilities = seat_handle_capabilities,
};

static void handle_global(void *data, struct wl_registry *registry,
		uint32_t name, const char *interface, uint32_t version) {
	(void)version;
	struct context *ctx = data;
	if (strcmp(interface, wl_seat_interface.name) == 0) {
		ctx->seat = wl_registry_bind(registry, name, &wl_seat_interface, 1);
		wl_seat_add_listener(ctx->seat, &seat_listener, ctx);
	} else if (strcmp(interface, wl_compositor_interface.name) == 0) {
		ctx->compositor =
			wl_registry_bind(registry, name, &wl_compositor_interface, 1);
	} else if (strcmp(interface, xdg_wm_base_interface.name) == 0) {
		ctx->xdg_wm_base =
			wl_registry_bind(registry, name, &xdg_wm_base_interface, 1);
	} else if (strcmp(interface, zwlr_layer_shell_v1_interface.name) == 0) {
		ctx->layer_shell = wl_registry_bind(registry, name, &zwlr_layer_shell_v1_interface, 1);
	}
}

static void handle_global_remove(void *data, struct wl_registry *registry,
		uint32_t name) {
	(void)data;
	(void)registry;
	(void)name;
}

static const struct wl_registry_listener registry_listener = {
	.global = handle_global,
	.global_remove = handle_global_remove,
};

static void draw_horiz(double val) {
	glVertex2f(-1,-1);
	glVertex2f(2*val-1, -1);
	glVertex2f(2*val-1, 1);
	glVertex2f(-1, 1);
}

static void draw_vert(double val) {
	glVertex2f(-1,-1);
	glVertex2f(1, -1);
	glVertex2f(1, 2*val-1);
	glVertex2f(-1, 2*val-1);
}

static int draw(struct context *ctx, double val, double peak) {
	glClear(GL_COLOR_BUFFER_BIT);

	void (*draw_bar)(double val);
	if (ctx->height > ctx->width) {
		draw_bar = draw_vert;
	} else {
		draw_bar = draw_horiz;
	}

	if (peak > 0.9) {
		glColor3f(.5, 0.0, 0.0);
	} else {
		glColor3f(0.25, .25, 0.25);
	}
	glBegin(GL_POLYGON);
	draw_bar(peak);
	glEnd();

	glColor3f(0.0, 1.0, 0.0);
	glBegin(GL_POLYGON);
	draw_bar(val);
	glEnd();

	if (!eglSwapBuffers(ctx->egl_display, ctx->egl_surface)) {
		fprintf(stderr, "eglSwapBuffers failed\n");
		return -1;
	}

	return 0;
}

#define PEAK_DURATION 20
#define HYSTERESIS 0.001

static int max_s16(void *buffer, int frames, int channels) {
	int max = 0;
	for (int i = 0; i < frames*channels; i++) {
		int b = abs(((short*)buffer)[i]);
		if (b > max)
			max = b;
	}
	return max;
}

static int max_s32(void *buffer, int frames, int channels) {
	int max = 0;
	for (int i = 0; i < frames*channels; i++) {
		int b = abs(((int*)buffer)[i]);
		if (b > max)
			max = b;
	}
	return max;
}

static int display_dispatch(struct pollfd *pfd, int polln, struct wl_display *display, int timeout) {
	assert(polln > 0);
	if (wl_display_prepare_read(display) == -1) {
		return wl_display_dispatch_pending(display);
	}

	pfd[0].events = POLLOUT;
	while (wl_display_flush(display) == -1) {
		if (errno != EAGAIN && errno != EPIPE) {
			wl_display_cancel_read(display);
			return -1;
		}

		// We only poll the wayland fd here
		while (poll(pfd, 1, -1) == -1) {
			if (errno != EINTR) {
				wl_display_cancel_read(display);
				return -1;
			}
		}
	}

	pfd[0].events = POLLIN;
	while (poll(pfd, polln, timeout) == -1) {
		if (errno != EINTR) {
			wl_display_cancel_read(display);
			return -1;
		}
	}

	if ((pfd[0].revents & POLLIN) == 0) {
		wl_display_cancel_read(display);
		return 0;
	}

	if (wl_display_read_events(display) == -1) {
		return -1;
	}

	return wl_display_dispatch_pending(display);
}

static snd_pcm_t *open_pcm(char *device, void **buffer, int *frame_capacity, unsigned int *channels, int *bits) {
	int ret;
	snd_pcm_t *handle_capture;
	if ((ret = snd_pcm_open(&handle_capture, device, SND_PCM_STREAM_CAPTURE, SND_PCM_NONBLOCK)) != 0) {
		fprintf(stderr, "Could not open capture device '%s': %s\n", device, snd_strerror(ret));
		return NULL;
	}

	snd_pcm_hw_params_t *hw_params;
	if ((ret = snd_pcm_hw_params_malloc(&hw_params)) != 0) {
		fprintf(stderr, "Could not allocate hardware parameter structure (%s)\n",
				snd_strerror(ret));
		return NULL;
	}
	
	if ((ret = snd_pcm_hw_params_any(handle_capture, hw_params)) != 0) {
		fprintf(stderr, "Could not initialize hardware parameter structure (%s)\n",
				snd_strerror(ret));
		return NULL;
	}

	snd_pcm_hw_params_get_channels(hw_params, channels);
	
	unsigned int rate = 44100;
	snd_pcm_hw_params_get_rate(hw_params, &rate, 0);

	snd_pcm_format_t format;
	snd_pcm_hw_params_get_format(hw_params, &format);

	switch (format) {
	case SND_PCM_FORMAT_S32_LE:
		*bits = 32;
		break;
	case SND_PCM_FORMAT_S16_LE:
		*bits = 16;
		break;
	default:
		fprintf(stderr, "Unknown format for input device: %d\n", format);
		return NULL;
	}

	snd_pcm_hw_params_set_access(handle_capture, hw_params, SND_PCM_ACCESS_RW_INTERLEAVED);
	if ((ret = snd_pcm_hw_params(handle_capture, hw_params)) != 0) {
		fprintf(stderr, "Could not set hardware parameters (%s)\n",
				snd_strerror(ret));
		return NULL;
	}

	int bufsize = rate * (*bits / 8) / PEAK_DURATION;
	*buffer = calloc(*channels, bufsize);
	if (*buffer == NULL) {
		fprintf(stderr, "Could not allocate buffer: %s\n", strerror(errno));
		return NULL;
	}
	*frame_capacity = bufsize / 4;
	return handle_capture;
}

static const char usage[] = ""
"usage: %s [options] device\n"
"  -h		show this help message\n"
"  -l           use layer shell\n"
"  -w <width>   bar width when using layer shell\n"
"  -a <side>    side to anchor to (left, right, top, bottom)\n"
"  device	ALSA device (e.g. 'dsnoop:0,0')\n";

int main(int argc, char **argv) {
	bool use_layer_shell = false;
	int bar_width = 8;
	int anchor = ZWLR_LAYER_SURFACE_V1_ANCHOR_TOP |
			ZWLR_LAYER_SURFACE_V1_ANCHOR_LEFT |
			ZWLR_LAYER_SURFACE_V1_ANCHOR_BOTTOM;
	bool vertical = true;

	int opt;
	while ((opt = getopt(argc, argv, "hlw:a:")) != -1) {
		switch (opt) {
		case 'l':
			use_layer_shell = true;
			break;
		case 'w':
			bar_width = strtol(optarg, NULL, 10);
			break;
		case 'a':
			if (strcmp(optarg, "left") == 0) {
				anchor = ZWLR_LAYER_SURFACE_V1_ANCHOR_TOP |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_LEFT |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_BOTTOM;
				vertical = true;
			} else if (strcmp(optarg, "right") == 0) {
				anchor = ZWLR_LAYER_SURFACE_V1_ANCHOR_TOP |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_RIGHT |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_BOTTOM;
				vertical = true;
			} else if (strcmp(optarg, "top") == 0) {
				anchor = ZWLR_LAYER_SURFACE_V1_ANCHOR_TOP |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_RIGHT |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_LEFT;
				vertical = false;
			} else if (strcmp(optarg, "bottom") == 0) {
				anchor = ZWLR_LAYER_SURFACE_V1_ANCHOR_BOTTOM |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_RIGHT |
					ZWLR_LAYER_SURFACE_V1_ANCHOR_LEFT;
				vertical = false;
			} else {
				fprintf(stderr, "unknown side: %s\n", optarg);
				return EXIT_FAILURE;
			}
			break;
		default:
			fprintf(stderr, usage, argv[0]);
			return opt == 'h' ? EXIT_SUCCESS : EXIT_FAILURE;
		}
	}

	if (optind >= argc) {
		fprintf(stderr, "Expected an ALSA device name after arguments\n");
		return EXIT_FAILURE;
	}
	char *device = argv[optind];

	struct context ctx = {
		.height = bar_width,
		.width = 1024,
		.running = true,
	};

	void *buffer = NULL;
	int frame_capacity = 0, bits = 0;
	unsigned int channels = 0;
	snd_pcm_t *handle_capture = open_pcm(device, &buffer, &frame_capacity, &channels, &bits);
	if (handle_capture == NULL) {
		return EXIT_FAILURE;
	}

	struct wl_display *display = wl_display_connect(NULL);
	if (display == NULL) {
		fprintf(stderr, "failed to create display\n");
		return EXIT_FAILURE;
	}

	struct wl_registry *registry = wl_display_get_registry(display);
	wl_registry_add_listener(registry, &registry_listener, &ctx);
	wl_display_dispatch(display);
	wl_display_roundtrip(display);

	if (ctx.compositor == NULL || ctx.xdg_wm_base == NULL) {
		fprintf(stderr, "no wl_compositor support\n");
		return EXIT_FAILURE;
	}

	ctx.egl_display = eglGetDisplay((EGLNativeDisplayType)display);
	if (ctx.egl_display == EGL_NO_DISPLAY) {
		fprintf(stderr, "failed to create EGL display\n");
		return EXIT_FAILURE;
	}

	eglBindAPI(EGL_OPENGL_API);
	glutInit(&argc, argv);

	EGLint major, minor;
	if (!eglInitialize(ctx.egl_display, &major, &minor)) {
		fprintf(stderr, "failed to initialize EGL\n");
		return EXIT_FAILURE;
	}

	EGLint count;
	eglGetConfigs(ctx.egl_display, NULL, 0, &count);

	EGLint config_attribs[] = {
		EGL_SURFACE_TYPE, EGL_WINDOW_BIT,
		EGL_RED_SIZE, 8,
		EGL_GREEN_SIZE, 8,
		EGL_BLUE_SIZE, 8,
		EGL_RENDERABLE_TYPE, EGL_OPENGL_ES2_BIT,
		EGL_NONE,
	};
	EGLint n = 0;
	EGLConfig *configs = calloc(count, sizeof(EGLConfig));
	eglChooseConfig(ctx.egl_display, config_attribs, configs, count, &n);
	if (n == 0) {
		fprintf(stderr, "failed to choose an EGL config\n");
		return EXIT_FAILURE;
	}
	ctx.egl_config = configs[0];

	EGLint context_attribs[] = {
		EGL_CONTEXT_CLIENT_VERSION, 2,
		EGL_NONE,
	};
	ctx.egl_context = eglCreateContext(ctx.egl_display, ctx.egl_config,
		EGL_NO_CONTEXT, context_attribs);

	ctx.surface = wl_compositor_create_surface(ctx.compositor);

	if (!use_layer_shell) {
		if (ctx.xdg_wm_base == NULL) {
			fprintf(stderr, "no xdg_wm_base support\n");
			return EXIT_FAILURE;
		}
		ctx.xdg_surface = xdg_wm_base_get_xdg_surface(ctx.xdg_wm_base, ctx.surface);
		ctx.xdg_toplevel = xdg_surface_get_toplevel(ctx.xdg_surface);

		xdg_surface_add_listener(ctx.xdg_surface, &xdg_surface_listener, &ctx);
		xdg_toplevel_add_listener(ctx.xdg_toplevel, &xdg_toplevel_listener, &ctx);
	} else {
		if (ctx.layer_shell == NULL) {
			fprintf(stderr, "no layer_shell support\n");
			return EXIT_FAILURE;
		}
		ctx.layer_surface = zwlr_layer_shell_v1_get_layer_surface(ctx.layer_shell, ctx.surface,
				NULL, ZWLR_LAYER_SHELL_V1_LAYER_TOP, "wlavu");
		if (vertical) {
			zwlr_layer_surface_v1_set_size(ctx.layer_surface, bar_width, 0);
		} else {
			zwlr_layer_surface_v1_set_size(ctx.layer_surface, 0, bar_width);
		}
		zwlr_layer_surface_v1_set_anchor(ctx.layer_surface, anchor);
		zwlr_layer_surface_v1_set_exclusive_zone(ctx.layer_surface, bar_width);
		zwlr_layer_surface_v1_add_listener(ctx.layer_surface, &layer_surface_listener, &ctx);
	}

	wl_surface_commit(ctx.surface);
	wl_display_roundtrip(display);
	
	ctx.wl_egl_window = wl_egl_window_create(ctx.surface, ctx.width, ctx.height);
	ctx.egl_surface = eglCreateWindowSurface(ctx.egl_display, ctx.egl_config,
		(EGLNativeWindowType)ctx.wl_egl_window, NULL);

	if (!eglMakeCurrent(ctx.egl_display, ctx.egl_surface, ctx.egl_surface, ctx.egl_context)) {
		fprintf(stderr, "eglMakeCurrent failed\n");
		return EXIT_FAILURE;
	}

	eglSwapInterval(ctx.egl_display, 0);


	int polln = snd_pcm_poll_descriptors_count(handle_capture) + 1;
	struct pollfd *pfd = calloc(polln, sizeof(struct pollfd));
	if (pfd == NULL) {
		fprintf(stderr, "Could not allocate poll descriptors\n");
		return EXIT_FAILURE;
	}
	pfd[0].fd = wl_display_get_fd(display);
	polln = snd_pcm_poll_descriptors(handle_capture, &pfd[1], polln-1) + 1;
	// For some reason we must read at least once
	snd_pcm_readi(handle_capture, buffer, frame_capacity);

	draw(&ctx, 0.0, 0.0);
	
	double peak;
	int peak_timer = 0;
	double divisor = INT_MAX;
	int (*max)(void *buffer, int frames, int channels) = bits == 32 ? max_s32 : max_s16;

	int ret;
	while (display_dispatch(pfd, polln, display, -1) != -1 && ctx.running) {
		unsigned short revent = 0;
		if ((ret = snd_pcm_poll_descriptors_revents(handle_capture, &pfd[1], polln-1, &revent)) != 0) {
			fprintf(stderr, "Could not convert alsa revents (%s)\n",
					snd_strerror(ret));
			return EXIT_FAILURE;
		}
		if ((revent & POLLIN) == 0) {
			continue;
		}
		snd_pcm_sframes_t frames = snd_pcm_readi(handle_capture, buffer, frame_capacity);

		if (frames < 0) {
			if ((ret = snd_pcm_recover(handle_capture, frames, 0)) != 0) {
				fprintf(stderr, "Could not recover from read error: %s\n", snd_strerror(ret));
				return EXIT_FAILURE;
			}
			continue;
		}

		double val = ((double)max(buffer, frames, channels)) / divisor;
		if (val >= peak || peak_timer == 0) {
			peak = val;
			peak_timer = PEAK_DURATION;
		} else if (peak_timer > 0) {
			peak_timer--;
		}

		draw(&ctx, val, peak);
	}

	snd_pcm_close(handle_capture);
	wl_surface_destroy(ctx.surface);

	return EXIT_SUCCESS;
}

A  => meson.build +66 -0
@@ 1,66 @@
project(
	'wlavu',
	'c',
	license: 'MIT',
	meson_version: '>=0.53.0',
	default_options: [
		'c_std=c11',
		'warning_level=3',
		'werror=true',
	],
)

add_project_arguments(
	[
		'-Wundef',
		'-Wunused',
		'-Wlogical-op',
		'-Wmissing-include-dirs',
		'-Wpointer-arith',
		'-Wimplicit-fallthrough',
		'-Wmissing-prototypes',
		'-Wno-unknown-warning-option',
		'-Wno-unused-command-line-argument',
		'-Wvla',
		'-Wl,--exclude-libs=ALL',
		'-D_USE_MATH_DEFINES',
		'-D_XOPEN_SOURCE=700',
	],
	language: 'c',
)

scanner = find_program('wayland-scanner')
scanner_private_code = generator(scanner, output: '@BASENAME@-protocol.c', arguments: ['private-code', '@INPUT@', '@OUTPUT@'])
scanner_client_header = generator(scanner, output: '@BASENAME@-client-protocol.h', arguments: ['client-header', '@INPUT@', '@OUTPUT@'])

protocols_src = [
	scanner_private_code.process('xdg-shell.xml'),
	scanner_private_code.process('wlr-layer-shell-unstable-v1.xml'),
]
protocols_headers = [
	scanner_client_header.process('xdg-shell.xml'),
	scanner_client_header.process('wlr-layer-shell-unstable-v1.xml'),
]

wl_client = dependency('wayland-client')
wl_protocols = dependency('wayland-protocols')
lib_protocols = static_library('protocols', protocols_src + protocols_headers, dependencies: wl_client)
protocols_dep = declare_dependency(link_with: lib_protocols, sources: protocols_headers)

cc = meson.get_compiler('c')

executable(
	'wlavu',
	['main.c'],
	dependencies: [
		protocols_dep,
		cc.find_library('m'),
		cc.find_library('asound'),
		dependency('freeglut'),
		dependency('gl'),
		dependency('glesv2'),
		dependency('egl'),
		dependency('wayland-egl'),
	],
	install: true
)

A  => wlr-layer-shell-unstable-v1.xml +325 -0
@@ 1,325 @@
<?xml version="1.0" encoding="UTF-8"?>
<protocol name="wlr_layer_shell_unstable_v1">
  <copyright>
    Copyright © 2017 Drew DeVault

    Permission to use, copy, modify, distribute, and sell this
    software and its documentation for any purpose is hereby granted
    without fee, provided that the above copyright notice appear in
    all copies and that both that copyright notice and this permission
    notice appear in supporting documentation, and that the name of
    the copyright holders not be used in advertising or publicity
    pertaining to distribution of the software without specific,
    written prior permission.  The copyright holders make no
    representations about the suitability of this software for any
    purpose.  It is provided "as is" without express or implied
    warranty.

    THE COPYRIGHT HOLDERS DISCLAIM ALL WARRANTIES WITH REGARD TO THIS
    SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND
    FITNESS, IN NO EVENT SHALL THE COPYRIGHT HOLDERS BE LIABLE FOR ANY
    SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
    WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN
    AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION,
    ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF
    THIS SOFTWARE.
  </copyright>

  <interface name="zwlr_layer_shell_v1" version="3">
    <description summary="create surfaces that are layers of the desktop">
      Clients can use this interface to assign the surface_layer role to
      wl_surfaces. Such surfaces are assigned to a "layer" of the output and
      rendered with a defined z-depth respective to each other. They may also be
      anchored to the edges and corners of a screen and specify input handling
      semantics. This interface should be suitable for the implementation of
      many desktop shell components, and a broad number of other applications
      that interact with the desktop.
    </description>

    <request name="get_layer_surface">
      <description summary="create a layer_surface from a surface">
        Create a layer surface for an existing surface. This assigns the role of
        layer_surface, or raises a protocol error if another role is already
        assigned.

        Creating a layer surface from a wl_surface which has a buffer attached
        or committed is a client error, and any attempts by a client to attach
        or manipulate a buffer prior to the first layer_surface.configure call
        must also be treated as errors.

        After creating a layer_surface object and setting it up, the client
        must perform an initial commit without any buffer attached.
        The compositor will reply with a layer_surface.configure event.
        The client must acknowledge it and is then allowed to attach a buffer
        to map the surface.

        You may pass NULL for output to allow the compositor to decide which
        output to use. Generally this will be the one that the user most
        recently interacted with.

        Clients can specify a namespace that defines the purpose of the layer
        surface.
      </description>
      <arg name="id" type="new_id" interface="zwlr_layer_surface_v1"/>
      <arg name="surface" type="object" interface="wl_surface"/>
      <arg name="output" type="object" interface="wl_output" allow-null="true"/>
      <arg name="layer" type="uint" enum="layer" summary="layer to add this surface to"/>
      <arg name="namespace" type="string" summary="namespace for the layer surface"/>
    </request>

    <enum name="error">
      <entry name="role" value="0" summary="wl_surface has another role"/>
      <entry name="invalid_layer" value="1" summary="layer value is invalid"/>
      <entry name="already_constructed" value="2" summary="wl_surface has a buffer attached or committed"/>
    </enum>

    <enum name="layer">
      <description summary="available layers for surfaces">
        These values indicate which layers a surface can be rendered in. They
        are ordered by z depth, bottom-most first. Traditional shell surfaces
        will typically be rendered between the bottom and top layers.
        Fullscreen shell surfaces are typically rendered at the top layer.
        Multiple surfaces can share a single layer, and ordering within a
        single layer is undefined.
      </description>

      <entry name="background" value="0"/>
      <entry name="bottom" value="1"/>
      <entry name="top" value="2"/>
      <entry name="overlay" value="3"/>
    </enum>

    <!-- Version 3 additions -->

    <request name="destroy" type="destructor" since="3">
      <description summary="destroy the layer_shell object">
        This request indicates that the client will not use the layer_shell
        object any more. Objects that have been created through this instance
        are not affected.
      </description>
    </request>
  </interface>

  <interface name="zwlr_layer_surface_v1" version="3">
    <description summary="layer metadata interface">
      An interface that may be implemented by a wl_surface, for surfaces that
      are designed to be rendered as a layer of a stacked desktop-like
      environment.

      Layer surface state (layer, size, anchor, exclusive zone,
      margin, interactivity) is double-buffered, and will be applied at the
      time wl_surface.commit of the corresponding wl_surface is called.

      Attaching a null buffer to a layer surface unmaps it.

      Unmapping a layer_surface means that the surface cannot be shown by the
      compositor until it is explicitly mapped again. The layer_surface
      returns to the state it had right after layer_shell.get_layer_surface.
      The client can re-map the surface by performing a commit without any
      buffer attached, waiting for a configure event and handling it as usual.
    </description>

    <request name="set_size">
      <description summary="sets the size of the surface">
        Sets the size of the surface in surface-local coordinates. The
        compositor will display the surface centered with respect to its
        anchors.

        If you pass 0 for either value, the compositor will assign it and
        inform you of the assignment in the configure event. You must set your
        anchor to opposite edges in the dimensions you omit; not doing so is a
        protocol error. Both values are 0 by default.

        Size is double-buffered, see wl_surface.commit.
      </description>
      <arg name="width" type="uint"/>
      <arg name="height" type="uint"/>
    </request>

    <request name="set_anchor">
      <description summary="configures the anchor point of the surface">
        Requests that the compositor anchor the surface to the specified edges
        and corners. If two orthogonal edges are specified (e.g. 'top' and
        'left'), then the anchor point will be the intersection of the edges
        (e.g. the top left corner of the output); otherwise the anchor point
        will be centered on that edge, or in the center if none is specified.

        Anchor is double-buffered, see wl_surface.commit.
      </description>
      <arg name="anchor" type="uint" enum="anchor"/>
    </request>

    <request name="set_exclusive_zone">
      <description summary="configures the exclusive geometry of this surface">
        Requests that the compositor avoids occluding an area with other
        surfaces. The compositor's use of this information is
        implementation-dependent - do not assume that this region will not
        actually be occluded.

        A positive value is only meaningful if the surface is anchored to one
        edge or an edge and both perpendicular edges. If the surface is not
        anchored, anchored to only two perpendicular edges (a corner), anchored
        to only two parallel edges or anchored to all edges, a positive value
        will be treated the same as zero.

        A positive zone is the distance from the edge in surface-local
        coordinates to consider exclusive.

        Surfaces that do not wish to have an exclusive zone may instead specify
        how they should interact with surfaces that do. If set to zero, the
        surface indicates that it would like to be moved to avoid occluding
        surfaces with a positive exclusive zone. If set to -1, the surface
        indicates that it would not like to be moved to accommodate for other
        surfaces, and the compositor should extend it all the way to the edges
        it is anchored to.

        For example, a panel might set its exclusive zone to 10, so that
        maximized shell surfaces are not shown on top of it. A notification
        might set its exclusive zone to 0, so that it is moved to avoid
        occluding the panel, but shell surfaces are shown underneath it. A
        wallpaper or lock screen might set their exclusive zone to -1, so that
        they stretch below or over the panel.

        The default value is 0.

        Exclusive zone is double-buffered, see wl_surface.commit.
      </description>
      <arg name="zone" type="int"/>
    </request>

    <request name="set_margin">
      <description summary="sets a margin from the anchor point">
        Requests that the surface be placed some distance away from the anchor
        point on the output, in surface-local coordinates. Setting this value
        for edges you are not anchored to has no effect.

        The exclusive zone includes the margin.

        Margin is double-buffered, see wl_surface.commit.
      </description>
      <arg name="top" type="int"/>
      <arg name="right" type="int"/>
      <arg name="bottom" type="int"/>
      <arg name="left" type="int"/>
    </request>

    <request name="set_keyboard_interactivity">
      <description summary="requests keyboard events">
        Set to 1 to request that the seat send keyboard events to this layer
        surface. For layers below the shell surface layer, the seat will use
        normal focus semantics. For layers above the shell surface layers, the
        seat will always give exclusive keyboard focus to the top-most layer
        which has keyboard interactivity set to true.

        Layer surfaces receive pointer, touch, and tablet events normally. If
        you do not want to receive them, set the input region on your surface
        to an empty region.

        Events is double-buffered, see wl_surface.commit.
      </description>
      <arg name="keyboard_interactivity" type="uint"/>
    </request>

    <request name="get_popup">
      <description summary="assign this layer_surface as an xdg_popup parent">
        This assigns an xdg_popup's parent to this layer_surface.  This popup
        should have been created via xdg_surface::get_popup with the parent set
        to NULL, and this request must be invoked before committing the popup's
        initial state.

        See the documentation of xdg_popup for more details about what an
        xdg_popup is and how it is used.
      </description>
      <arg name="popup" type="object" interface="xdg_popup"/>
    </request>

    <request name="ack_configure">
      <description summary="ack a configure event">
        When a configure event is received, if a client commits the
        surface in response to the configure event, then the client
        must make an ack_configure request sometime before the commit
        request, passing along the serial of the configure event.

        If the client receives multiple configure events before it
        can respond to one, it only has to ack the last configure event.

        A client is not required to commit immediately after sending
        an ack_configure request - it may even ack_configure several times
        before its next surface commit.

        A client may send multiple ack_configure requests before committing, but
        only the last request sent before a commit indicates which configure
        event the client really is responding to.
      </description>
      <arg name="serial" type="uint" summary="the serial from the configure event"/>
    </request>

    <request name="destroy" type="destructor">
      <description summary="destroy the layer_surface">
        This request destroys the layer surface.
      </description>
    </request>

    <event name="configure">
      <description summary="suggest a surface change">
        The configure event asks the client to resize its surface.

        Clients should arrange their surface for the new states, and then send
        an ack_configure request with the serial sent in this configure event at
        some point before committing the new surface.

        The client is free to dismiss all but the last configure event it
        received.

        The width and height arguments specify the size of the window in
        surface-local coordinates.

        The size is a hint, in the sense that the client is free to ignore it if
        it doesn't resize, pick a smaller size (to satisfy aspect ratio or
        resize in steps of NxM pixels). If the client picks a smaller size and
        is anchored to two opposite anchors (e.g. 'top' and 'bottom'), the
        surface will be centered on this axis.

        If the width or height arguments are zero, it means the client should
        decide its own window dimension.
      </description>
      <arg name="serial" type="uint"/>
      <arg name="width" type="uint"/>
      <arg name="height" type="uint"/>
    </event>

    <event name="closed">
      <description summary="surface should be closed">
        The closed event is sent by the compositor when the surface will no
        longer be shown. The output may have been destroyed or the user may
        have asked for it to be removed. Further changes to the surface will be
        ignored. The client should destroy the resource after receiving this
        event, and create a new surface if they so choose.
      </description>
    </event>

    <enum name="error">
      <entry name="invalid_surface_state" value="0" summary="provided surface state is invalid"/>
      <entry name="invalid_size" value="1" summary="size is invalid"/>
      <entry name="invalid_anchor" value="2" summary="anchor bitfield is invalid"/>
    </enum>

    <enum name="anchor" bitfield="true">
      <entry name="top" value="1" summary="the top edge of the anchor rectangle"/>
      <entry name="bottom" value="2" summary="the bottom edge of the anchor rectangle"/>
      <entry name="left" value="4" summary="the left edge of the anchor rectangle"/>
      <entry name="right" value="8" summary="the right edge of the anchor rectangle"/>
    </enum>

    <!-- Version 2 additions -->

    <request name="set_layer" since="2">
      <description summary="change the layer of the surface">
        Change the layer that the surface is rendered on.

        Layer is double-buffered, see wl_surface.commit.
      </description>
      <arg name="layer" type="uint" enum="zwlr_layer_shell_v1.layer" summary="layer to move this surface to"/>
    </request>
  </interface>
</protocol>

A  => xdg-shell.xml +1249 -0
@@ 1,1249 @@
<?xml version="1.0" encoding="UTF-8"?>
<protocol name="xdg_shell">

  <copyright>
    Copyright © 2008-2013 Kristian Høgsberg
    Copyright © 2013      Rafael Antognolli
    Copyright © 2013      Jasper St. Pierre
    Copyright © 2010-2013 Intel Corporation
    Copyright © 2015-2017 Samsung Electronics Co., Ltd
    Copyright © 2015-2017 Red Hat Inc.

    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.
  </copyright>

  <interface name="xdg_wm_base" version="3">
    <description summary="create desktop-style surfaces">
      The xdg_wm_base interface is exposed as a global object enabling clients
      to turn their wl_surfaces into windows in a desktop environment. It
      defines the basic functionality needed for clients and the compositor to
      create windows that can be dragged, resized, maximized, etc, as well as
      creating transient windows such as popup menus.
    </description>

    <enum name="error">
      <entry name="role" value="0" summary="given wl_surface has another role"/>
      <entry name="defunct_surfaces" value="1"
	     summary="xdg_wm_base was destroyed before children"/>
      <entry name="not_the_topmost_popup" value="2"
	     summary="the client tried to map or destroy a non-topmost popup"/>
      <entry name="invalid_popup_parent" value="3"
	     summary="the client specified an invalid popup parent surface"/>
      <entry name="invalid_surface_state" value="4"
	     summary="the client provided an invalid surface state"/>
      <entry name="invalid_positioner" value="5"
	     summary="the client provided an invalid positioner"/>
    </enum>

    <request name="destroy" type="destructor">
      <description summary="destroy xdg_wm_base">
	Destroy this xdg_wm_base object.

	Destroying a bound xdg_wm_base object while there are surfaces
	still alive created by this xdg_wm_base object instance is illegal
	and will result in a protocol error.
      </description>
    </request>

    <request name="create_positioner">
      <description summary="create a positioner object">
	Create a positioner object. A positioner object is used to position
	surfaces relative to some parent surface. See the interface description
	and xdg_surface.get_popup for details.
      </description>
      <arg name="id" type="new_id" interface="xdg_positioner"/>
    </request>

    <request name="get_xdg_surface">
      <description summary="create a shell surface from a surface">
	This creates an xdg_surface for the given surface. While xdg_surface
	itself is not a role, the corresponding surface may only be assigned
	a role extending xdg_surface, such as xdg_toplevel or xdg_popup.

	This creates an xdg_surface for the given surface. An xdg_surface is
	used as basis to define a role to a given surface, such as xdg_toplevel
	or xdg_popup. It also manages functionality shared between xdg_surface
	based surface roles.

	See the documentation of xdg_surface for more details about what an
	xdg_surface is and how it is used.
      </description>
      <arg name="id" type="new_id" interface="xdg_surface"/>
      <arg name="surface" type="object" interface="wl_surface"/>
    </request>

    <request name="pong">
      <description summary="respond to a ping event">
	A client must respond to a ping event with a pong request or
	the client may be deemed unresponsive. See xdg_wm_base.ping.
      </description>
      <arg name="serial" type="uint" summary="serial of the ping event"/>
    </request>

    <event name="ping">
      <description summary="check if the client is alive">
	The ping event asks the client if it's still alive. Pass the
	serial specified in the event back to the compositor by sending
	a "pong" request back with the specified serial. See xdg_wm_base.pong.

	Compositors can use this to determine if the client is still
	alive. It's unspecified what will happen if the client doesn't
	respond to the ping request, or in what timeframe. Clients should
	try to respond in a reasonable amount of time.

	A compositor is free to ping in any way it wants, but a client must
	always respond to any xdg_wm_base object it created.
      </description>
      <arg name="serial" type="uint" summary="pass this to the pong request"/>
    </event>
  </interface>

  <interface name="xdg_positioner" version="3">
    <description summary="child surface positioner">
      The xdg_positioner provides a collection of rules for the placement of a
      child surface relative to a parent surface. Rules can be defined to ensure
      the child surface remains within the visible area's borders, and to
      specify how the child surface changes its position, such as sliding along
      an axis, or flipping around a rectangle. These positioner-created rules are
      constrained by the requirement that a child surface must intersect with or
      be at least partially adjacent to its parent surface.

      See the various requests for details about possible rules.

      At the time of the request, the compositor makes a copy of the rules
      specified by the xdg_positioner. Thus, after the request is complete the
      xdg_positioner object can be destroyed or reused; further changes to the
      object will have no effect on previous usages.

      For an xdg_positioner object to be considered complete, it must have a
      non-zero size set by set_size, and a non-zero anchor rectangle set by
      set_anchor_rect. Passing an incomplete xdg_positioner object when
      positioning a surface raises an error.
    </description>

    <enum name="error">
      <entry name="invalid_input" value="0" summary="invalid input provided"/>
    </enum>

    <request name="destroy" type="destructor">
      <description summary="destroy the xdg_positioner object">
	Notify the compositor that the xdg_positioner will no longer be used.
      </description>
    </request>

    <request name="set_size">
      <description summary="set the size of the to-be positioned rectangle">
	Set the size of the surface that is to be positioned with the positioner
	object. The size is in surface-local coordinates and corresponds to the
	window geometry. See xdg_surface.set_window_geometry.

	If a zero or negative size is set the invalid_input error is raised.
      </description>
      <arg name="width" type="int" summary="width of positioned rectangle"/>
      <arg name="height" type="int" summary="height of positioned rectangle"/>
    </request>

    <request name="set_anchor_rect">
      <description summary="set the anchor rectangle within the parent surface">
	Specify the anchor rectangle within the parent surface that the child
	surface will be placed relative to. The rectangle is relative to the
	window geometry as defined by xdg_surface.set_window_geometry of the
	parent surface.

	When the xdg_positioner object is used to position a child surface, the
	anchor rectangle may not extend outside the window geometry of the
	positioned child's parent surface.

	If a negative size is set the invalid_input error is raised.
      </description>
      <arg name="x" type="int" summary="x position of anchor rectangle"/>
      <arg name="y" type="int" summary="y position of anchor rectangle"/>
      <arg name="width" type="int" summary="width of anchor rectangle"/>
      <arg name="height" type="int" summary="height of anchor rectangle"/>
    </request>

    <enum name="anchor">
      <entry name="none" value="0"/>
      <entry name="top" value="1"/>
      <entry name="bottom" value="2"/>
      <entry name="left" value="3"/>
      <entry name="right" value="4"/>
      <entry name="top_left" value="5"/>
      <entry name="bottom_left" value="6"/>
      <entry name="top_right" value="7"/>
      <entry name="bottom_right" value="8"/>
    </enum>

    <request name="set_anchor">
      <description summary="set anchor rectangle anchor">
	Defines the anchor point for the anchor rectangle. The specified anchor
	is used derive an anchor point that the child surface will be
	positioned relative to. If a corner anchor is set (e.g. 'top_left' or
	'bottom_right'), the anchor point will be at the specified corner;
	otherwise, the derived anchor point will be centered on the specified
	edge, or in the center of the anchor rectangle if no edge is specified.
      </description>
      <arg name="anchor" type="uint" enum="anchor"
	   summary="anchor"/>
    </request>

    <enum name="gravity">
      <entry name="none" value="0"/>
      <entry name="top" value="1"/>
      <entry name="bottom" value="2"/>
      <entry name="left" value="3"/>
      <entry name="right" value="4"/>
      <entry name="top_left" value="5"/>
      <entry name="bottom_left" value="6"/>
      <entry name="top_right" value="7"/>
      <entry name="bottom_right" value="8"/>
    </enum>

    <request name="set_gravity">
      <description summary="set child surface gravity">
	Defines in what direction a surface should be positioned, relative to
	the anchor point of the parent surface. If a corner gravity is
	specified (e.g. 'bottom_right' or 'top_left'), then the child surface
	will be placed towards the specified gravity; otherwise, the child
	surface will be centered over the anchor point on any axis that had no
	gravity specified.
      </description>
      <arg name="gravity" type="uint" enum="gravity"
	   summary="gravity direction"/>
    </request>

    <enum name="constraint_adjustment" bitfield="true">
      <description summary="constraint adjustments">
	The constraint adjustment value define ways the compositor will adjust
	the position of the surface, if the unadjusted position would result
	in the surface being partly constrained.

	Whether a surface is considered 'constrained' is left to the compositor
	to determine. For example, the surface may be partly outside the
	compositor's defined 'work area', thus necessitating the child surface's
	position be adjusted until it is entirely inside the work area.

	The adjustments can be combined, according to a defined precedence: 1)
	Flip, 2) Slide, 3) Resize.
      </description>
      <entry name="none" value="0">
	<description summary="don't move the child surface when constrained">
	  Don't alter the surface position even if it is constrained on some
	  axis, for example partially outside the edge of an output.
	</description>
      </entry>
      <entry name="slide_x" value="1">
	<description summary="move along the x axis until unconstrained">
	  Slide the surface along the x axis until it is no longer constrained.

	  First try to slide towards the direction of the gravity on the x axis
	  until either the edge in the opposite direction of the gravity is
	  unconstrained or the edge in the direction of the gravity is
	  constrained.

	  Then try to slide towards the opposite direction of the gravity on the
	  x axis until either the edge in the direction of the gravity is
	  unconstrained or the edge in the opposite direction of the gravity is
	  constrained.
	</description>
      </entry>
      <entry name="slide_y" value="2">
	<description summary="move along the y axis until unconstrained">
	  Slide the surface along the y axis until it is no longer constrained.

	  First try to slide towards the direction of the gravity on the y axis
	  until either the edge in the opposite direction of the gravity is
	  unconstrained or the edge in the direction of the gravity is
	  constrained.

	  Then try to slide towards the opposite direction of the gravity on the
	  y axis until either the edge in the direction of the gravity is
	  unconstrained or the edge in the opposite direction of the gravity is
	  constrained.
	</description>
      </entry>
      <entry name="flip_x" value="4">
	<description summary="invert the anchor and gravity on the x axis">
	  Invert the anchor and gravity on the x axis if the surface is
	  constrained on the x axis. For example, if the left edge of the
	  surface is constrained, the gravity is 'left' and the anchor is
	  'left', change the gravity to 'right' and the anchor to 'right'.

	  If the adjusted position also ends up being constrained, the resulting
	  position of the flip_x adjustment will be the one before the
	  adjustment.
	</description>
      </entry>
      <entry name="flip_y" value="8">
	<description summary="invert the anchor and gravity on the y axis">
	  Invert the anchor and gravity on the y axis if the surface is
	  constrained on the y axis. For example, if the bottom edge of the
	  surface is constrained, the gravity is 'bottom' and the anchor is
	  'bottom', change the gravity to 'top' and the anchor to 'top'.

	  The adjusted position is calculated given the original anchor
	  rectangle and offset, but with the new flipped anchor and gravity
	  values.

	  If the adjusted position also ends up being constrained, the resulting
	  position of the flip_y adjustment will be the one before the
	  adjustment.
	</description>
      </entry>
      <entry name="resize_x" value="16">
	<description summary="horizontally resize the surface">
	  Resize the surface horizontally so that it is completely
	  unconstrained.
	</description>
      </entry>
      <entry name="resize_y" value="32">
	<description summary="vertically resize the surface">
	  Resize the surface vertically so that it is completely unconstrained.
	</description>
      </entry>
    </enum>

    <request name="set_constraint_adjustment">
      <description summary="set the adjustment to be done when constrained">
	Specify how the window should be positioned if the originally intended
	position caused the surface to be constrained, meaning at least
	partially outside positioning boundaries set by the compositor. The
	adjustment is set by constructing a bitmask describing the adjustment to
	be made when the surface is constrained on that axis.

	If no bit for one axis is set, the compositor will assume that the child
	surface should not change its position on that axis when constrained.

	If more than one bit for one axis is set, the order of how adjustments
	are applied is specified in the corresponding adjustment descriptions.

	The default adjustment is none.
      </description>
      <arg name="constraint_adjustment" type="uint"
	   summary="bit mask of constraint adjustments"/>
    </request>

    <request name="set_offset">
      <description summary="set surface position offset">
	Specify the surface position offset relative to the position of the
	anchor on the anchor rectangle and the anchor on the surface. For
	example if the anchor of the anchor rectangle is at (x, y), the surface
	has the gravity bottom|right, and the offset is (ox, oy), the calculated
	surface position will be (x + ox, y + oy). The offset position of the
	surface is the one used for constraint testing. See
	set_constraint_adjustment.

	An example use case is placing a popup menu on top of a user interface
	element, while aligning the user interface element of the parent surface
	with some user interface element placed somewhere in the popup surface.
      </description>
      <arg name="x" type="int" summary="surface position x offset"/>
      <arg name="y" type="int" summary="surface position y offset"/>
    </request>

    <!-- Version 3 additions -->

    <request name="set_reactive" since="3">
      <description summary="continuously reconstrain the surface">
	When set reactive, the surface is reconstrained if the conditions used
	for constraining changed, e.g. the parent window moved.

	If the conditions changed and the popup was reconstrained, an
	xdg_popup.configure event is sent with updated geometry, followed by an
	xdg_surface.configure event.
      </description>
    </request>

    <request name="set_parent_size" since="3">
      <description summary="">
	Set the parent window geometry the compositor should use when
	positioning the popup. The compositor may use this information to
	determine the future state the popup should be constrained using. If
	this doesn't match the dimension of the parent the popup is eventually
	positioned against, the behavior is undefined.

	The arguments are given in the surface-local coordinate space.
      </description>
      <arg name="parent_width" type="int"
	   summary="future window geometry width of parent"/>
      <arg name="parent_height" type="int"
	   summary="future window geometry height of parent"/>
    </request>

    <request name="set_parent_configure" since="3">
      <description summary="set parent configure this is a response to">
	Set the serial of an xdg_surface.configure event this positioner will be
	used in response to. The compositor may use this information together
	with set_parent_size to determine what future state the popup should be
	constrained using.
      </description>
      <arg name="serial" type="uint"
	   summary="serial of parent configure event"/>
    </request>
  </interface>

  <interface name="xdg_surface" version="3">
    <description summary="desktop user interface surface base interface">
      An interface that may be implemented by a wl_surface, for
      implementations that provide a desktop-style user interface.

      It provides a base set of functionality required to construct user
      interface elements requiring management by the compositor, such as
      toplevel windows, menus, etc. The types of functionality are split into
      xdg_surface roles.

      Creating an xdg_surface does not set the role for a wl_surface. In order
      to map an xdg_surface, the client must create a role-specific object
      using, e.g., get_toplevel, get_popup. The wl_surface for any given
      xdg_surface can have at most one role, and may not be assigned any role
      not based on xdg_surface.

      A role must be assigned before any other requests are made to the
      xdg_surface object.

      The client must call wl_surface.commit on the corresponding wl_surface
      for the xdg_surface state to take effect.

      Creating an xdg_surface from a wl_surface which has a buffer attached or
      committed is a client error, and any attempts by a client to attach or
      manipulate a buffer prior to the first xdg_surface.configure call must
      also be treated as errors.

      After creating a role-specific object and setting it up, the client must
      perform an initial commit without any buffer attached. The compositor
      will reply with an xdg_surface.configure event. The client must
      acknowledge it and is then allowed to attach a buffer to map the surface.

      Mapping an xdg_surface-based role surface is defined as making it
      possible for the surface to be shown by the compositor. Note that
      a mapped surface is not guaranteed to be visible once it is mapped.

      For an xdg_surface to be mapped by the compositor, the following
      conditions must be met:
      (1) the client has assigned an xdg_surface-based role to the surface
      (2) the client has set and committed the xdg_surface state and the
	  role-dependent state to the surface
      (3) the client has committed a buffer to the surface

      A newly-unmapped surface is considered to have met condition (1) out
      of the 3 required conditions for mapping a surface if its role surface
      has not been destroyed.
    </description>

    <enum name="error">
      <entry name="not_constructed" value="1"/>
      <entry name="already_constructed" value="2"/>
      <entry name="unconfigured_buffer" value="3"/>
    </enum>

    <request name="destroy" type="destructor">
      <description summary="destroy the xdg_surface">
	Destroy the xdg_surface object. An xdg_surface must only be destroyed
	after its role object has been destroyed.
      </description>
    </request>

    <request name="get_toplevel">
      <description summary="assign the xdg_toplevel surface role">
	This creates an xdg_toplevel object for the given xdg_surface and gives
	the associated wl_surface the xdg_toplevel role.

	See the documentation of xdg_toplevel for more details about what an
	xdg_toplevel is and how it is used.
      </description>
      <arg name="id" type="new_id" interface="xdg_toplevel"/>
    </request>

    <request name="get_popup">
      <description summary="assign the xdg_popup surface role">
	This creates an xdg_popup object for the given xdg_surface and gives
	the associated wl_surface the xdg_popup role.

	If null is passed as a parent, a parent surface must be specified using
	some other protocol, before committing the initial state.

	See the documentation of xdg_popup for more details about what an
	xdg_popup is and how it is used.
      </description>
      <arg name="id" type="new_id" interface="xdg_popup"/>
      <arg name="parent" type="object" interface="xdg_surface" allow-null="true"/>
      <arg name="positioner" type="object" interface="xdg_positioner"/>
    </request>

    <request name="set_window_geometry">
      <description summary="set the new window geometry">
	The window geometry of a surface is its "visible bounds" from the
	user's perspective. Client-side decorations often have invisible
	portions like drop-shadows which should be ignored for the
	purposes of aligning, placing and constraining windows.

	The window geometry is double buffered, and will be applied at the
	time wl_surface.commit of the corresponding wl_surface is called.

	When maintaining a position, the compositor should treat the (x, y)
	coordinate of the window geometry as the top left corner of the window.
	A client changing the (x, y) window geometry coordinate should in
	general not alter the position of the window.

	Once the window geometry of the surface is set, it is not possible to
	unset it, and it will remain the same until set_window_geometry is
	called again, even if a new subsurface or buffer is attached.

	If never set, the value is the full bounds of the surface,
	including any subsurfaces. This updates dynamically on every
	commit. This unset is meant for extremely simple clients.

	The arguments are given in the surface-local coordinate space of
	the wl_surface associated with this xdg_surface.

	The width and height must be greater than zero. Setting an invalid size
	will raise an error. When applied, the effective window geometry will be
	the set window geometry clamped to the bounding rectangle of the
	combined geometry of the surface of the xdg_surface and the associated
	subsurfaces.
      </description>
      <arg name="x" type="int"/>
      <arg name="y" type="int"/>
      <arg name="width" type="int"/>
      <arg name="height" type="int"/>
    </request>

    <request name="ack_configure">
      <description summary="ack a configure event">
	When a configure event is received, if a client commits the
	surface in response to the configure event, then the client
	must make an ack_configure request sometime before the commit
	request, passing along the serial of the configure event.

	For instance, for toplevel surfaces the compositor might use this
	information to move a surface to the top left only when the client has
	drawn itself for the maximized or fullscreen state.

	If the client receives multiple configure events before it
	can respond to one, it only has to ack the last configure event.

	A client is not required to commit immediately after sending
	an ack_configure request - it may even ack_configure several times
	before its next surface commit.

	A client may send multiple ack_configure requests before committing, but
	only the last request sent before a commit indicates which configure
	event the client really is responding to.
      </description>
      <arg name="serial" type="uint" summary="the serial from the configure event"/>
    </request>

    <event name="configure">
      <description summary="suggest a surface change">
	The configure event marks the end of a configure sequence. A configure
	sequence is a set of one or more events configuring the state of the
	xdg_surface, including the final xdg_surface.configure event.

	Where applicable, xdg_surface surface roles will during a configure
	sequence extend this event as a latched state sent as events before the
	xdg_surface.configure event. Such events should be considered to make up
	a set of atomically applied configuration states, where the
	xdg_surface.configure commits the accumulated state.

	Clients should arrange their surface for the new states, and then send
	an ack_configure request with the serial sent in this configure event at
	some point before committing the new surface.

	If the client receives multiple configure events before it can respond
	to one, it is free to discard all but the last event it received.
      </description>
      <arg name="serial" type="uint" summary="serial of the configure event"/>
    </event>

  </interface>

  <interface name="xdg_toplevel" version="3">
    <description summary="toplevel surface">
      This interface defines an xdg_surface role which allows a surface to,
      among other things, set window-like properties such as maximize,
      fullscreen, and minimize, set application-specific metadata like title and
      id, and well as trigger user interactive operations such as interactive
      resize and move.

      Unmapping an xdg_toplevel means that the surface cannot be shown
      by the compositor until it is explicitly mapped again.
      All active operations (e.g., move, resize) are canceled and all
      attributes (e.g. title, state, stacking, ...) are discarded for
      an xdg_toplevel surface when it is unmapped. The xdg_toplevel returns to
      the state it had right after xdg_surface.get_toplevel. The client
      can re-map the toplevel by perfoming a commit without any buffer
      attached, waiting for a configure event and handling it as usual (see
      xdg_surface description).

      Attaching a null buffer to a toplevel unmaps the surface.
    </description>

    <request name="destroy" type="destructor">
      <description summary="destroy the xdg_toplevel">
	This request destroys the role surface and unmaps the surface;
	see "Unmapping" behavior in interface section for details.
      </description>
    </request>

    <request name="set_parent">
      <description summary="set the parent of this surface">
	Set the "parent" of this surface. This surface should be stacked
	above the parent surface and all other ancestor surfaces.

	Parent windows should be set on dialogs, toolboxes, or other
	"auxiliary" surfaces, so that the parent is raised when the dialog
	is raised.

	Setting a null parent for a child window removes any parent-child
	relationship for the child. Setting a null parent for a window which
	currently has no parent is a no-op.

	If the parent is unmapped then its children are managed as
	though the parent of the now-unmapped parent has become the
	parent of this surface. If no parent exists for the now-unmapped
	parent then the children are managed as though they have no
	parent surface.
      </description>
      <arg name="parent" type="object" interface="xdg_toplevel" allow-null="true"/>
    </request>

    <request name="set_title">
      <description summary="set surface title">
	Set a short title for the surface.

	This string may be used to identify the surface in a task bar,
	window list, or other user interface elements provided by the
	compositor.

	The string must be encoded in UTF-8.
      </description>
      <arg name="title" type="string"/>
    </request>

    <request name="set_app_id">
      <description summary="set application ID">
	Set an application identifier for the surface.

	The app ID identifies the general class of applications to which
	the surface belongs. The compositor can use this to group multiple
	surfaces together, or to determine how to launch a new application.

	For D-Bus activatable applications, the app ID is used as the D-Bus
	service name.

	The compositor shell will try to group application surfaces together
	by their app ID. As a best practice, it is suggested to select app
	ID's that match the basename of the application's .desktop file.
	For example, "org.freedesktop.FooViewer" where the .desktop file is
	"org.freedesktop.FooViewer.desktop".

	Like other properties, a set_app_id request can be sent after the
	xdg_toplevel has been mapped to update the property.

	See the desktop-entry specification [0] for more details on
	application identifiers and how they relate to well-known D-Bus
	names and .desktop files.

	[0] http://standards.freedesktop.org/desktop-entry-spec/
      </description>
      <arg name="app_id" type="string"/>
    </request>

    <request name="show_window_menu">
      <description summary="show the window menu">
	Clients implementing client-side decorations might want to show
	a context menu when right-clicking on the decorations, giving the
	user a menu that they can use to maximize or minimize the window.

	This request asks the compositor to pop up such a window menu at
	the given position, relative to the local surface coordinates of
	the parent surface. There are no guarantees as to what menu items
	the window menu contains.

	This request must be used in response to some sort of user action
	like a button press, key press, or touch down event.
      </description>
      <arg name="seat" type="object" interface="wl_seat" summary="the wl_seat of the user event"/>
      <arg name="serial" type="uint" summary="the serial of the user event"/>
      <arg name="x" type="int" summary="the x position to pop up the window menu at"/>
      <arg name="y" type="int" summary="the y position to pop up the window menu at"/>
    </request>

    <request name="move">
      <description summary="start an interactive move">
	Start an interactive, user-driven move of the surface.

	This request must be used in response to some sort of user action
	like a button press, key press, or touch down event. The passed
	serial is used to determine the type of interactive move (touch,
	pointer, etc).

	The server may ignore move requests depending on the state of
	the surface (e.g. fullscreen or maximized), or if the passed serial
	is no longer valid.

	If triggered, the surface will lose the focus of the device
	(wl_pointer, wl_touch, etc) used for the move. It is up to the
	compositor to visually indicate that the move is taking place, such as
	updating a pointer cursor, during the move. There is no guarantee
	that the device focus will return when the move is completed.
      </description>
      <arg name="seat" type="object" interface="wl_seat" summary="the wl_seat of the user event"/>
      <arg name="serial" type="uint" summary="the serial of the user event"/>
    </request>

    <enum name="resize_edge">
      <description summary="edge values for resizing">
	These values are used to indicate which edge of a surface
	is being dragged in a resize operation.
      </description>
      <entry name="none" value="0"/>
      <entry name="top" value="1"/>
      <entry name="bottom" value="2"/>
      <entry name="left" value="4"/>
      <entry name="top_left" value="5"/>
      <entry name="bottom_left" value="6"/>
      <entry name="right" value="8"/>
      <entry name="top_right" value="9"/>
      <entry name="bottom_right" value="10"/>
    </enum>

    <request name="resize">
      <description summary="start an interactive resize">
	Start a user-driven, interactive resize of the surface.

	This request must be used in response to some sort of user action
	like a button press, key press, or touch down event. The passed
	serial is used to determine the type of interactive resize (touch,
	pointer, etc).

	The server may ignore resize requests depending on the state of
	the surface (e.g. fullscreen or maximized).

	If triggered, the client will receive configure events with the
	"resize" state enum value and the expected sizes. See the "resize"
	enum value for more details about what is required. The client
	must also acknowledge configure events using "ack_configure". After
	the resize is completed, the client will receive another "configure"
	event without the resize state.

	If triggered, the surface also will lose the focus of the device
	(wl_pointer, wl_touch, etc) used for the resize. It is up to the
	compositor to visually indicate that the resize is taking place,
	such as updating a pointer cursor, during the resize. There is no
	guarantee that the device focus will return when the resize is
	completed.

	The edges parameter specifies how the surface should be resized,
	and is one of the values of the resize_edge enum. The compositor
	may use this information to update the surface position for
	example when dragging the top left corner. The compositor may also
	use this information to adapt its behavior, e.g. choose an
	appropriate cursor image.
      </description>
      <arg name="seat" type="object" interface="wl_seat" summary="the wl_seat of the user event"/>
      <arg name="serial" type="uint" summary="the serial of the user event"/>
      <arg name="edges" type="uint" enum="resize_edge" summary="which edge or corner is being dragged"/>
    </request>

    <enum name="state">
      <description summary="types of state on the surface">
	The different state values used on the surface. This is designed for
	state values like maximized, fullscreen. It is paired with the
	configure event to ensure that both the client and the compositor
	setting the state can be synchronized.

	States set in this way are double-buffered. They will get applied on
	the next commit.
      </description>
      <entry name="maximized" value="1" summary="the surface is maximized">
	<description summary="the surface is maximized">
	  The surface is maximized. The window geometry specified in the configure
	  event must be obeyed by the client.

	  The client should draw without shadow or other
	  decoration outside of the window geometry.
	</description>
      </entry>
      <entry name="fullscreen" value="2" summary="the surface is fullscreen">
	<description summary="the surface is fullscreen">
	  The surface is fullscreen. The window geometry specified in the
	  configure event is a maximum; the client cannot resize beyond it. For
	  a surface to cover the whole fullscreened area, the geometry
	  dimensions must be obeyed by the client. For more details, see
	  xdg_toplevel.set_fullscreen.
	</description>
      </entry>
      <entry name="resizing" value="3" summary="the surface is being resized">
	<description summary="the surface is being resized">
	  The surface is being resized. The window geometry specified in the
	  configure event is a maximum; the client cannot resize beyond it.
	  Clients that have aspect ratio or cell sizing configuration can use
	  a smaller size, however.
	</description>
      </entry>
      <entry name="activated" value="4" summary="the surface is now activated">
	<description summary="the surface is now activated">
	  Client window decorations should be painted as if the window is
	  active. Do not assume this means that the window actually has
	  keyboard or pointer focus.
	</description>
      </entry>
      <entry name="tiled_left" value="5" since="2">
	<description summary="the surface is tiled">
	  The window is currently in a tiled layout and the left edge is
	  considered to be adjacent to another part of the tiling grid.
	</description>
      </entry>
      <entry name="tiled_right" value="6" since="2">
	<description summary="the surface is tiled">
	  The window is currently in a tiled layout and the right edge is
	  considered to be adjacent to another part of the tiling grid.
	</description>
      </entry>
      <entry name="tiled_top" value="7" since="2">
	<description summary="the surface is tiled">
	  The window is currently in a tiled layout and the top edge is
	  considered to be adjacent to another part of the tiling grid.
	</description>
      </entry>
      <entry name="tiled_bottom" value="8" since="2">
	<description summary="the surface is tiled">
	  The window is currently in a tiled layout and the bottom edge is
	  considered to be adjacent to another part of the tiling grid.
	</description>
      </entry>
    </enum>

    <request name="set_max_size">
      <description summary="set the maximum size">
	Set a maximum size for the window.

	The client can specify a maximum size so that the compositor does
	not try to configure the window beyond this size.

	The width and height arguments are in window geometry coordinates.
	See xdg_surface.set_window_geometry.

	Values set in this way are double-buffered. They will get applied
	on the next commit.

	The compositor can use this information to allow or disallow
	different states like maximize or fullscreen and draw accurate
	animations.

	Similarly, a tiling window manager may use this information to
	place and resize client windows in a more effective way.

	The client should not rely on the compositor to obey the maximum
	size. The compositor may decide to ignore the values set by the
	client and request a larger size.

	If never set, or a value of zero in the request, means that the
	client has no expected maximum size in the given dimension.
	As a result, a client wishing to reset the maximum size
	to an unspecified state can use zero for width and height in the
	request.

	Requesting a maximum size to be smaller than the minimum size of
	a surface is illegal and will result in a protocol error.

	The width and height must be greater than or equal to zero. Using
	strictly negative values for width and height will result in a
	protocol error.
      </description>
      <arg name="width" type="int"/>
      <arg name="height" type="int"/>
    </request>

    <request name="set_min_size">
      <description summary="set the minimum size">
	Set a minimum size for the window.

	The client can specify a minimum size so that the compositor does
	not try to configure the window below this size.

	The width and height arguments are in window geometry coordinates.
	See xdg_surface.set_window_geometry.

	Values set in this way are double-buffered. They will get applied
	on the next commit.

	The compositor can use this information to allow or disallow
	different states like maximize or fullscreen and draw accurate
	animations.

	Similarly, a tiling window manager may use this information to
	place and resize client windows in a more effective way.

	The client should not rely on the compositor to obey the minimum
	size. The compositor may decide to ignore the values set by the
	client and request a smaller size.

	If never set, or a value of zero in the request, means that the
	client has no expected minimum size in the given dimension.
	As a result, a client wishing to reset the minimum size
	to an unspecified state can use zero for width and height in the
	request.

	Requesting a minimum size to be larger than the maximum size of
	a surface is illegal and will result in a protocol error.

	The width and height must be greater than or equal to zero. Using
	strictly negative values for width and height will result in a
	protocol error.
      </description>
      <arg name="width" type="int"/>
      <arg name="height" type="int"/>
    </request>

    <request name="set_maximized">
      <description summary="maximize the window">
	Maximize the surface.

	After requesting that the surface should be maximized, the compositor
	will respond by emitting a configure event. Whether this configure
	actually sets the window maximized is subject to compositor policies.
	The client must then update its content, drawing in the configured
	state. The client must also acknowledge the configure when committing
	the new content (see ack_configure).

	It is up to the compositor to decide how and where to maximize the
	surface, for example which output and what region of the screen should
	be used.

	If the surface was already maximized, the compositor will still emit
	a configure event with the "maximized" state.

	If the surface is in a fullscreen state, this request has no direct
	effect. It may alter the state the surface is returned to when
	unmaximized unless overridden by the compositor.
      </description>
    </request>

    <request name="unset_maximized">
      <description summary="unmaximize the window">
	Unmaximize the surface.

	After requesting that the surface should be unmaximized, the compositor
	will respond by emitting a configure event. Whether this actually
	un-maximizes the window is subject to compositor policies.
	If available and applicable, the compositor will include the window
	geometry dimensions the window had prior to being maximized in the
	configure event. The client must then update its content, drawing it in
	the configured state. The client must also acknowledge the configure
	when committing the new content (see ack_configure).

	It is up to the compositor to position the surface after it was
	unmaximized; usually the position the surface had before maximizing, if
	applicable.

	If the surface was already not maximized, the compositor will still
	emit a configure event without the "maximized" state.

	If the surface is in a fullscreen state, this request has no direct
	effect. It may alter the state the surface is returned to when
	unmaximized unless overridden by the compositor.
      </description>
    </request>

    <request name="set_fullscreen">
      <description summary="set the window as fullscreen on an output">
	Make the surface fullscreen.

	After requesting that the surface should be fullscreened, the
	compositor will respond by emitting a configure event. Whether the
	client is actually put into a fullscreen state is subject to compositor
	policies. The client must also acknowledge the configure when
	committing the new content (see ack_configure).

	The output passed by the request indicates the client's preference as
	to which display it should be set fullscreen on. If this value is NULL,
	it's up to the compositor to choose which display will be used to map
	this surface.

	If the surface doesn't cover the whole output, the compositor will
	position the surface in the center of the output and compensate with
	with border fill covering the rest of the output. The content of the
	border fill is undefined, but should be assumed to be in some way that
	attempts to blend into the surrounding area (e.g. solid black).

	If the fullscreened surface is not opaque, the compositor must make
	sure that other screen content not part of the same surface tree (made
	up of subsurfaces, popups or similarly coupled surfaces) are not
	visible below the fullscreened surface.
      </description>
      <arg name="output" type="object" interface="wl_output" allow-null="true"/>
    </request>

    <request name="unset_fullscreen">
      <description summary="unset the window as fullscreen">
	Make the surface no longer fullscreen.

	After requesting that the surface should be unfullscreened, the
	compositor will respond by emitting a configure event.
	Whether this actually removes the fullscreen state of the client is
	subject to compositor policies.

	Making a surface unfullscreen sets states for the surface based on the following:
	* the state(s) it may have had before becoming fullscreen
	* any state(s) decided by the compositor
	* any state(s) requested by the client while the surface was fullscreen

	The compositor may include the previous window geometry dimensions in
	the configure event, if applicable.

	The client must also acknowledge the configure when committing the new
	content (see ack_configure).
      </description>
    </request>

    <request name="set_minimized">
      <description summary="set the window as minimized">
	Request that the compositor minimize your surface. There is no
	way to know if the surface is currently minimized, nor is there
	any way to unset minimization on this surface.

	If you are looking to throttle redrawing when minimized, please
	instead use the wl_surface.frame event for this, as this will
	also work with live previews on windows in Alt-Tab, Expose or
	similar compositor features.
      </description>
    </request>

    <event name="configure">
      <description summary="suggest a surface change">
	This configure event asks the client to resize its toplevel surface or
	to change its state. The configured state should not be applied
	immediately. See xdg_surface.configure for details.

	The width and height arguments specify a hint to the window
	about how its surface should be resized in window geometry
	coordinates. See set_window_geometry.

	If the width or height arguments are zero, it means the client
	should decide its own window dimension. This may happen when the
	compositor needs to configure the state of the surface but doesn't
	have any information about any previous or expected dimension.

	The states listed in the event specify how the width/height
	arguments should be interpreted, and possibly how it should be
	drawn.

	Clients must send an ack_configure in response to this event. See
	xdg_surface.configure and xdg_surface.ack_configure for details.
      </description>
      <arg name="width" type="int"/>
      <arg name="height" type="int"/>
      <arg name="states" type="array"/>
    </event>

    <event name="close">
      <description summary="surface wants to be closed">
	The close event is sent by the compositor when the user
	wants the surface to be closed. This should be equivalent to
	the user clicking the close button in client-side decorations,
	if your application has any.

	This is only a request that the user intends to close the
	window. The client may choose to ignore this request, or show
	a dialog to ask the user to save their data, etc.
      </description>
    </event>
  </interface>

  <interface name="xdg_popup" version="3">
    <description summary="short-lived, popup surfaces for menus">
      A popup surface is a short-lived, temporary surface. It can be used to
      implement for example menus, popovers, tooltips and other similar user
      interface concepts.

      A popup can be made to take an explicit grab. See xdg_popup.grab for
      details.

      When the popup is dismissed, a popup_done event will be sent out, and at
      the same time the surface will be unmapped. See the xdg_popup.popup_done
      event for details.

      Explicitly destroying the xdg_popup object will also dismiss the popup and
      unmap the surface. Clients that want to dismiss the popup when another
      surface of their own is clicked should dismiss the popup using the destroy
      request.

      A newly created xdg_popup will be stacked on top of all previously created
      xdg_popup surfaces associated with the same xdg_toplevel.

      The parent of an xdg_popup must be mapped (see the xdg_surface
      description) before the xdg_popup itself.

      The client must call wl_surface.commit on the corresponding wl_surface
      for the xdg_popup state to take effect.
    </description>

    <enum name="error">
      <entry name="invalid_grab" value="0"
	     summary="tried to grab after being mapped"/>
    </enum>

    <request name="destroy" type="destructor">
      <description summary="remove xdg_popup interface">
	This destroys the popup. Explicitly destroying the xdg_popup
	object will also dismiss the popup, and unmap the surface.

	If this xdg_popup is not the "topmost" popup, a protocol error
	will be sent.
      </description>
    </request>

    <request name="grab">
      <description summary="make the popup take an explicit grab">
	This request makes the created popup take an explicit grab. An explicit
	grab will be dismissed when the user dismisses the popup, or when the
	client destroys the xdg_popup. This can be done by the user clicking
	outside the surface, using the keyboard, or even locking the screen
	through closing the lid or a timeout.

	If the compositor denies the grab, the popup will be immediately
	dismissed.

	This request must be used in response to some sort of user action like a
	button press, key press, or touch down event. The serial number of the
	event should be passed as 'serial'.

	The parent of a grabbing popup must either be an xdg_toplevel surface or
	another xdg_popup with an explicit grab. If the parent is another
	xdg_popup it means that the popups are nested, with this popup now being
	the topmost popup.

	Nested popups must be destroyed in the reverse order they were created
	in, e.g. the only popup you are allowed to destroy at all times is the
	topmost one.

	When compositors choose to dismiss a popup, they may dismiss every
	nested grabbing popup as well. When a compositor dismisses popups, it
	will follow the same dismissing order as required from the client.

	The parent of a grabbing popup must either be another xdg_popup with an
	active explicit grab, or an xdg_popup or xdg_toplevel, if there are no
	explicit grabs already taken.

	If the topmost grabbing popup is destroyed, the grab will be returned to
	the parent of the popup, if that parent previously had an explicit grab.

	If the parent is a grabbing popup which has already been dismissed, this
	popup will be immediately dismissed. If the parent is a popup that did
	not take an explicit grab, an error will be raised.

	During a popup grab, the client owning the grab will receive pointer
	and touch events for all their surfaces as normal (similar to an
	"owner-events" grab in X11 parlance), while the top most grabbing popup
	will always have keyboard focus.
      </description>
      <arg name="seat" type="object" interface="wl_seat"
	   summary="the wl_seat of the user event"/>
      <arg name="serial" type="uint" summary="the serial of the user event"/>
    </request>

    <event name="configure">
      <description summary="configure the popup surface">
	This event asks the popup surface to configure itself given the
	configuration. The configured state should not be applied immediately.
	See xdg_surface.configure for details.

	The x and y arguments represent the position the popup was placed at
	given the xdg_positioner rule, relative to the upper left corner of the
	window geometry of the parent surface.

	For version 2 or older, the configure event for an xdg_popup is only
	ever sent once for the initial configuration. Starting with version 3,
	it may be sent again if the popup is setup with an xdg_positioner with
	set_reactive requested, or in response to xdg_popup.reposition requests.
      </description>
      <arg name="x" type="int"
	   summary="x position relative to parent surface window geometry"/>
      <arg name="y" type="int"
	   summary="y position relative to parent surface window geometry"/>
      <arg name="width" type="int" summary="window geometry width"/>
      <arg name="height" type="int" summary="window geometry height"/>
    </event>

    <event name="popup_done">
      <description summary="popup interaction is done">
	The popup_done event is sent out when a popup is dismissed by the
	compositor. The client should destroy the xdg_popup object at this
	point.
      </description>
    </event>

    <!-- Version 3 additions -->

    <request name="reposition" since="3">
      <description summary="recalculate the popup's location">
	Reposition an already-mapped popup. The popup will be placed given the
	details in the passed xdg_positioner object, and a
	xdg_popup.repositioned followed by xdg_popup.configure and
	xdg_surface.configure will be emitted in response. Any parameters set
	by the previous positioner will be discarded.

	The passed token will be sent in the corresponding
	xdg_popup.repositioned event. The new popup position will not take
	effect until the corresponding configure event is acknowledged by the
	client. See xdg_popup.repositioned for details. The token itself is
	opaque, and has no other special meaning.

	If multiple reposition requests are sent, the compositor may skip all
	but the last one.

	If the popup is repositioned in response to a configure event for its
	parent, the client should send an xdg_positioner.set_parent_configure
	and possibly an xdg_positioner.set_parent_size request to allow the
	compositor to properly constrain the popup.

	If the popup is repositioned together with a parent that is being
	resized, but not in response to a configure event, the client should
	send an xdg_positioner.set_parent_size request.
      </description>
      <arg name="positioner" type="object" interface="xdg_positioner"/>
      <arg name="token" type="uint" summary="reposition request token"/>
    </request>

    <event name="repositioned" since="3">
      <description summary="signal the completion of a repositioned request">
	The repositioned event is sent as part of a popup configuration
	sequence, together with xdg_popup.configure and lastly
	xdg_surface.configure to notify the completion of a reposition request.

	The repositioned event is to notify about the completion of a
	xdg_popup.reposition request. The token argument is the token passed
	in the xdg_popup.reposition request.

	Immediately after this event is emitted, xdg_popup.configure and
	xdg_surface.configure will be sent with the updated size and position,
	as well as a new configure serial.

	The client should optionally update the content of the popup, but must
	acknowledge the new popup configuration for the new position to take
	effect. See xdg_surface.ack_configure for details.
      </description>
      <arg name="token" type="uint" summary="reposition request token"/>
    </event>

  </interface>
</protocol>