/* Generated by wayland-scanner 1.14.0 */ #ifndef WAYLAND_CLIENT_PROTOCOL_H #define WAYLAND_CLIENT_PROTOCOL_H #include #include #include "wayland-client.h" #ifdef __cplusplus extern "C" { #endif /** * @page page_wayland The wayland protocol * @section page_ifaces_wayland Interfaces * - @subpage page_iface_wl_display - core global object * - @subpage page_iface_wl_registry - global registry object * - @subpage page_iface_wl_callback - callback object * - @subpage page_iface_wl_compositor - the compositor singleton * - @subpage page_iface_wl_shm_pool - a shared memory pool * - @subpage page_iface_wl_shm - shared memory support * - @subpage page_iface_wl_buffer - content for a wl_surface * - @subpage page_iface_wl_data_offer - offer to transfer data * - @subpage page_iface_wl_data_source - offer to transfer data * - @subpage page_iface_wl_data_device - data transfer device * - @subpage page_iface_wl_data_device_manager - data transfer interface * - @subpage page_iface_wl_shell - create desktop-style surfaces * - @subpage page_iface_wl_shell_surface - desktop-style metadata interface * - @subpage page_iface_wl_surface - an onscreen surface * - @subpage page_iface_wl_seat - group of input devices * - @subpage page_iface_wl_pointer - pointer input device * - @subpage page_iface_wl_keyboard - keyboard input device * - @subpage page_iface_wl_touch - touchscreen input device * - @subpage page_iface_wl_output - compositor output region * - @subpage page_iface_wl_region - region interface * - @subpage page_iface_wl_subcompositor - sub-surface compositing * - @subpage page_iface_wl_subsurface - sub-surface interface to a wl_surface * @section page_copyright_wayland Copyright *
 *
 * Copyright © 2008-2011 Kristian Høgsberg
 * Copyright © 2010-2011 Intel Corporation
 * Copyright © 2012-2013 Collabora, Ltd.
 *
 * 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.
 * 
*/ struct wl_buffer; struct wl_callback; struct wl_compositor; struct wl_data_device; struct wl_data_device_manager; struct wl_data_offer; struct wl_data_source; struct wl_display; struct wl_keyboard; struct wl_output; struct wl_pointer; struct wl_region; struct wl_registry; struct wl_seat; struct wl_shell; struct wl_shell_surface; struct wl_shm; struct wl_shm_pool; struct wl_subcompositor; struct wl_subsurface; struct wl_surface; struct wl_touch; /** * @page page_iface_wl_display wl_display * @section page_iface_wl_display_desc Description * * The core global object. This is a special singleton object. It * is used for internal Wayland protocol features. * @section page_iface_wl_display_api API * See @ref iface_wl_display. */ /** * @defgroup iface_wl_display The wl_display interface * * The core global object. This is a special singleton object. It * is used for internal Wayland protocol features. */ extern const struct wl_interface wl_display_interface; /** * @page page_iface_wl_registry wl_registry * @section page_iface_wl_registry_desc Description * * The singleton global registry object. The server has a number of * global objects that are available to all clients. These objects * typically represent an actual object in the server (for example, * an input device) or they are singleton objects that provide * extension functionality. * * When a client creates a registry object, the registry object * will emit a global event for each global currently in the * registry. Globals come and go as a result of device or * monitor hotplugs, reconfiguration or other events, and the * registry will send out global and global_remove events to * keep the client up to date with the changes. To mark the end * of the initial burst of events, the client can use the * wl_display.sync request immediately after calling * wl_display.get_registry. * * A client can bind to a global object by using the bind * request. This creates a client-side handle that lets the object * emit events to the client and lets the client invoke requests on * the object. * @section page_iface_wl_registry_api API * See @ref iface_wl_registry. */ /** * @defgroup iface_wl_registry The wl_registry interface * * The singleton global registry object. The server has a number of * global objects that are available to all clients. These objects * typically represent an actual object in the server (for example, * an input device) or they are singleton objects that provide * extension functionality. * * When a client creates a registry object, the registry object * will emit a global event for each global currently in the * registry. Globals come and go as a result of device or * monitor hotplugs, reconfiguration or other events, and the * registry will send out global and global_remove events to * keep the client up to date with the changes. To mark the end * of the initial burst of events, the client can use the * wl_display.sync request immediately after calling * wl_display.get_registry. * * A client can bind to a global object by using the bind * request. This creates a client-side handle that lets the object * emit events to the client and lets the client invoke requests on * the object. */ extern const struct wl_interface wl_registry_interface; /** * @page page_iface_wl_callback wl_callback * @section page_iface_wl_callback_desc Description * * Clients can handle the 'done' event to get notified when * the related request is done. * @section page_iface_wl_callback_api API * See @ref iface_wl_callback. */ /** * @defgroup iface_wl_callback The wl_callback interface * * Clients can handle the 'done' event to get notified when * the related request is done. */ extern const struct wl_interface wl_callback_interface; /** * @page page_iface_wl_compositor wl_compositor * @section page_iface_wl_compositor_desc Description * * A compositor. This object is a singleton global. The * compositor is in charge of combining the contents of multiple * surfaces into one displayable output. * @section page_iface_wl_compositor_api API * See @ref iface_wl_compositor. */ /** * @defgroup iface_wl_compositor The wl_compositor interface * * A compositor. This object is a singleton global. The * compositor is in charge of combining the contents of multiple * surfaces into one displayable output. */ extern const struct wl_interface wl_compositor_interface; /** * @page page_iface_wl_shm_pool wl_shm_pool * @section page_iface_wl_shm_pool_desc Description * * The wl_shm_pool object encapsulates a piece of memory shared * between the compositor and client. Through the wl_shm_pool * object, the client can allocate shared memory wl_buffer objects. * All objects created through the same pool share the same * underlying mapped memory. Reusing the mapped memory avoids the * setup/teardown overhead and is useful when interactively resizing * a surface or for many small buffers. * @section page_iface_wl_shm_pool_api API * See @ref iface_wl_shm_pool. */ /** * @defgroup iface_wl_shm_pool The wl_shm_pool interface * * The wl_shm_pool object encapsulates a piece of memory shared * between the compositor and client. Through the wl_shm_pool * object, the client can allocate shared memory wl_buffer objects. * All objects created through the same pool share the same * underlying mapped memory. Reusing the mapped memory avoids the * setup/teardown overhead and is useful when interactively resizing * a surface or for many small buffers. */ extern const struct wl_interface wl_shm_pool_interface; /** * @page page_iface_wl_shm wl_shm * @section page_iface_wl_shm_desc Description * * A singleton global object that provides support for shared * memory. * * Clients can create wl_shm_pool objects using the create_pool * request. * * At connection setup time, the wl_shm object emits one or more * format events to inform clients about the valid pixel formats * that can be used for buffers. * @section page_iface_wl_shm_api API * See @ref iface_wl_shm. */ /** * @defgroup iface_wl_shm The wl_shm interface * * A singleton global object that provides support for shared * memory. * * Clients can create wl_shm_pool objects using the create_pool * request. * * At connection setup time, the wl_shm object emits one or more * format events to inform clients about the valid pixel formats * that can be used for buffers. */ extern const struct wl_interface wl_shm_interface; /** * @page page_iface_wl_buffer wl_buffer * @section page_iface_wl_buffer_desc Description * * A buffer provides the content for a wl_surface. Buffers are * created through factory interfaces such as wl_drm, wl_shm or * similar. It has a width and a height and can be attached to a * wl_surface, but the mechanism by which a client provides and * updates the contents is defined by the buffer factory interface. * @section page_iface_wl_buffer_api API * See @ref iface_wl_buffer. */ /** * @defgroup iface_wl_buffer The wl_buffer interface * * A buffer provides the content for a wl_surface. Buffers are * created through factory interfaces such as wl_drm, wl_shm or * similar. It has a width and a height and can be attached to a * wl_surface, but the mechanism by which a client provides and * updates the contents is defined by the buffer factory interface. */ extern const struct wl_interface wl_buffer_interface; /** * @page page_iface_wl_data_offer wl_data_offer * @section page_iface_wl_data_offer_desc Description * * A wl_data_offer represents a piece of data offered for transfer * by another client (the source client). It is used by the * copy-and-paste and drag-and-drop mechanisms. The offer * describes the different mime types that the data can be * converted to and provides the mechanism for transferring the * data directly from the source client. * @section page_iface_wl_data_offer_api API * See @ref iface_wl_data_offer. */ /** * @defgroup iface_wl_data_offer The wl_data_offer interface * * A wl_data_offer represents a piece of data offered for transfer * by another client (the source client). It is used by the * copy-and-paste and drag-and-drop mechanisms. The offer * describes the different mime types that the data can be * converted to and provides the mechanism for transferring the * data directly from the source client. */ extern const struct wl_interface wl_data_offer_interface; /** * @page page_iface_wl_data_source wl_data_source * @section page_iface_wl_data_source_desc Description * * The wl_data_source object is the source side of a wl_data_offer. * It is created by the source client in a data transfer and * provides a way to describe the offered data and a way to respond * to requests to transfer the data. * @section page_iface_wl_data_source_api API * See @ref iface_wl_data_source. */ /** * @defgroup iface_wl_data_source The wl_data_source interface * * The wl_data_source object is the source side of a wl_data_offer. * It is created by the source client in a data transfer and * provides a way to describe the offered data and a way to respond * to requests to transfer the data. */ extern const struct wl_interface wl_data_source_interface; /** * @page page_iface_wl_data_device wl_data_device * @section page_iface_wl_data_device_desc Description * * There is one wl_data_device per seat which can be obtained * from the global wl_data_device_manager singleton. * * A wl_data_device provides access to inter-client data transfer * mechanisms such as copy-and-paste and drag-and-drop. * @section page_iface_wl_data_device_api API * See @ref iface_wl_data_device. */ /** * @defgroup iface_wl_data_device The wl_data_device interface * * There is one wl_data_device per seat which can be obtained * from the global wl_data_device_manager singleton. * * A wl_data_device provides access to inter-client data transfer * mechanisms such as copy-and-paste and drag-and-drop. */ extern const struct wl_interface wl_data_device_interface; /** * @page page_iface_wl_data_device_manager wl_data_device_manager * @section page_iface_wl_data_device_manager_desc Description * * The wl_data_device_manager is a singleton global object that * provides access to inter-client data transfer mechanisms such as * copy-and-paste and drag-and-drop. These mechanisms are tied to * a wl_seat and this interface lets a client get a wl_data_device * corresponding to a wl_seat. * * Depending on the version bound, the objects created from the bound * wl_data_device_manager object will have different requirements for * functioning properly. See wl_data_source.set_actions, * wl_data_offer.accept and wl_data_offer.finish for details. * @section page_iface_wl_data_device_manager_api API * See @ref iface_wl_data_device_manager. */ /** * @defgroup iface_wl_data_device_manager The wl_data_device_manager interface * * The wl_data_device_manager is a singleton global object that * provides access to inter-client data transfer mechanisms such as * copy-and-paste and drag-and-drop. These mechanisms are tied to * a wl_seat and this interface lets a client get a wl_data_device * corresponding to a wl_seat. * * Depending on the version bound, the objects created from the bound * wl_data_device_manager object will have different requirements for * functioning properly. See wl_data_source.set_actions, * wl_data_offer.accept and wl_data_offer.finish for details. */ extern const struct wl_interface wl_data_device_manager_interface; /** * @page page_iface_wl_shell wl_shell * @section page_iface_wl_shell_desc Description * * This interface is implemented by servers that provide * desktop-style user interfaces. * * It allows clients to associate a wl_shell_surface with * a basic surface. * @section page_iface_wl_shell_api API * See @ref iface_wl_shell. */ /** * @defgroup iface_wl_shell The wl_shell interface * * This interface is implemented by servers that provide * desktop-style user interfaces. * * It allows clients to associate a wl_shell_surface with * a basic surface. */ extern const struct wl_interface wl_shell_interface; /** * @page page_iface_wl_shell_surface wl_shell_surface * @section page_iface_wl_shell_surface_desc Description * * An interface that may be implemented by a wl_surface, for * implementations that provide a desktop-style user interface. * * It provides requests to treat surfaces like toplevel, fullscreen * or popup windows, move, resize or maximize them, associate * metadata like title and class, etc. * * On the server side the object is automatically destroyed when * the related wl_surface is destroyed. On the client side, * wl_shell_surface_destroy() must be called before destroying * the wl_surface object. * @section page_iface_wl_shell_surface_api API * See @ref iface_wl_shell_surface. */ /** * @defgroup iface_wl_shell_surface The wl_shell_surface interface * * An interface that may be implemented by a wl_surface, for * implementations that provide a desktop-style user interface. * * It provides requests to treat surfaces like toplevel, fullscreen * or popup windows, move, resize or maximize them, associate * metadata like title and class, etc. * * On the server side the object is automatically destroyed when * the related wl_surface is destroyed. On the client side, * wl_shell_surface_destroy() must be called before destroying * the wl_surface object. */ extern const struct wl_interface wl_shell_surface_interface; /** * @page page_iface_wl_surface wl_surface * @section page_iface_wl_surface_desc Description * * A surface is a rectangular area that is displayed on the screen. * It has a location, size and pixel contents. * * The size of a surface (and relative positions on it) is described * in surface-local coordinates, which may differ from the buffer * coordinates of the pixel content, in case a buffer_transform * or a buffer_scale is used. * * A surface without a "role" is fairly useless: a compositor does * not know where, when or how to present it. The role is the * purpose of a wl_surface. Examples of roles are a cursor for a * pointer (as set by wl_pointer.set_cursor), a drag icon * (wl_data_device.start_drag), a sub-surface * (wl_subcompositor.get_subsurface), and a window as defined by a * shell protocol (e.g. wl_shell.get_shell_surface). * * A surface can have only one role at a time. Initially a * wl_surface does not have a role. Once a wl_surface is given a * role, it is set permanently for the whole lifetime of the * wl_surface object. Giving the current role again is allowed, * unless explicitly forbidden by the relevant interface * specification. * * Surface roles are given by requests in other interfaces such as * wl_pointer.set_cursor. The request should explicitly mention * that this request gives a role to a wl_surface. Often, this * request also creates a new protocol object that represents the * role and adds additional functionality to wl_surface. When a * client wants to destroy a wl_surface, they must destroy this 'role * object' before the wl_surface. * * Destroying the role object does not remove the role from the * wl_surface, but it may stop the wl_surface from "playing the role". * For instance, if a wl_subsurface object is destroyed, the wl_surface * it was created for will be unmapped and forget its position and * z-order. It is allowed to create a wl_subsurface for the same * wl_surface again, but it is not allowed to use the wl_surface as * a cursor (cursor is a different role than sub-surface, and role * switching is not allowed). * @section page_iface_wl_surface_api API * See @ref iface_wl_surface. */ /** * @defgroup iface_wl_surface The wl_surface interface * * A surface is a rectangular area that is displayed on the screen. * It has a location, size and pixel contents. * * The size of a surface (and relative positions on it) is described * in surface-local coordinates, which may differ from the buffer * coordinates of the pixel content, in case a buffer_transform * or a buffer_scale is used. * * A surface without a "role" is fairly useless: a compositor does * not know where, when or how to present it. The role is the * purpose of a wl_surface. Examples of roles are a cursor for a * pointer (as set by wl_pointer.set_cursor), a drag icon * (wl_data_device.start_drag), a sub-surface * (wl_subcompositor.get_subsurface), and a window as defined by a * shell protocol (e.g. wl_shell.get_shell_surface). * * A surface can have only one role at a time. Initially a * wl_surface does not have a role. Once a wl_surface is given a * role, it is set permanently for the whole lifetime of the * wl_surface object. Giving the current role again is allowed, * unless explicitly forbidden by the relevant interface * specification. * * Surface roles are given by requests in other interfaces such as * wl_pointer.set_cursor. The request should explicitly mention * that this request gives a role to a wl_surface. Often, this * request also creates a new protocol object that represents the * role and adds additional functionality to wl_surface. When a * client wants to destroy a wl_surface, they must destroy this 'role * object' before the wl_surface. * * Destroying the role object does not remove the role from the * wl_surface, but it may stop the wl_surface from "playing the role". * For instance, if a wl_subsurface object is destroyed, the wl_surface * it was created for will be unmapped and forget its position and * z-order. It is allowed to create a wl_subsurface for the same * wl_surface again, but it is not allowed to use the wl_surface as * a cursor (cursor is a different role than sub-surface, and role * switching is not allowed). */ extern const struct wl_interface wl_surface_interface; /** * @page page_iface_wl_seat wl_seat * @section page_iface_wl_seat_desc Description * * A seat is a group of keyboards, pointer and touch devices. This * object is published as a global during start up, or when such a * device is hot plugged. A seat typically has a pointer and * maintains a keyboard focus and a pointer focus. * @section page_iface_wl_seat_api API * See @ref iface_wl_seat. */ /** * @defgroup iface_wl_seat The wl_seat interface * * A seat is a group of keyboards, pointer and touch devices. This * object is published as a global during start up, or when such a * device is hot plugged. A seat typically has a pointer and * maintains a keyboard focus and a pointer focus. */ extern const struct wl_interface wl_seat_interface; /** * @page page_iface_wl_pointer wl_pointer * @section page_iface_wl_pointer_desc Description * * The wl_pointer interface represents one or more input devices, * such as mice, which control the pointer location and pointer_focus * of a seat. * * The wl_pointer interface generates motion, enter and leave * events for the surfaces that the pointer is located over, * and button and axis events for button presses, button releases * and scrolling. * @section page_iface_wl_pointer_api API * See @ref iface_wl_pointer. */ /** * @defgroup iface_wl_pointer The wl_pointer interface * * The wl_pointer interface represents one or more input devices, * such as mice, which control the pointer location and pointer_focus * of a seat. * * The wl_pointer interface generates motion, enter and leave * events for the surfaces that the pointer is located over, * and button and axis events for button presses, button releases * and scrolling. */ extern const struct wl_interface wl_pointer_interface; /** * @page page_iface_wl_keyboard wl_keyboard * @section page_iface_wl_keyboard_desc Description * * The wl_keyboard interface represents one or more keyboards * associated with a seat. * @section page_iface_wl_keyboard_api API * See @ref iface_wl_keyboard. */ /** * @defgroup iface_wl_keyboard The wl_keyboard interface * * The wl_keyboard interface represents one or more keyboards * associated with a seat. */ extern const struct wl_interface wl_keyboard_interface; /** * @page page_iface_wl_touch wl_touch * @section page_iface_wl_touch_desc Description * * The wl_touch interface represents a touchscreen * associated with a seat. * * Touch interactions can consist of one or more contacts. * For each contact, a series of events is generated, starting * with a down event, followed by zero or more motion events, * and ending with an up event. Events relating to the same * contact point can be identified by the ID of the sequence. * @section page_iface_wl_touch_api API * See @ref iface_wl_touch. */ /** * @defgroup iface_wl_touch The wl_touch interface * * The wl_touch interface represents a touchscreen * associated with a seat. * * Touch interactions can consist of one or more contacts. * For each contact, a series of events is generated, starting * with a down event, followed by zero or more motion events, * and ending with an up event. Events relating to the same * contact point can be identified by the ID of the sequence. */ extern const struct wl_interface wl_touch_interface; /** * @page page_iface_wl_output wl_output * @section page_iface_wl_output_desc Description * * An output describes part of the compositor geometry. The * compositor works in the 'compositor coordinate system' and an * output corresponds to a rectangular area in that space that is * actually visible. This typically corresponds to a monitor that * displays part of the compositor space. This object is published * as global during start up, or when a monitor is hotplugged. * @section page_iface_wl_output_api API * See @ref iface_wl_output. */ /** * @defgroup iface_wl_output The wl_output interface * * An output describes part of the compositor geometry. The * compositor works in the 'compositor coordinate system' and an * output corresponds to a rectangular area in that space that is * actually visible. This typically corresponds to a monitor that * displays part of the compositor space. This object is published * as global during start up, or when a monitor is hotplugged. */ extern const struct wl_interface wl_output_interface; /** * @page page_iface_wl_region wl_region * @section page_iface_wl_region_desc Description * * A region object describes an area. * * Region objects are used to describe the opaque and input * regions of a surface. * @section page_iface_wl_region_api API * See @ref iface_wl_region. */ /** * @defgroup iface_wl_region The wl_region interface * * A region object describes an area. * * Region objects are used to describe the opaque and input * regions of a surface. */ extern const struct wl_interface wl_region_interface; /** * @page page_iface_wl_subcompositor wl_subcompositor * @section page_iface_wl_subcompositor_desc Description * * The global interface exposing sub-surface compositing capabilities. * A wl_surface, that has sub-surfaces associated, is called the * parent surface. Sub-surfaces can be arbitrarily nested and create * a tree of sub-surfaces. * * The root surface in a tree of sub-surfaces is the main * surface. The main surface cannot be a sub-surface, because * sub-surfaces must always have a parent. * * A main surface with its sub-surfaces forms a (compound) window. * For window management purposes, this set of wl_surface objects is * to be considered as a single window, and it should also behave as * such. * * The aim of sub-surfaces is to offload some of the compositing work * within a window from clients to the compositor. A prime example is * a video player with decorations and video in separate wl_surface * objects. This should allow the compositor to pass YUV video buffer * processing to dedicated overlay hardware when possible. * @section page_iface_wl_subcompositor_api API * See @ref iface_wl_subcompositor. */ /** * @defgroup iface_wl_subcompositor The wl_subcompositor interface * * The global interface exposing sub-surface compositing capabilities. * A wl_surface, that has sub-surfaces associated, is called the * parent surface. Sub-surfaces can be arbitrarily nested and create * a tree of sub-surfaces. * * The root surface in a tree of sub-surfaces is the main * surface. The main surface cannot be a sub-surface, because * sub-surfaces must always have a parent. * * A main surface with its sub-surfaces forms a (compound) window. * For window management purposes, this set of wl_surface objects is * to be considered as a single window, and it should also behave as * such. * * The aim of sub-surfaces is to offload some of the compositing work * within a window from clients to the compositor. A prime example is * a video player with decorations and video in separate wl_surface * objects. This should allow the compositor to pass YUV video buffer * processing to dedicated overlay hardware when possible. */ extern const struct wl_interface wl_subcompositor_interface; /** * @page page_iface_wl_subsurface wl_subsurface * @section page_iface_wl_subsurface_desc Description * * An additional interface to a wl_surface object, which has been * made a sub-surface. A sub-surface has one parent surface. A * sub-surface's size and position are not limited to that of the parent. * Particularly, a sub-surface is not automatically clipped to its * parent's area. * * A sub-surface becomes mapped, when a non-NULL wl_buffer is applied * and the parent surface is mapped. The order of which one happens * first is irrelevant. A sub-surface is hidden if the parent becomes * hidden, or if a NULL wl_buffer is applied. These rules apply * recursively through the tree of surfaces. * * The behaviour of a wl_surface.commit request on a sub-surface * depends on the sub-surface's mode. The possible modes are * synchronized and desynchronized, see methods * wl_subsurface.set_sync and wl_subsurface.set_desync. Synchronized * mode caches the wl_surface state to be applied when the parent's * state gets applied, and desynchronized mode applies the pending * wl_surface state directly. A sub-surface is initially in the * synchronized mode. * * Sub-surfaces have also other kind of state, which is managed by * wl_subsurface requests, as opposed to wl_surface requests. This * state includes the sub-surface position relative to the parent * surface (wl_subsurface.set_position), and the stacking order of * the parent and its sub-surfaces (wl_subsurface.place_above and * .place_below). This state is applied when the parent surface's * wl_surface state is applied, regardless of the sub-surface's mode. * As the exception, set_sync and set_desync are effective immediately. * * The main surface can be thought to be always in desynchronized mode, * since it does not have a parent in the sub-surfaces sense. * * Even if a sub-surface is in desynchronized mode, it will behave as * in synchronized mode, if its parent surface behaves as in * synchronized mode. This rule is applied recursively throughout the * tree of surfaces. This means, that one can set a sub-surface into * synchronized mode, and then assume that all its child and grand-child * sub-surfaces are synchronized, too, without explicitly setting them. * * If the wl_surface associated with the wl_subsurface is destroyed, the * wl_subsurface object becomes inert. Note, that destroying either object * takes effect immediately. If you need to synchronize the removal * of a sub-surface to the parent surface update, unmap the sub-surface * first by attaching a NULL wl_buffer, update parent, and then destroy * the sub-surface. * * If the parent wl_surface object is destroyed, the sub-surface is * unmapped. * @section page_iface_wl_subsurface_api API * See @ref iface_wl_subsurface. */ /** * @defgroup iface_wl_subsurface The wl_subsurface interface * * An additional interface to a wl_surface object, which has been * made a sub-surface. A sub-surface has one parent surface. A * sub-surface's size and position are not limited to that of the parent. * Particularly, a sub-surface is not automatically clipped to its * parent's area. * * A sub-surface becomes mapped, when a non-NULL wl_buffer is applied * and the parent surface is mapped. The order of which one happens * first is irrelevant. A sub-surface is hidden if the parent becomes * hidden, or if a NULL wl_buffer is applied. These rules apply * recursively through the tree of surfaces. * * The behaviour of a wl_surface.commit request on a sub-surface * depends on the sub-surface's mode. The possible modes are * synchronized and desynchronized, see methods * wl_subsurface.set_sync and wl_subsurface.set_desync. Synchronized * mode caches the wl_surface state to be applied when the parent's * state gets applied, and desynchronized mode applies the pending * wl_surface state directly. A sub-surface is initially in the * synchronized mode. * * Sub-surfaces have also other kind of state, which is managed by * wl_subsurface requests, as opposed to wl_surface requests. This * state includes the sub-surface position relative to the parent * surface (wl_subsurface.set_position), and the stacking order of * the parent and its sub-surfaces (wl_subsurface.place_above and * .place_below). This state is applied when the parent surface's * wl_surface state is applied, regardless of the sub-surface's mode. * As the exception, set_sync and set_desync are effective immediately. * * The main surface can be thought to be always in desynchronized mode, * since it does not have a parent in the sub-surfaces sense. * * Even if a sub-surface is in desynchronized mode, it will behave as * in synchronized mode, if its parent surface behaves as in * synchronized mode. This rule is applied recursively throughout the * tree of surfaces. This means, that one can set a sub-surface into * synchronized mode, and then assume that all its child and grand-child * sub-surfaces are synchronized, too, without explicitly setting them. * * If the wl_surface associated with the wl_subsurface is destroyed, the * wl_subsurface object becomes inert. Note, that destroying either object * takes effect immediately. If you need to synchronize the removal * of a sub-surface to the parent surface update, unmap the sub-surface * first by attaching a NULL wl_buffer, update parent, and then destroy * the sub-surface. * * If the parent wl_surface object is destroyed, the sub-surface is * unmapped. */ extern const struct wl_interface wl_subsurface_interface; #ifndef WL_DISPLAY_ERROR_ENUM #define WL_DISPLAY_ERROR_ENUM /** * @ingroup iface_wl_display * global error values * * These errors are global and can be emitted in response to any * server request. */ enum wl_display_error { /** * server couldn't find object */ WL_DISPLAY_ERROR_INVALID_OBJECT = 0, /** * method doesn't exist on the specified interface */ WL_DISPLAY_ERROR_INVALID_METHOD = 1, /** * server is out of memory */ WL_DISPLAY_ERROR_NO_MEMORY = 2, }; #endif /* WL_DISPLAY_ERROR_ENUM */ /** * @ingroup iface_wl_display * @struct wl_display_listener */ struct wl_display_listener { /** * fatal error event * * The error event is sent out when a fatal (non-recoverable) * error has occurred. The object_id argument is the object where * the error occurred, most often in response to a request to that * object. The code identifies the error and is defined by the * object interface. As such, each interface defines its own set of * error codes. The message is a brief description of the error, * for (debugging) convenience. * @param object_id object where the error occurred * @param code error code * @param message error description */ void (*error)(void *data, struct wl_display *wl_display, void *object_id, uint32_t code, const char *message); /** * acknowledge object ID deletion * * This event is used internally by the object ID management * logic. When a client deletes an object, the server will send * this event to acknowledge that it has seen the delete request. * When the client receives this event, it will know that it can * safely reuse the object ID. * @param id deleted object ID */ void (*delete_id)(void *data, struct wl_display *wl_display, uint32_t id); }; /** * @ingroup iface_wl_display */ static inline int wl_display_add_listener(struct wl_display *wl_display, const struct wl_display_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_display, (void (**)(void)) listener, data); } #define WL_DISPLAY_SYNC 0 #define WL_DISPLAY_GET_REGISTRY 1 /** * @ingroup iface_wl_display */ #define WL_DISPLAY_ERROR_SINCE_VERSION 1 /** * @ingroup iface_wl_display */ #define WL_DISPLAY_DELETE_ID_SINCE_VERSION 1 /** * @ingroup iface_wl_display */ #define WL_DISPLAY_SYNC_SINCE_VERSION 1 /** * @ingroup iface_wl_display */ #define WL_DISPLAY_GET_REGISTRY_SINCE_VERSION 1 /** @ingroup iface_wl_display */ static inline void wl_display_set_user_data(struct wl_display *wl_display, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_display, user_data); } /** @ingroup iface_wl_display */ static inline void * wl_display_get_user_data(struct wl_display *wl_display) { return wl_proxy_get_user_data((struct wl_proxy *) wl_display); } static inline uint32_t wl_display_get_version(struct wl_display *wl_display) { return wl_proxy_get_version((struct wl_proxy *) wl_display); } /** * @ingroup iface_wl_display * * The sync request asks the server to emit the 'done' event * on the returned wl_callback object. Since requests are * handled in-order and events are delivered in-order, this can * be used as a barrier to ensure all previous requests and the * resulting events have been handled. * * The object returned by this request will be destroyed by the * compositor after the callback is fired and as such the client must not * attempt to use it after that point. * * The callback_data passed in the callback is the event serial. */ static inline struct wl_callback * wl_display_sync(struct wl_display *wl_display) { struct wl_proxy *callback; callback = wl_proxy_marshal_constructor((struct wl_proxy *) wl_display, WL_DISPLAY_SYNC, &wl_callback_interface, NULL); return (struct wl_callback *) callback; } /** * @ingroup iface_wl_display * * This request creates a registry object that allows the client * to list and bind the global objects available from the * compositor. */ static inline struct wl_registry * wl_display_get_registry(struct wl_display *wl_display) { struct wl_proxy *registry; registry = wl_proxy_marshal_constructor((struct wl_proxy *) wl_display, WL_DISPLAY_GET_REGISTRY, &wl_registry_interface, NULL); return (struct wl_registry *) registry; } /** * @ingroup iface_wl_registry * @struct wl_registry_listener */ struct wl_registry_listener { /** * announce global object * * Notify the client of global objects. * * The event notifies the client that a global object with the * given name is now available, and it implements the given version * of the given interface. * @param name numeric name of the global object * @param interface interface implemented by the object * @param version interface version */ void (*global)(void *data, struct wl_registry *wl_registry, uint32_t name, const char *interface, uint32_t version); /** * announce removal of global object * * Notify the client of removed global objects. * * This event notifies the client that the global identified by * name is no longer available. If the client bound to the global * using the bind request, the client should now destroy that * object. * * The object remains valid and requests to the object will be * ignored until the client destroys it, to avoid races between the * global going away and a client sending a request to it. * @param name numeric name of the global object */ void (*global_remove)(void *data, struct wl_registry *wl_registry, uint32_t name); }; /** * @ingroup iface_wl_registry */ static inline int wl_registry_add_listener(struct wl_registry *wl_registry, const struct wl_registry_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_registry, (void (**)(void)) listener, data); } #define WL_REGISTRY_BIND 0 /** * @ingroup iface_wl_registry */ #define WL_REGISTRY_GLOBAL_SINCE_VERSION 1 /** * @ingroup iface_wl_registry */ #define WL_REGISTRY_GLOBAL_REMOVE_SINCE_VERSION 1 /** * @ingroup iface_wl_registry */ #define WL_REGISTRY_BIND_SINCE_VERSION 1 /** @ingroup iface_wl_registry */ static inline void wl_registry_set_user_data(struct wl_registry *wl_registry, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_registry, user_data); } /** @ingroup iface_wl_registry */ static inline void * wl_registry_get_user_data(struct wl_registry *wl_registry) { return wl_proxy_get_user_data((struct wl_proxy *) wl_registry); } static inline uint32_t wl_registry_get_version(struct wl_registry *wl_registry) { return wl_proxy_get_version((struct wl_proxy *) wl_registry); } /** @ingroup iface_wl_registry */ static inline void wl_registry_destroy(struct wl_registry *wl_registry) { wl_proxy_destroy((struct wl_proxy *) wl_registry); } /** * @ingroup iface_wl_registry * * Binds a new, client-created object to the server using the * specified name as the identifier. */ static inline void * wl_registry_bind(struct wl_registry *wl_registry, uint32_t name, const struct wl_interface *interface, uint32_t version) { struct wl_proxy *id; id = wl_proxy_marshal_constructor_versioned((struct wl_proxy *) wl_registry, WL_REGISTRY_BIND, interface, version, name, interface->name, version, NULL); return (void *) id; } /** * @ingroup iface_wl_callback * @struct wl_callback_listener */ struct wl_callback_listener { /** * done event * * Notify the client when the related request is done. * @param callback_data request-specific data for the callback */ void (*done)(void *data, struct wl_callback *wl_callback, uint32_t callback_data); }; /** * @ingroup iface_wl_callback */ static inline int wl_callback_add_listener(struct wl_callback *wl_callback, const struct wl_callback_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_callback, (void (**)(void)) listener, data); } /** * @ingroup iface_wl_callback */ #define WL_CALLBACK_DONE_SINCE_VERSION 1 /** @ingroup iface_wl_callback */ static inline void wl_callback_set_user_data(struct wl_callback *wl_callback, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_callback, user_data); } /** @ingroup iface_wl_callback */ static inline void * wl_callback_get_user_data(struct wl_callback *wl_callback) { return wl_proxy_get_user_data((struct wl_proxy *) wl_callback); } static inline uint32_t wl_callback_get_version(struct wl_callback *wl_callback) { return wl_proxy_get_version((struct wl_proxy *) wl_callback); } /** @ingroup iface_wl_callback */ static inline void wl_callback_destroy(struct wl_callback *wl_callback) { wl_proxy_destroy((struct wl_proxy *) wl_callback); } #define WL_COMPOSITOR_CREATE_SURFACE 0 #define WL_COMPOSITOR_CREATE_REGION 1 /** * @ingroup iface_wl_compositor */ #define WL_COMPOSITOR_CREATE_SURFACE_SINCE_VERSION 1 /** * @ingroup iface_wl_compositor */ #define WL_COMPOSITOR_CREATE_REGION_SINCE_VERSION 1 /** @ingroup iface_wl_compositor */ static inline void wl_compositor_set_user_data(struct wl_compositor *wl_compositor, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_compositor, user_data); } /** @ingroup iface_wl_compositor */ static inline void * wl_compositor_get_user_data(struct wl_compositor *wl_compositor) { return wl_proxy_get_user_data((struct wl_proxy *) wl_compositor); } static inline uint32_t wl_compositor_get_version(struct wl_compositor *wl_compositor) { return wl_proxy_get_version((struct wl_proxy *) wl_compositor); } /** @ingroup iface_wl_compositor */ static inline void wl_compositor_destroy(struct wl_compositor *wl_compositor) { wl_proxy_destroy((struct wl_proxy *) wl_compositor); } /** * @ingroup iface_wl_compositor * * Ask the compositor to create a new surface. */ static inline struct wl_surface * wl_compositor_create_surface(struct wl_compositor *wl_compositor) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_compositor, WL_COMPOSITOR_CREATE_SURFACE, &wl_surface_interface, NULL); return (struct wl_surface *) id; } /** * @ingroup iface_wl_compositor * * Ask the compositor to create a new region. */ static inline struct wl_region * wl_compositor_create_region(struct wl_compositor *wl_compositor) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_compositor, WL_COMPOSITOR_CREATE_REGION, &wl_region_interface, NULL); return (struct wl_region *) id; } #define WL_SHM_POOL_CREATE_BUFFER 0 #define WL_SHM_POOL_DESTROY 1 #define WL_SHM_POOL_RESIZE 2 /** * @ingroup iface_wl_shm_pool */ #define WL_SHM_POOL_CREATE_BUFFER_SINCE_VERSION 1 /** * @ingroup iface_wl_shm_pool */ #define WL_SHM_POOL_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_shm_pool */ #define WL_SHM_POOL_RESIZE_SINCE_VERSION 1 /** @ingroup iface_wl_shm_pool */ static inline void wl_shm_pool_set_user_data(struct wl_shm_pool *wl_shm_pool, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_shm_pool, user_data); } /** @ingroup iface_wl_shm_pool */ static inline void * wl_shm_pool_get_user_data(struct wl_shm_pool *wl_shm_pool) { return wl_proxy_get_user_data((struct wl_proxy *) wl_shm_pool); } static inline uint32_t wl_shm_pool_get_version(struct wl_shm_pool *wl_shm_pool) { return wl_proxy_get_version((struct wl_proxy *) wl_shm_pool); } /** * @ingroup iface_wl_shm_pool * * Create a wl_buffer object from the pool. * * The buffer is created offset bytes into the pool and has * width and height as specified. The stride argument specifies * the number of bytes from the beginning of one row to the beginning * of the next. The format is the pixel format of the buffer and * must be one of those advertised through the wl_shm.format event. * * A buffer will keep a reference to the pool it was created from * so it is valid to destroy the pool immediately after creating * a buffer from it. */ static inline struct wl_buffer * wl_shm_pool_create_buffer(struct wl_shm_pool *wl_shm_pool, int32_t offset, int32_t width, int32_t height, int32_t stride, uint32_t format) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_shm_pool, WL_SHM_POOL_CREATE_BUFFER, &wl_buffer_interface, NULL, offset, width, height, stride, format); return (struct wl_buffer *) id; } /** * @ingroup iface_wl_shm_pool * * Destroy the shared memory pool. * * The mmapped memory will be released when all * buffers that have been created from this pool * are gone. */ static inline void wl_shm_pool_destroy(struct wl_shm_pool *wl_shm_pool) { wl_proxy_marshal((struct wl_proxy *) wl_shm_pool, WL_SHM_POOL_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_shm_pool); } /** * @ingroup iface_wl_shm_pool * * This request will cause the server to remap the backing memory * for the pool from the file descriptor passed when the pool was * created, but using the new size. This request can only be * used to make the pool bigger. */ static inline void wl_shm_pool_resize(struct wl_shm_pool *wl_shm_pool, int32_t size) { wl_proxy_marshal((struct wl_proxy *) wl_shm_pool, WL_SHM_POOL_RESIZE, size); } #ifndef WL_SHM_ERROR_ENUM #define WL_SHM_ERROR_ENUM /** * @ingroup iface_wl_shm * wl_shm error values * * These errors can be emitted in response to wl_shm requests. */ enum wl_shm_error { /** * buffer format is not known */ WL_SHM_ERROR_INVALID_FORMAT = 0, /** * invalid size or stride during pool or buffer creation */ WL_SHM_ERROR_INVALID_STRIDE = 1, /** * mmapping the file descriptor failed */ WL_SHM_ERROR_INVALID_FD = 2, }; #endif /* WL_SHM_ERROR_ENUM */ #ifndef WL_SHM_FORMAT_ENUM #define WL_SHM_FORMAT_ENUM /** * @ingroup iface_wl_shm * pixel formats * * This describes the memory layout of an individual pixel. * * All renderers should support argb8888 and xrgb8888 but any other * formats are optional and may not be supported by the particular * renderer in use. * * The drm format codes match the macros defined in drm_fourcc.h. * The formats actually supported by the compositor will be * reported by the format event. */ enum wl_shm_format { /** * 32-bit ARGB format, [31:0] A:R:G:B 8:8:8:8 little endian */ WL_SHM_FORMAT_ARGB8888 = 0, /** * 32-bit RGB format, [31:0] x:R:G:B 8:8:8:8 little endian */ WL_SHM_FORMAT_XRGB8888 = 1, /** * 8-bit color index format, [7:0] C */ WL_SHM_FORMAT_C8 = 0x20203843, /** * 8-bit RGB format, [7:0] R:G:B 3:3:2 */ WL_SHM_FORMAT_RGB332 = 0x38424752, /** * 8-bit BGR format, [7:0] B:G:R 2:3:3 */ WL_SHM_FORMAT_BGR233 = 0x38524742, /** * 16-bit xRGB format, [15:0] x:R:G:B 4:4:4:4 little endian */ WL_SHM_FORMAT_XRGB4444 = 0x32315258, /** * 16-bit xBGR format, [15:0] x:B:G:R 4:4:4:4 little endian */ WL_SHM_FORMAT_XBGR4444 = 0x32314258, /** * 16-bit RGBx format, [15:0] R:G:B:x 4:4:4:4 little endian */ WL_SHM_FORMAT_RGBX4444 = 0x32315852, /** * 16-bit BGRx format, [15:0] B:G:R:x 4:4:4:4 little endian */ WL_SHM_FORMAT_BGRX4444 = 0x32315842, /** * 16-bit ARGB format, [15:0] A:R:G:B 4:4:4:4 little endian */ WL_SHM_FORMAT_ARGB4444 = 0x32315241, /** * 16-bit ABGR format, [15:0] A:B:G:R 4:4:4:4 little endian */ WL_SHM_FORMAT_ABGR4444 = 0x32314241, /** * 16-bit RBGA format, [15:0] R:G:B:A 4:4:4:4 little endian */ WL_SHM_FORMAT_RGBA4444 = 0x32314152, /** * 16-bit BGRA format, [15:0] B:G:R:A 4:4:4:4 little endian */ WL_SHM_FORMAT_BGRA4444 = 0x32314142, /** * 16-bit xRGB format, [15:0] x:R:G:B 1:5:5:5 little endian */ WL_SHM_FORMAT_XRGB1555 = 0x35315258, /** * 16-bit xBGR 1555 format, [15:0] x:B:G:R 1:5:5:5 little endian */ WL_SHM_FORMAT_XBGR1555 = 0x35314258, /** * 16-bit RGBx 5551 format, [15:0] R:G:B:x 5:5:5:1 little endian */ WL_SHM_FORMAT_RGBX5551 = 0x35315852, /** * 16-bit BGRx 5551 format, [15:0] B:G:R:x 5:5:5:1 little endian */ WL_SHM_FORMAT_BGRX5551 = 0x35315842, /** * 16-bit ARGB 1555 format, [15:0] A:R:G:B 1:5:5:5 little endian */ WL_SHM_FORMAT_ARGB1555 = 0x35315241, /** * 16-bit ABGR 1555 format, [15:0] A:B:G:R 1:5:5:5 little endian */ WL_SHM_FORMAT_ABGR1555 = 0x35314241, /** * 16-bit RGBA 5551 format, [15:0] R:G:B:A 5:5:5:1 little endian */ WL_SHM_FORMAT_RGBA5551 = 0x35314152, /** * 16-bit BGRA 5551 format, [15:0] B:G:R:A 5:5:5:1 little endian */ WL_SHM_FORMAT_BGRA5551 = 0x35314142, /** * 16-bit RGB 565 format, [15:0] R:G:B 5:6:5 little endian */ WL_SHM_FORMAT_RGB565 = 0x36314752, /** * 16-bit BGR 565 format, [15:0] B:G:R 5:6:5 little endian */ WL_SHM_FORMAT_BGR565 = 0x36314742, /** * 24-bit RGB format, [23:0] R:G:B little endian */ WL_SHM_FORMAT_RGB888 = 0x34324752, /** * 24-bit BGR format, [23:0] B:G:R little endian */ WL_SHM_FORMAT_BGR888 = 0x34324742, /** * 32-bit xBGR format, [31:0] x:B:G:R 8:8:8:8 little endian */ WL_SHM_FORMAT_XBGR8888 = 0x34324258, /** * 32-bit RGBx format, [31:0] R:G:B:x 8:8:8:8 little endian */ WL_SHM_FORMAT_RGBX8888 = 0x34325852, /** * 32-bit BGRx format, [31:0] B:G:R:x 8:8:8:8 little endian */ WL_SHM_FORMAT_BGRX8888 = 0x34325842, /** * 32-bit ABGR format, [31:0] A:B:G:R 8:8:8:8 little endian */ WL_SHM_FORMAT_ABGR8888 = 0x34324241, /** * 32-bit RGBA format, [31:0] R:G:B:A 8:8:8:8 little endian */ WL_SHM_FORMAT_RGBA8888 = 0x34324152, /** * 32-bit BGRA format, [31:0] B:G:R:A 8:8:8:8 little endian */ WL_SHM_FORMAT_BGRA8888 = 0x34324142, /** * 32-bit xRGB format, [31:0] x:R:G:B 2:10:10:10 little endian */ WL_SHM_FORMAT_XRGB2101010 = 0x30335258, /** * 32-bit xBGR format, [31:0] x:B:G:R 2:10:10:10 little endian */ WL_SHM_FORMAT_XBGR2101010 = 0x30334258, /** * 32-bit RGBx format, [31:0] R:G:B:x 10:10:10:2 little endian */ WL_SHM_FORMAT_RGBX1010102 = 0x30335852, /** * 32-bit BGRx format, [31:0] B:G:R:x 10:10:10:2 little endian */ WL_SHM_FORMAT_BGRX1010102 = 0x30335842, /** * 32-bit ARGB format, [31:0] A:R:G:B 2:10:10:10 little endian */ WL_SHM_FORMAT_ARGB2101010 = 0x30335241, /** * 32-bit ABGR format, [31:0] A:B:G:R 2:10:10:10 little endian */ WL_SHM_FORMAT_ABGR2101010 = 0x30334241, /** * 32-bit RGBA format, [31:0] R:G:B:A 10:10:10:2 little endian */ WL_SHM_FORMAT_RGBA1010102 = 0x30334152, /** * 32-bit BGRA format, [31:0] B:G:R:A 10:10:10:2 little endian */ WL_SHM_FORMAT_BGRA1010102 = 0x30334142, /** * packed YCbCr format, [31:0] Cr0:Y1:Cb0:Y0 8:8:8:8 little endian */ WL_SHM_FORMAT_YUYV = 0x56595559, /** * packed YCbCr format, [31:0] Cb0:Y1:Cr0:Y0 8:8:8:8 little endian */ WL_SHM_FORMAT_YVYU = 0x55595659, /** * packed YCbCr format, [31:0] Y1:Cr0:Y0:Cb0 8:8:8:8 little endian */ WL_SHM_FORMAT_UYVY = 0x59565955, /** * packed YCbCr format, [31:0] Y1:Cb0:Y0:Cr0 8:8:8:8 little endian */ WL_SHM_FORMAT_VYUY = 0x59555956, /** * packed AYCbCr format, [31:0] A:Y:Cb:Cr 8:8:8:8 little endian */ WL_SHM_FORMAT_AYUV = 0x56555941, /** * 2 plane YCbCr Cr:Cb format, 2x2 subsampled Cr:Cb plane */ WL_SHM_FORMAT_NV12 = 0x3231564e, /** * 2 plane YCbCr Cb:Cr format, 2x2 subsampled Cb:Cr plane */ WL_SHM_FORMAT_NV21 = 0x3132564e, /** * 2 plane YCbCr Cr:Cb format, 2x1 subsampled Cr:Cb plane */ WL_SHM_FORMAT_NV16 = 0x3631564e, /** * 2 plane YCbCr Cb:Cr format, 2x1 subsampled Cb:Cr plane */ WL_SHM_FORMAT_NV61 = 0x3136564e, /** * 3 plane YCbCr format, 4x4 subsampled Cb (1) and Cr (2) planes */ WL_SHM_FORMAT_YUV410 = 0x39565559, /** * 3 plane YCbCr format, 4x4 subsampled Cr (1) and Cb (2) planes */ WL_SHM_FORMAT_YVU410 = 0x39555659, /** * 3 plane YCbCr format, 4x1 subsampled Cb (1) and Cr (2) planes */ WL_SHM_FORMAT_YUV411 = 0x31315559, /** * 3 plane YCbCr format, 4x1 subsampled Cr (1) and Cb (2) planes */ WL_SHM_FORMAT_YVU411 = 0x31315659, /** * 3 plane YCbCr format, 2x2 subsampled Cb (1) and Cr (2) planes */ WL_SHM_FORMAT_YUV420 = 0x32315559, /** * 3 plane YCbCr format, 2x2 subsampled Cr (1) and Cb (2) planes */ WL_SHM_FORMAT_YVU420 = 0x32315659, /** * 3 plane YCbCr format, 2x1 subsampled Cb (1) and Cr (2) planes */ WL_SHM_FORMAT_YUV422 = 0x36315559, /** * 3 plane YCbCr format, 2x1 subsampled Cr (1) and Cb (2) planes */ WL_SHM_FORMAT_YVU422 = 0x36315659, /** * 3 plane YCbCr format, non-subsampled Cb (1) and Cr (2) planes */ WL_SHM_FORMAT_YUV444 = 0x34325559, /** * 3 plane YCbCr format, non-subsampled Cr (1) and Cb (2) planes */ WL_SHM_FORMAT_YVU444 = 0x34325659, }; #endif /* WL_SHM_FORMAT_ENUM */ /** * @ingroup iface_wl_shm * @struct wl_shm_listener */ struct wl_shm_listener { /** * pixel format description * * Informs the client about a valid pixel format that can be used * for buffers. Known formats include argb8888 and xrgb8888. * @param format buffer pixel format */ void (*format)(void *data, struct wl_shm *wl_shm, uint32_t format); }; /** * @ingroup iface_wl_shm */ static inline int wl_shm_add_listener(struct wl_shm *wl_shm, const struct wl_shm_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_shm, (void (**)(void)) listener, data); } #define WL_SHM_CREATE_POOL 0 /** * @ingroup iface_wl_shm */ #define WL_SHM_FORMAT_SINCE_VERSION 1 /** * @ingroup iface_wl_shm */ #define WL_SHM_CREATE_POOL_SINCE_VERSION 1 /** @ingroup iface_wl_shm */ static inline void wl_shm_set_user_data(struct wl_shm *wl_shm, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_shm, user_data); } /** @ingroup iface_wl_shm */ static inline void * wl_shm_get_user_data(struct wl_shm *wl_shm) { return wl_proxy_get_user_data((struct wl_proxy *) wl_shm); } static inline uint32_t wl_shm_get_version(struct wl_shm *wl_shm) { return wl_proxy_get_version((struct wl_proxy *) wl_shm); } /** @ingroup iface_wl_shm */ static inline void wl_shm_destroy(struct wl_shm *wl_shm) { wl_proxy_destroy((struct wl_proxy *) wl_shm); } /** * @ingroup iface_wl_shm * * Create a new wl_shm_pool object. * * The pool can be used to create shared memory based buffer * objects. The server will mmap size bytes of the passed file * descriptor, to use as backing memory for the pool. */ static inline struct wl_shm_pool * wl_shm_create_pool(struct wl_shm *wl_shm, int32_t fd, int32_t size) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_shm, WL_SHM_CREATE_POOL, &wl_shm_pool_interface, NULL, fd, size); return (struct wl_shm_pool *) id; } /** * @ingroup iface_wl_buffer * @struct wl_buffer_listener */ struct wl_buffer_listener { /** * compositor releases buffer * * Sent when this wl_buffer is no longer used by the compositor. * The client is now free to reuse or destroy this buffer and its * backing storage. * * If a client receives a release event before the frame callback * requested in the same wl_surface.commit that attaches this * wl_buffer to a surface, then the client is immediately free to * reuse the buffer and its backing storage, and does not need a * second buffer for the next surface content update. Typically * this is possible, when the compositor maintains a copy of the * wl_surface contents, e.g. as a GL texture. This is an important * optimization for GL(ES) compositors with wl_shm clients. */ void (*release)(void *data, struct wl_buffer *wl_buffer); }; /** * @ingroup iface_wl_buffer */ static inline int wl_buffer_add_listener(struct wl_buffer *wl_buffer, const struct wl_buffer_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_buffer, (void (**)(void)) listener, data); } #define WL_BUFFER_DESTROY 0 /** * @ingroup iface_wl_buffer */ #define WL_BUFFER_RELEASE_SINCE_VERSION 1 /** * @ingroup iface_wl_buffer */ #define WL_BUFFER_DESTROY_SINCE_VERSION 1 /** @ingroup iface_wl_buffer */ static inline void wl_buffer_set_user_data(struct wl_buffer *wl_buffer, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_buffer, user_data); } /** @ingroup iface_wl_buffer */ static inline void * wl_buffer_get_user_data(struct wl_buffer *wl_buffer) { return wl_proxy_get_user_data((struct wl_proxy *) wl_buffer); } static inline uint32_t wl_buffer_get_version(struct wl_buffer *wl_buffer) { return wl_proxy_get_version((struct wl_proxy *) wl_buffer); } /** * @ingroup iface_wl_buffer * * Destroy a buffer. If and how you need to release the backing * storage is defined by the buffer factory interface. * * For possible side-effects to a surface, see wl_surface.attach. */ static inline void wl_buffer_destroy(struct wl_buffer *wl_buffer) { wl_proxy_marshal((struct wl_proxy *) wl_buffer, WL_BUFFER_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_buffer); } #ifndef WL_DATA_OFFER_ERROR_ENUM #define WL_DATA_OFFER_ERROR_ENUM enum wl_data_offer_error { /** * finish request was called untimely */ WL_DATA_OFFER_ERROR_INVALID_FINISH = 0, /** * action mask contains invalid values */ WL_DATA_OFFER_ERROR_INVALID_ACTION_MASK = 1, /** * action argument has an invalid value */ WL_DATA_OFFER_ERROR_INVALID_ACTION = 2, /** * offer doesn't accept this request */ WL_DATA_OFFER_ERROR_INVALID_OFFER = 3, }; #endif /* WL_DATA_OFFER_ERROR_ENUM */ /** * @ingroup iface_wl_data_offer * @struct wl_data_offer_listener */ struct wl_data_offer_listener { /** * advertise offered mime type * * Sent immediately after creating the wl_data_offer object. One * event per offered mime type. * @param mime_type offered mime type */ void (*offer)(void *data, struct wl_data_offer *wl_data_offer, const char *mime_type); /** * notify the source-side available actions * * This event indicates the actions offered by the data source. * It will be sent right after wl_data_device.enter, or anytime the * source side changes its offered actions through * wl_data_source.set_actions. * @param source_actions actions offered by the data source * @since 3 */ void (*source_actions)(void *data, struct wl_data_offer *wl_data_offer, uint32_t source_actions); /** * notify the selected action * * This event indicates the action selected by the compositor * after matching the source/destination side actions. Only one * action (or none) will be offered here. * * This event can be emitted multiple times during the * drag-and-drop operation in response to destination side action * changes through wl_data_offer.set_actions. * * This event will no longer be emitted after wl_data_device.drop * happened on the drag-and-drop destination, the client must honor * the last action received, or the last preferred one set through * wl_data_offer.set_actions when handling an "ask" action. * * Compositors may also change the selected action on the fly, * mainly in response to keyboard modifier changes during the * drag-and-drop operation. * * The most recent action received is always the valid one. Prior * to receiving wl_data_device.drop, the chosen action may change * (e.g. due to keyboard modifiers being pressed). At the time of * receiving wl_data_device.drop the drag-and-drop destination must * honor the last action received. * * Action changes may still happen after wl_data_device.drop, * especially on "ask" actions, where the drag-and-drop destination * may choose another action afterwards. Action changes happening * at this stage are always the result of inter-client negotiation, * the compositor shall no longer be able to induce a different * action. * * Upon "ask" actions, it is expected that the drag-and-drop * destination may potentially choose a different action and/or * mime type, based on wl_data_offer.source_actions and finally * chosen by the user (e.g. popping up a menu with the available * options). The final wl_data_offer.set_actions and * wl_data_offer.accept requests must happen before the call to * wl_data_offer.finish. * @param dnd_action action selected by the compositor * @since 3 */ void (*action)(void *data, struct wl_data_offer *wl_data_offer, uint32_t dnd_action); }; /** * @ingroup iface_wl_data_offer */ static inline int wl_data_offer_add_listener(struct wl_data_offer *wl_data_offer, const struct wl_data_offer_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_data_offer, (void (**)(void)) listener, data); } #define WL_DATA_OFFER_ACCEPT 0 #define WL_DATA_OFFER_RECEIVE 1 #define WL_DATA_OFFER_DESTROY 2 #define WL_DATA_OFFER_FINISH 3 #define WL_DATA_OFFER_SET_ACTIONS 4 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_OFFER_SINCE_VERSION 1 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_SOURCE_ACTIONS_SINCE_VERSION 3 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_ACTION_SINCE_VERSION 3 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_ACCEPT_SINCE_VERSION 1 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_RECEIVE_SINCE_VERSION 1 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_FINISH_SINCE_VERSION 3 /** * @ingroup iface_wl_data_offer */ #define WL_DATA_OFFER_SET_ACTIONS_SINCE_VERSION 3 /** @ingroup iface_wl_data_offer */ static inline void wl_data_offer_set_user_data(struct wl_data_offer *wl_data_offer, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_data_offer, user_data); } /** @ingroup iface_wl_data_offer */ static inline void * wl_data_offer_get_user_data(struct wl_data_offer *wl_data_offer) { return wl_proxy_get_user_data((struct wl_proxy *) wl_data_offer); } static inline uint32_t wl_data_offer_get_version(struct wl_data_offer *wl_data_offer) { return wl_proxy_get_version((struct wl_proxy *) wl_data_offer); } /** * @ingroup iface_wl_data_offer * * Indicate that the client can accept the given mime type, or * NULL for not accepted. * * For objects of version 2 or older, this request is used by the * client to give feedback whether the client can receive the given * mime type, or NULL if none is accepted; the feedback does not * determine whether the drag-and-drop operation succeeds or not. * * For objects of version 3 or newer, this request determines the * final result of the drag-and-drop operation. If the end result * is that no mime types were accepted, the drag-and-drop operation * will be cancelled and the corresponding drag source will receive * wl_data_source.cancelled. Clients may still use this event in * conjunction with wl_data_source.action for feedback. */ static inline void wl_data_offer_accept(struct wl_data_offer *wl_data_offer, uint32_t serial, const char *mime_type) { wl_proxy_marshal((struct wl_proxy *) wl_data_offer, WL_DATA_OFFER_ACCEPT, serial, mime_type); } /** * @ingroup iface_wl_data_offer * * To transfer the offered data, the client issues this request * and indicates the mime type it wants to receive. The transfer * happens through the passed file descriptor (typically created * with the pipe system call). The source client writes the data * in the mime type representation requested and then closes the * file descriptor. * * The receiving client reads from the read end of the pipe until * EOF and then closes its end, at which point the transfer is * complete. * * This request may happen multiple times for different mime types, * both before and after wl_data_device.drop. Drag-and-drop destination * clients may preemptively fetch data or examine it more closely to * determine acceptance. */ static inline void wl_data_offer_receive(struct wl_data_offer *wl_data_offer, const char *mime_type, int32_t fd) { wl_proxy_marshal((struct wl_proxy *) wl_data_offer, WL_DATA_OFFER_RECEIVE, mime_type, fd); } /** * @ingroup iface_wl_data_offer * * Destroy the data offer. */ static inline void wl_data_offer_destroy(struct wl_data_offer *wl_data_offer) { wl_proxy_marshal((struct wl_proxy *) wl_data_offer, WL_DATA_OFFER_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_data_offer); } /** * @ingroup iface_wl_data_offer * * Notifies the compositor that the drag destination successfully * finished the drag-and-drop operation. * * Upon receiving this request, the compositor will emit * wl_data_source.dnd_finished on the drag source client. * * It is a client error to perform other requests than * wl_data_offer.destroy after this one. It is also an error to perform * this request after a NULL mime type has been set in * wl_data_offer.accept or no action was received through * wl_data_offer.action. */ static inline void wl_data_offer_finish(struct wl_data_offer *wl_data_offer) { wl_proxy_marshal((struct wl_proxy *) wl_data_offer, WL_DATA_OFFER_FINISH); } /** * @ingroup iface_wl_data_offer * * Sets the actions that the destination side client supports for * this operation. This request may trigger the emission of * wl_data_source.action and wl_data_offer.action events if the compositor * needs to change the selected action. * * This request can be called multiple times throughout the * drag-and-drop operation, typically in response to wl_data_device.enter * or wl_data_device.motion events. * * This request determines the final result of the drag-and-drop * operation. If the end result is that no action is accepted, * the drag source will receive wl_drag_source.cancelled. * * The dnd_actions argument must contain only values expressed in the * wl_data_device_manager.dnd_actions enum, and the preferred_action * argument must only contain one of those values set, otherwise it * will result in a protocol error. * * While managing an "ask" action, the destination drag-and-drop client * may perform further wl_data_offer.receive requests, and is expected * to perform one last wl_data_offer.set_actions request with a preferred * action other than "ask" (and optionally wl_data_offer.accept) before * requesting wl_data_offer.finish, in order to convey the action selected * by the user. If the preferred action is not in the * wl_data_offer.source_actions mask, an error will be raised. * * If the "ask" action is dismissed (e.g. user cancellation), the client * is expected to perform wl_data_offer.destroy right away. * * This request can only be made on drag-and-drop offers, a protocol error * will be raised otherwise. */ static inline void wl_data_offer_set_actions(struct wl_data_offer *wl_data_offer, uint32_t dnd_actions, uint32_t preferred_action) { wl_proxy_marshal((struct wl_proxy *) wl_data_offer, WL_DATA_OFFER_SET_ACTIONS, dnd_actions, preferred_action); } #ifndef WL_DATA_SOURCE_ERROR_ENUM #define WL_DATA_SOURCE_ERROR_ENUM enum wl_data_source_error { /** * action mask contains invalid values */ WL_DATA_SOURCE_ERROR_INVALID_ACTION_MASK = 0, /** * source doesn't accept this request */ WL_DATA_SOURCE_ERROR_INVALID_SOURCE = 1, }; #endif /* WL_DATA_SOURCE_ERROR_ENUM */ /** * @ingroup iface_wl_data_source * @struct wl_data_source_listener */ struct wl_data_source_listener { /** * a target accepts an offered mime type * * Sent when a target accepts pointer_focus or motion events. If * a target does not accept any of the offered types, type is NULL. * * Used for feedback during drag-and-drop. * @param mime_type mime type accepted by the target */ void (*target)(void *data, struct wl_data_source *wl_data_source, const char *mime_type); /** * send the data * * Request for data from the client. Send the data as the * specified mime type over the passed file descriptor, then close * it. * @param mime_type mime type for the data * @param fd file descriptor for the data */ void (*send)(void *data, struct wl_data_source *wl_data_source, const char *mime_type, int32_t fd); /** * selection was cancelled * * This data source is no longer valid. There are several reasons * why this could happen: * * - The data source has been replaced by another data source. - * The drag-and-drop operation was performed, but the drop * destination did not accept any of the mime types offered through * wl_data_source.target. - The drag-and-drop operation was * performed, but the drop destination did not select any of the * actions present in the mask offered through * wl_data_source.action. - The drag-and-drop operation was * performed but didn't happen over a surface. - The compositor * cancelled the drag-and-drop operation (e.g. compositor dependent * timeouts to avoid stale drag-and-drop transfers). * * The client should clean up and destroy this data source. * * For objects of version 2 or older, wl_data_source.cancelled will * only be emitted if the data source was replaced by another data * source. */ void (*cancelled)(void *data, struct wl_data_source *wl_data_source); /** * the drag-and-drop operation physically finished * * The user performed the drop action. This event does not * indicate acceptance, wl_data_source.cancelled may still be * emitted afterwards if the drop destination does not accept any * mime type. * * However, this event might however not be received if the * compositor cancelled the drag-and-drop operation before this * event could happen. * * Note that the data_source may still be used in the future and * should not be destroyed here. * @since 3 */ void (*dnd_drop_performed)(void *data, struct wl_data_source *wl_data_source); /** * the drag-and-drop operation concluded * * The drop destination finished interoperating with this data * source, so the client is now free to destroy this data source * and free all associated data. * * If the action used to perform the operation was "move", the * source can now delete the transferred data. * @since 3 */ void (*dnd_finished)(void *data, struct wl_data_source *wl_data_source); /** * notify the selected action * * This event indicates the action selected by the compositor * after matching the source/destination side actions. Only one * action (or none) will be offered here. * * This event can be emitted multiple times during the * drag-and-drop operation, mainly in response to destination side * changes through wl_data_offer.set_actions, and as the data * device enters/leaves surfaces. * * It is only possible to receive this event after * wl_data_source.dnd_drop_performed if the drag-and-drop operation * ended in an "ask" action, in which case the final * wl_data_source.action event will happen immediately before * wl_data_source.dnd_finished. * * Compositors may also change the selected action on the fly, * mainly in response to keyboard modifier changes during the * drag-and-drop operation. * * The most recent action received is always the valid one. The * chosen action may change alongside negotiation (e.g. an "ask" * action can turn into a "move" operation), so the effects of the * final action must always be applied in * wl_data_offer.dnd_finished. * * Clients can trigger cursor surface changes from this point, so * they reflect the current action. * @param dnd_action action selected by the compositor * @since 3 */ void (*action)(void *data, struct wl_data_source *wl_data_source, uint32_t dnd_action); }; /** * @ingroup iface_wl_data_source */ static inline int wl_data_source_add_listener(struct wl_data_source *wl_data_source, const struct wl_data_source_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_data_source, (void (**)(void)) listener, data); } #define WL_DATA_SOURCE_OFFER 0 #define WL_DATA_SOURCE_DESTROY 1 #define WL_DATA_SOURCE_SET_ACTIONS 2 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_TARGET_SINCE_VERSION 1 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_SEND_SINCE_VERSION 1 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_CANCELLED_SINCE_VERSION 1 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_DND_DROP_PERFORMED_SINCE_VERSION 3 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_DND_FINISHED_SINCE_VERSION 3 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_ACTION_SINCE_VERSION 3 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_OFFER_SINCE_VERSION 1 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_data_source */ #define WL_DATA_SOURCE_SET_ACTIONS_SINCE_VERSION 3 /** @ingroup iface_wl_data_source */ static inline void wl_data_source_set_user_data(struct wl_data_source *wl_data_source, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_data_source, user_data); } /** @ingroup iface_wl_data_source */ static inline void * wl_data_source_get_user_data(struct wl_data_source *wl_data_source) { return wl_proxy_get_user_data((struct wl_proxy *) wl_data_source); } static inline uint32_t wl_data_source_get_version(struct wl_data_source *wl_data_source) { return wl_proxy_get_version((struct wl_proxy *) wl_data_source); } /** * @ingroup iface_wl_data_source * * This request adds a mime type to the set of mime types * advertised to targets. Can be called several times to offer * multiple types. */ static inline void wl_data_source_offer(struct wl_data_source *wl_data_source, const char *mime_type) { wl_proxy_marshal((struct wl_proxy *) wl_data_source, WL_DATA_SOURCE_OFFER, mime_type); } /** * @ingroup iface_wl_data_source * * Destroy the data source. */ static inline void wl_data_source_destroy(struct wl_data_source *wl_data_source) { wl_proxy_marshal((struct wl_proxy *) wl_data_source, WL_DATA_SOURCE_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_data_source); } /** * @ingroup iface_wl_data_source * * Sets the actions that the source side client supports for this * operation. This request may trigger wl_data_source.action and * wl_data_offer.action events if the compositor needs to change the * selected action. * * The dnd_actions argument must contain only values expressed in the * wl_data_device_manager.dnd_actions enum, otherwise it will result * in a protocol error. * * This request must be made once only, and can only be made on sources * used in drag-and-drop, so it must be performed before * wl_data_device.start_drag. Attempting to use the source other than * for drag-and-drop will raise a protocol error. */ static inline void wl_data_source_set_actions(struct wl_data_source *wl_data_source, uint32_t dnd_actions) { wl_proxy_marshal((struct wl_proxy *) wl_data_source, WL_DATA_SOURCE_SET_ACTIONS, dnd_actions); } #ifndef WL_DATA_DEVICE_ERROR_ENUM #define WL_DATA_DEVICE_ERROR_ENUM enum wl_data_device_error { /** * given wl_surface has another role */ WL_DATA_DEVICE_ERROR_ROLE = 0, }; #endif /* WL_DATA_DEVICE_ERROR_ENUM */ /** * @ingroup iface_wl_data_device * @struct wl_data_device_listener */ struct wl_data_device_listener { /** * introduce a new wl_data_offer * * The data_offer event introduces a new wl_data_offer object, * which will subsequently be used in either the data_device.enter * event (for drag-and-drop) or the data_device.selection event * (for selections). Immediately following the * data_device_data_offer event, the new data_offer object will * send out data_offer.offer events to describe the mime types it * offers. * @param id the new data_offer object */ void (*data_offer)(void *data, struct wl_data_device *wl_data_device, struct wl_data_offer *id); /** * initiate drag-and-drop session * * This event is sent when an active drag-and-drop pointer enters * a surface owned by the client. The position of the pointer at * enter time is provided by the x and y arguments, in * surface-local coordinates. * @param serial serial number of the enter event * @param surface client surface entered * @param x surface-local x coordinate * @param y surface-local y coordinate * @param id source data_offer object */ void (*enter)(void *data, struct wl_data_device *wl_data_device, uint32_t serial, struct wl_surface *surface, wl_fixed_t x, wl_fixed_t y, struct wl_data_offer *id); /** * end drag-and-drop session * * This event is sent when the drag-and-drop pointer leaves the * surface and the session ends. The client must destroy the * wl_data_offer introduced at enter time at this point. */ void (*leave)(void *data, struct wl_data_device *wl_data_device); /** * drag-and-drop session motion * * This event is sent when the drag-and-drop pointer moves within * the currently focused surface. The new position of the pointer * is provided by the x and y arguments, in surface-local * coordinates. * @param time timestamp with millisecond granularity * @param x surface-local x coordinate * @param y surface-local y coordinate */ void (*motion)(void *data, struct wl_data_device *wl_data_device, uint32_t time, wl_fixed_t x, wl_fixed_t y); /** * end drag-and-drop session successfully * * The event is sent when a drag-and-drop operation is ended * because the implicit grab is removed. * * The drag-and-drop destination is expected to honor the last * action received through wl_data_offer.action, if the resulting * action is "copy" or "move", the destination can still perform * wl_data_offer.receive requests, and is expected to end all * transfers with a wl_data_offer.finish request. * * If the resulting action is "ask", the action will not be * considered final. The drag-and-drop destination is expected to * perform one last wl_data_offer.set_actions request, or * wl_data_offer.destroy in order to cancel the operation. */ void (*drop)(void *data, struct wl_data_device *wl_data_device); /** * advertise new selection * * The selection event is sent out to notify the client of a new * wl_data_offer for the selection for this device. The * data_device.data_offer and the data_offer.offer events are sent * out immediately before this event to introduce the data offer * object. The selection event is sent to a client immediately * before receiving keyboard focus and when a new selection is set * while the client has keyboard focus. The data_offer is valid * until a new data_offer or NULL is received or until the client * loses keyboard focus. The client must destroy the previous * selection data_offer, if any, upon receiving this event. * @param id selection data_offer object */ void (*selection)(void *data, struct wl_data_device *wl_data_device, struct wl_data_offer *id); }; /** * @ingroup iface_wl_data_device */ static inline int wl_data_device_add_listener(struct wl_data_device *wl_data_device, const struct wl_data_device_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_data_device, (void (**)(void)) listener, data); } #define WL_DATA_DEVICE_START_DRAG 0 #define WL_DATA_DEVICE_SET_SELECTION 1 #define WL_DATA_DEVICE_RELEASE 2 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_DATA_OFFER_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_ENTER_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_LEAVE_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_MOTION_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_DROP_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_SELECTION_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_START_DRAG_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_SET_SELECTION_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device */ #define WL_DATA_DEVICE_RELEASE_SINCE_VERSION 2 /** @ingroup iface_wl_data_device */ static inline void wl_data_device_set_user_data(struct wl_data_device *wl_data_device, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_data_device, user_data); } /** @ingroup iface_wl_data_device */ static inline void * wl_data_device_get_user_data(struct wl_data_device *wl_data_device) { return wl_proxy_get_user_data((struct wl_proxy *) wl_data_device); } static inline uint32_t wl_data_device_get_version(struct wl_data_device *wl_data_device) { return wl_proxy_get_version((struct wl_proxy *) wl_data_device); } /** @ingroup iface_wl_data_device */ static inline void wl_data_device_destroy(struct wl_data_device *wl_data_device) { wl_proxy_destroy((struct wl_proxy *) wl_data_device); } /** * @ingroup iface_wl_data_device * * This request asks the compositor to start a drag-and-drop * operation on behalf of the client. * * The source argument is the data source that provides the data * for the eventual data transfer. If source is NULL, enter, leave * and motion events are sent only to the client that initiated the * drag and the client is expected to handle the data passing * internally. * * The origin surface is the surface where the drag originates and * the client must have an active implicit grab that matches the * serial. * * The icon surface is an optional (can be NULL) surface that * provides an icon to be moved around with the cursor. Initially, * the top-left corner of the icon surface is placed at the cursor * hotspot, but subsequent wl_surface.attach request can move the * relative position. Attach requests must be confirmed with * wl_surface.commit as usual. The icon surface is given the role of * a drag-and-drop icon. If the icon surface already has another role, * it raises a protocol error. * * The current and pending input regions of the icon wl_surface are * cleared, and wl_surface.set_input_region is ignored until the * wl_surface is no longer used as the icon surface. When the use * as an icon ends, the current and pending input regions become * undefined, and the wl_surface is unmapped. */ static inline void wl_data_device_start_drag(struct wl_data_device *wl_data_device, struct wl_data_source *source, struct wl_surface *origin, struct wl_surface *icon, uint32_t serial) { wl_proxy_marshal((struct wl_proxy *) wl_data_device, WL_DATA_DEVICE_START_DRAG, source, origin, icon, serial); } /** * @ingroup iface_wl_data_device * * This request asks the compositor to set the selection * to the data from the source on behalf of the client. * * To unset the selection, set the source to NULL. */ static inline void wl_data_device_set_selection(struct wl_data_device *wl_data_device, struct wl_data_source *source, uint32_t serial) { wl_proxy_marshal((struct wl_proxy *) wl_data_device, WL_DATA_DEVICE_SET_SELECTION, source, serial); } /** * @ingroup iface_wl_data_device * * This request destroys the data device. */ static inline void wl_data_device_release(struct wl_data_device *wl_data_device) { wl_proxy_marshal((struct wl_proxy *) wl_data_device, WL_DATA_DEVICE_RELEASE); wl_proxy_destroy((struct wl_proxy *) wl_data_device); } #ifndef WL_DATA_DEVICE_MANAGER_DND_ACTION_ENUM #define WL_DATA_DEVICE_MANAGER_DND_ACTION_ENUM /** * @ingroup iface_wl_data_device_manager * drag and drop actions * * This is a bitmask of the available/preferred actions in a * drag-and-drop operation. * * In the compositor, the selected action is a result of matching the * actions offered by the source and destination sides. "action" events * with a "none" action will be sent to both source and destination if * there is no match. All further checks will effectively happen on * (source actions ∩ destination actions). * * In addition, compositors may also pick different actions in * reaction to key modifiers being pressed. One common design that * is used in major toolkits (and the behavior recommended for * compositors) is: * * - If no modifiers are pressed, the first match (in bit order) * will be used. * - Pressing Shift selects "move", if enabled in the mask. * - Pressing Control selects "copy", if enabled in the mask. * * Behavior beyond that is considered implementation-dependent. * Compositors may for example bind other modifiers (like Alt/Meta) * or drags initiated with other buttons than BTN_LEFT to specific * actions (e.g. "ask"). */ enum wl_data_device_manager_dnd_action { /** * no action */ WL_DATA_DEVICE_MANAGER_DND_ACTION_NONE = 0, /** * copy action */ WL_DATA_DEVICE_MANAGER_DND_ACTION_COPY = 1, /** * move action */ WL_DATA_DEVICE_MANAGER_DND_ACTION_MOVE = 2, /** * ask action */ WL_DATA_DEVICE_MANAGER_DND_ACTION_ASK = 4, }; #endif /* WL_DATA_DEVICE_MANAGER_DND_ACTION_ENUM */ #define WL_DATA_DEVICE_MANAGER_CREATE_DATA_SOURCE 0 #define WL_DATA_DEVICE_MANAGER_GET_DATA_DEVICE 1 /** * @ingroup iface_wl_data_device_manager */ #define WL_DATA_DEVICE_MANAGER_CREATE_DATA_SOURCE_SINCE_VERSION 1 /** * @ingroup iface_wl_data_device_manager */ #define WL_DATA_DEVICE_MANAGER_GET_DATA_DEVICE_SINCE_VERSION 1 /** @ingroup iface_wl_data_device_manager */ static inline void wl_data_device_manager_set_user_data(struct wl_data_device_manager *wl_data_device_manager, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_data_device_manager, user_data); } /** @ingroup iface_wl_data_device_manager */ static inline void * wl_data_device_manager_get_user_data(struct wl_data_device_manager *wl_data_device_manager) { return wl_proxy_get_user_data((struct wl_proxy *) wl_data_device_manager); } static inline uint32_t wl_data_device_manager_get_version(struct wl_data_device_manager *wl_data_device_manager) { return wl_proxy_get_version((struct wl_proxy *) wl_data_device_manager); } /** @ingroup iface_wl_data_device_manager */ static inline void wl_data_device_manager_destroy(struct wl_data_device_manager *wl_data_device_manager) { wl_proxy_destroy((struct wl_proxy *) wl_data_device_manager); } /** * @ingroup iface_wl_data_device_manager * * Create a new data source. */ static inline struct wl_data_source * wl_data_device_manager_create_data_source(struct wl_data_device_manager *wl_data_device_manager) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_data_device_manager, WL_DATA_DEVICE_MANAGER_CREATE_DATA_SOURCE, &wl_data_source_interface, NULL); return (struct wl_data_source *) id; } /** * @ingroup iface_wl_data_device_manager * * Create a new data device for a given seat. */ static inline struct wl_data_device * wl_data_device_manager_get_data_device(struct wl_data_device_manager *wl_data_device_manager, struct wl_seat *seat) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_data_device_manager, WL_DATA_DEVICE_MANAGER_GET_DATA_DEVICE, &wl_data_device_interface, NULL, seat); return (struct wl_data_device *) id; } #ifndef WL_SHELL_ERROR_ENUM #define WL_SHELL_ERROR_ENUM enum wl_shell_error { /** * given wl_surface has another role */ WL_SHELL_ERROR_ROLE = 0, }; #endif /* WL_SHELL_ERROR_ENUM */ #define WL_SHELL_GET_SHELL_SURFACE 0 /** * @ingroup iface_wl_shell */ #define WL_SHELL_GET_SHELL_SURFACE_SINCE_VERSION 1 /** @ingroup iface_wl_shell */ static inline void wl_shell_set_user_data(struct wl_shell *wl_shell, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_shell, user_data); } /** @ingroup iface_wl_shell */ static inline void * wl_shell_get_user_data(struct wl_shell *wl_shell) { return wl_proxy_get_user_data((struct wl_proxy *) wl_shell); } static inline uint32_t wl_shell_get_version(struct wl_shell *wl_shell) { return wl_proxy_get_version((struct wl_proxy *) wl_shell); } /** @ingroup iface_wl_shell */ static inline void wl_shell_destroy(struct wl_shell *wl_shell) { wl_proxy_destroy((struct wl_proxy *) wl_shell); } /** * @ingroup iface_wl_shell * * Create a shell surface for an existing surface. This gives * the wl_surface the role of a shell surface. If the wl_surface * already has another role, it raises a protocol error. * * Only one shell surface can be associated with a given surface. */ static inline struct wl_shell_surface * wl_shell_get_shell_surface(struct wl_shell *wl_shell, struct wl_surface *surface) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_shell, WL_SHELL_GET_SHELL_SURFACE, &wl_shell_surface_interface, NULL, surface); return (struct wl_shell_surface *) id; } #ifndef WL_SHELL_SURFACE_RESIZE_ENUM #define WL_SHELL_SURFACE_RESIZE_ENUM /** * @ingroup iface_wl_shell_surface * edge values for resizing * * These values are used to indicate which edge of a surface * is being dragged in a resize operation. The server may * use this information to adapt its behavior, e.g. choose * an appropriate cursor image. */ enum wl_shell_surface_resize { /** * no edge */ WL_SHELL_SURFACE_RESIZE_NONE = 0, /** * top edge */ WL_SHELL_SURFACE_RESIZE_TOP = 1, /** * bottom edge */ WL_SHELL_SURFACE_RESIZE_BOTTOM = 2, /** * left edge */ WL_SHELL_SURFACE_RESIZE_LEFT = 4, /** * top and left edges */ WL_SHELL_SURFACE_RESIZE_TOP_LEFT = 5, /** * bottom and left edges */ WL_SHELL_SURFACE_RESIZE_BOTTOM_LEFT = 6, /** * right edge */ WL_SHELL_SURFACE_RESIZE_RIGHT = 8, /** * top and right edges */ WL_SHELL_SURFACE_RESIZE_TOP_RIGHT = 9, /** * bottom and right edges */ WL_SHELL_SURFACE_RESIZE_BOTTOM_RIGHT = 10, }; #endif /* WL_SHELL_SURFACE_RESIZE_ENUM */ #ifndef WL_SHELL_SURFACE_TRANSIENT_ENUM #define WL_SHELL_SURFACE_TRANSIENT_ENUM /** * @ingroup iface_wl_shell_surface * details of transient behaviour * * These flags specify details of the expected behaviour * of transient surfaces. Used in the set_transient request. */ enum wl_shell_surface_transient { /** * do not set keyboard focus */ WL_SHELL_SURFACE_TRANSIENT_INACTIVE = 0x1, }; #endif /* WL_SHELL_SURFACE_TRANSIENT_ENUM */ #ifndef WL_SHELL_SURFACE_FULLSCREEN_METHOD_ENUM #define WL_SHELL_SURFACE_FULLSCREEN_METHOD_ENUM /** * @ingroup iface_wl_shell_surface * different method to set the surface fullscreen * * Hints to indicate to the compositor how to deal with a conflict * between the dimensions of the surface and the dimensions of the * output. The compositor is free to ignore this parameter. */ enum wl_shell_surface_fullscreen_method { /** * no preference, apply default policy */ WL_SHELL_SURFACE_FULLSCREEN_METHOD_DEFAULT = 0, /** * scale, preserve the surface's aspect ratio and center on output */ WL_SHELL_SURFACE_FULLSCREEN_METHOD_SCALE = 1, /** * switch output mode to the smallest mode that can fit the surface, add black borders to compensate size mismatch */ WL_SHELL_SURFACE_FULLSCREEN_METHOD_DRIVER = 2, /** * no upscaling, center on output and add black borders to compensate size mismatch */ WL_SHELL_SURFACE_FULLSCREEN_METHOD_FILL = 3, }; #endif /* WL_SHELL_SURFACE_FULLSCREEN_METHOD_ENUM */ /** * @ingroup iface_wl_shell_surface * @struct wl_shell_surface_listener */ struct wl_shell_surface_listener { /** * ping client * * Ping a client to check if it is receiving events and sending * requests. A client is expected to reply with a pong request. * @param serial serial number of the ping */ void (*ping)(void *data, struct wl_shell_surface *wl_shell_surface, uint32_t serial); /** * suggest resize * * The configure event asks the client to resize its surface. * * 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). * * The edges parameter provides a hint about how the surface was * resized. The client may use this information to decide how to * adjust its content to the new size (e.g. a scrolling area might * adjust its content position to leave the viewable content * unmoved). * * 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. * @param edges how the surface was resized * @param width new width of the surface * @param height new height of the surface */ void (*configure)(void *data, struct wl_shell_surface *wl_shell_surface, uint32_t edges, int32_t width, int32_t height); /** * popup interaction is done * * The popup_done event is sent out when a popup grab is broken, * that is, when the user clicks a surface that doesn't belong to * the client owning the popup surface. */ void (*popup_done)(void *data, struct wl_shell_surface *wl_shell_surface); }; /** * @ingroup iface_wl_shell_surface */ static inline int wl_shell_surface_add_listener(struct wl_shell_surface *wl_shell_surface, const struct wl_shell_surface_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_shell_surface, (void (**)(void)) listener, data); } #define WL_SHELL_SURFACE_PONG 0 #define WL_SHELL_SURFACE_MOVE 1 #define WL_SHELL_SURFACE_RESIZE 2 #define WL_SHELL_SURFACE_SET_TOPLEVEL 3 #define WL_SHELL_SURFACE_SET_TRANSIENT 4 #define WL_SHELL_SURFACE_SET_FULLSCREEN 5 #define WL_SHELL_SURFACE_SET_POPUP 6 #define WL_SHELL_SURFACE_SET_MAXIMIZED 7 #define WL_SHELL_SURFACE_SET_TITLE 8 #define WL_SHELL_SURFACE_SET_CLASS 9 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_PING_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_CONFIGURE_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_POPUP_DONE_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_PONG_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_MOVE_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_RESIZE_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_TOPLEVEL_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_TRANSIENT_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_FULLSCREEN_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_POPUP_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_MAXIMIZED_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_TITLE_SINCE_VERSION 1 /** * @ingroup iface_wl_shell_surface */ #define WL_SHELL_SURFACE_SET_CLASS_SINCE_VERSION 1 /** @ingroup iface_wl_shell_surface */ static inline void wl_shell_surface_set_user_data(struct wl_shell_surface *wl_shell_surface, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_shell_surface, user_data); } /** @ingroup iface_wl_shell_surface */ static inline void * wl_shell_surface_get_user_data(struct wl_shell_surface *wl_shell_surface) { return wl_proxy_get_user_data((struct wl_proxy *) wl_shell_surface); } static inline uint32_t wl_shell_surface_get_version(struct wl_shell_surface *wl_shell_surface) { return wl_proxy_get_version((struct wl_proxy *) wl_shell_surface); } /** @ingroup iface_wl_shell_surface */ static inline void wl_shell_surface_destroy(struct wl_shell_surface *wl_shell_surface) { wl_proxy_destroy((struct wl_proxy *) wl_shell_surface); } /** * @ingroup iface_wl_shell_surface * * A client must respond to a ping event with a pong request or * the client may be deemed unresponsive. */ static inline void wl_shell_surface_pong(struct wl_shell_surface *wl_shell_surface, uint32_t serial) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_PONG, serial); } /** * @ingroup iface_wl_shell_surface * * Start a pointer-driven move of the surface. * * This request must be used in response to a button press event. * The server may ignore move requests depending on the state of * the surface (e.g. fullscreen or maximized). */ static inline void wl_shell_surface_move(struct wl_shell_surface *wl_shell_surface, struct wl_seat *seat, uint32_t serial) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_MOVE, seat, serial); } /** * @ingroup iface_wl_shell_surface * * Start a pointer-driven resizing of the surface. * * This request must be used in response to a button press event. * The server may ignore resize requests depending on the state of * the surface (e.g. fullscreen or maximized). */ static inline void wl_shell_surface_resize(struct wl_shell_surface *wl_shell_surface, struct wl_seat *seat, uint32_t serial, uint32_t edges) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_RESIZE, seat, serial, edges); } /** * @ingroup iface_wl_shell_surface * * Map the surface as a toplevel surface. * * A toplevel surface is not fullscreen, maximized or transient. */ static inline void wl_shell_surface_set_toplevel(struct wl_shell_surface *wl_shell_surface) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_TOPLEVEL); } /** * @ingroup iface_wl_shell_surface * * Map the surface relative to an existing surface. * * The x and y arguments specify the location of the upper left * corner of the surface relative to the upper left corner of the * parent surface, in surface-local coordinates. * * The flags argument controls details of the transient behaviour. */ static inline void wl_shell_surface_set_transient(struct wl_shell_surface *wl_shell_surface, struct wl_surface *parent, int32_t x, int32_t y, uint32_t flags) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_TRANSIENT, parent, x, y, flags); } /** * @ingroup iface_wl_shell_surface * * Map the surface as a fullscreen surface. * * If an output parameter is given then the surface will be made * fullscreen on that output. If the client does not specify the * output then the compositor will apply its policy - usually * choosing the output on which the surface has the biggest surface * area. * * The client may specify a method to resolve a size conflict * between the output size and the surface size - this is provided * through the method parameter. * * The framerate parameter is used only when the method is set * to "driver", to indicate the preferred framerate. A value of 0 * indicates that the client does not care about framerate. The * framerate is specified in mHz, that is framerate of 60000 is 60Hz. * * A method of "scale" or "driver" implies a scaling operation of * the surface, either via a direct scaling operation or a change of * the output mode. This will override any kind of output scaling, so * that mapping a surface with a buffer size equal to the mode can * fill the screen independent of buffer_scale. * * A method of "fill" means we don't scale up the buffer, however * any output scale is applied. This means that you may run into * an edge case where the application maps a buffer with the same * size of the output mode but buffer_scale 1 (thus making a * surface larger than the output). In this case it is allowed to * downscale the results to fit the screen. * * The compositor must reply to this request with a configure event * with the dimensions for the output on which the surface will * be made fullscreen. */ static inline void wl_shell_surface_set_fullscreen(struct wl_shell_surface *wl_shell_surface, uint32_t method, uint32_t framerate, struct wl_output *output) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_FULLSCREEN, method, framerate, output); } /** * @ingroup iface_wl_shell_surface * * Map the surface as a popup. * * A popup surface is a transient surface with an added pointer * grab. * * An existing implicit grab will be changed to owner-events mode, * and the popup grab will continue after the implicit grab ends * (i.e. releasing the mouse button does not cause the popup to * be unmapped). * * The popup grab continues until the window is destroyed or a * mouse button is pressed in any other client's window. A click * in any of the client's surfaces is reported as normal, however, * clicks in other clients' surfaces will be discarded and trigger * the callback. * * The x and y arguments specify the location of the upper left * corner of the surface relative to the upper left corner of the * parent surface, in surface-local coordinates. */ static inline void wl_shell_surface_set_popup(struct wl_shell_surface *wl_shell_surface, struct wl_seat *seat, uint32_t serial, struct wl_surface *parent, int32_t x, int32_t y, uint32_t flags) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_POPUP, seat, serial, parent, x, y, flags); } /** * @ingroup iface_wl_shell_surface * * Map the surface as a maximized surface. * * If an output parameter is given then the surface will be * maximized on that output. If the client does not specify the * output then the compositor will apply its policy - usually * choosing the output on which the surface has the biggest surface * area. * * The compositor will reply with a configure event telling * the expected new surface size. The operation is completed * on the next buffer attach to this surface. * * A maximized surface typically fills the entire output it is * bound to, except for desktop elements such as panels. This is * the main difference between a maximized shell surface and a * fullscreen shell surface. * * The details depend on the compositor implementation. */ static inline void wl_shell_surface_set_maximized(struct wl_shell_surface *wl_shell_surface, struct wl_output *output) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_MAXIMIZED, output); } /** * @ingroup iface_wl_shell_surface * * 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. */ static inline void wl_shell_surface_set_title(struct wl_shell_surface *wl_shell_surface, const char *title) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_TITLE, title); } /** * @ingroup iface_wl_shell_surface * * Set a class for the surface. * * The surface class identifies the general class of applications * to which the surface belongs. A common convention is to use the * file name (or the full path if it is a non-standard location) of * the application's .desktop file as the class. */ static inline void wl_shell_surface_set_class(struct wl_shell_surface *wl_shell_surface, const char *class_) { wl_proxy_marshal((struct wl_proxy *) wl_shell_surface, WL_SHELL_SURFACE_SET_CLASS, class_); } #ifndef WL_SURFACE_ERROR_ENUM #define WL_SURFACE_ERROR_ENUM /** * @ingroup iface_wl_surface * wl_surface error values * * These errors can be emitted in response to wl_surface requests. */ enum wl_surface_error { /** * buffer scale value is invalid */ WL_SURFACE_ERROR_INVALID_SCALE = 0, /** * buffer transform value is invalid */ WL_SURFACE_ERROR_INVALID_TRANSFORM = 1, }; #endif /* WL_SURFACE_ERROR_ENUM */ /** * @ingroup iface_wl_surface * @struct wl_surface_listener */ struct wl_surface_listener { /** * surface enters an output * * This is emitted whenever a surface's creation, movement, or * resizing results in some part of it being within the scanout * region of an output. * * Note that a surface may be overlapping with zero or more * outputs. * @param output output entered by the surface */ void (*enter)(void *data, struct wl_surface *wl_surface, struct wl_output *output); /** * surface leaves an output * * This is emitted whenever a surface's creation, movement, or * resizing results in it no longer having any part of it within * the scanout region of an output. * @param output output left by the surface */ void (*leave)(void *data, struct wl_surface *wl_surface, struct wl_output *output); }; /** * @ingroup iface_wl_surface */ static inline int wl_surface_add_listener(struct wl_surface *wl_surface, const struct wl_surface_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_surface, (void (**)(void)) listener, data); } #define WL_SURFACE_DESTROY 0 #define WL_SURFACE_ATTACH 1 #define WL_SURFACE_DAMAGE 2 #define WL_SURFACE_FRAME 3 #define WL_SURFACE_SET_OPAQUE_REGION 4 #define WL_SURFACE_SET_INPUT_REGION 5 #define WL_SURFACE_COMMIT 6 #define WL_SURFACE_SET_BUFFER_TRANSFORM 7 #define WL_SURFACE_SET_BUFFER_SCALE 8 #define WL_SURFACE_DAMAGE_BUFFER 9 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_ENTER_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_LEAVE_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_ATTACH_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_DAMAGE_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_FRAME_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_SET_OPAQUE_REGION_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_SET_INPUT_REGION_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_COMMIT_SINCE_VERSION 1 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_SET_BUFFER_TRANSFORM_SINCE_VERSION 2 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_SET_BUFFER_SCALE_SINCE_VERSION 3 /** * @ingroup iface_wl_surface */ #define WL_SURFACE_DAMAGE_BUFFER_SINCE_VERSION 4 /** @ingroup iface_wl_surface */ static inline void wl_surface_set_user_data(struct wl_surface *wl_surface, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_surface, user_data); } /** @ingroup iface_wl_surface */ static inline void * wl_surface_get_user_data(struct wl_surface *wl_surface) { return wl_proxy_get_user_data((struct wl_proxy *) wl_surface); } static inline uint32_t wl_surface_get_version(struct wl_surface *wl_surface) { return wl_proxy_get_version((struct wl_proxy *) wl_surface); } /** * @ingroup iface_wl_surface * * Deletes the surface and invalidates its object ID. */ static inline void wl_surface_destroy(struct wl_surface *wl_surface) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_surface); } /** * @ingroup iface_wl_surface * * Set a buffer as the content of this surface. * * The new size of the surface is calculated based on the buffer * size transformed by the inverse buffer_transform and the * inverse buffer_scale. This means that the supplied buffer * must be an integer multiple of the buffer_scale. * * The x and y arguments specify the location of the new pending * buffer's upper left corner, relative to the current buffer's upper * left corner, in surface-local coordinates. In other words, the * x and y, combined with the new surface size define in which * directions the surface's size changes. * * Surface contents are double-buffered state, see wl_surface.commit. * * The initial surface contents are void; there is no content. * wl_surface.attach assigns the given wl_buffer as the pending * wl_buffer. wl_surface.commit makes the pending wl_buffer the new * surface contents, and the size of the surface becomes the size * calculated from the wl_buffer, as described above. After commit, * there is no pending buffer until the next attach. * * Committing a pending wl_buffer allows the compositor to read the * pixels in the wl_buffer. The compositor may access the pixels at * any time after the wl_surface.commit request. When the compositor * will not access the pixels anymore, it will send the * wl_buffer.release event. Only after receiving wl_buffer.release, * the client may reuse the wl_buffer. A wl_buffer that has been * attached and then replaced by another attach instead of committed * will not receive a release event, and is not used by the * compositor. * * Destroying the wl_buffer after wl_buffer.release does not change * the surface contents. However, if the client destroys the * wl_buffer before receiving the wl_buffer.release event, the surface * contents become undefined immediately. * * If wl_surface.attach is sent with a NULL wl_buffer, the * following wl_surface.commit will remove the surface content. */ static inline void wl_surface_attach(struct wl_surface *wl_surface, struct wl_buffer *buffer, int32_t x, int32_t y) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_ATTACH, buffer, x, y); } /** * @ingroup iface_wl_surface * * This request is used to describe the regions where the pending * buffer is different from the current surface contents, and where * the surface therefore needs to be repainted. The compositor * ignores the parts of the damage that fall outside of the surface. * * Damage is double-buffered state, see wl_surface.commit. * * The damage rectangle is specified in surface-local coordinates, * where x and y specify the upper left corner of the damage rectangle. * * The initial value for pending damage is empty: no damage. * wl_surface.damage adds pending damage: the new pending damage * is the union of old pending damage and the given rectangle. * * wl_surface.commit assigns pending damage as the current damage, * and clears pending damage. The server will clear the current * damage as it repaints the surface. * * Alternatively, damage can be posted with wl_surface.damage_buffer * which uses buffer coordinates instead of surface coordinates, * and is probably the preferred and intuitive way of doing this. */ static inline void wl_surface_damage(struct wl_surface *wl_surface, int32_t x, int32_t y, int32_t width, int32_t height) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_DAMAGE, x, y, width, height); } /** * @ingroup iface_wl_surface * * Request a notification when it is a good time to start drawing a new * frame, by creating a frame callback. This is useful for throttling * redrawing operations, and driving animations. * * When a client is animating on a wl_surface, it can use the 'frame' * request to get notified when it is a good time to draw and commit the * next frame of animation. If the client commits an update earlier than * that, it is likely that some updates will not make it to the display, * and the client is wasting resources by drawing too often. * * The frame request will take effect on the next wl_surface.commit. * The notification will only be posted for one frame unless * requested again. For a wl_surface, the notifications are posted in * the order the frame requests were committed. * * The server must send the notifications so that a client * will not send excessive updates, while still allowing * the highest possible update rate for clients that wait for the reply * before drawing again. The server should give some time for the client * to draw and commit after sending the frame callback events to let it * hit the next output refresh. * * A server should avoid signaling the frame callbacks if the * surface is not visible in any way, e.g. the surface is off-screen, * or completely obscured by other opaque surfaces. * * The object returned by this request will be destroyed by the * compositor after the callback is fired and as such the client must not * attempt to use it after that point. * * The callback_data passed in the callback is the current time, in * milliseconds, with an undefined base. */ static inline struct wl_callback * wl_surface_frame(struct wl_surface *wl_surface) { struct wl_proxy *callback; callback = wl_proxy_marshal_constructor((struct wl_proxy *) wl_surface, WL_SURFACE_FRAME, &wl_callback_interface, NULL); return (struct wl_callback *) callback; } /** * @ingroup iface_wl_surface * * This request sets the region of the surface that contains * opaque content. * * The opaque region is an optimization hint for the compositor * that lets it optimize the redrawing of content behind opaque * regions. Setting an opaque region is not required for correct * behaviour, but marking transparent content as opaque will result * in repaint artifacts. * * The opaque region is specified in surface-local coordinates. * * The compositor ignores the parts of the opaque region that fall * outside of the surface. * * Opaque region is double-buffered state, see wl_surface.commit. * * wl_surface.set_opaque_region changes the pending opaque region. * wl_surface.commit copies the pending region to the current region. * Otherwise, the pending and current regions are never changed. * * The initial value for an opaque region is empty. Setting the pending * opaque region has copy semantics, and the wl_region object can be * destroyed immediately. A NULL wl_region causes the pending opaque * region to be set to empty. */ static inline void wl_surface_set_opaque_region(struct wl_surface *wl_surface, struct wl_region *region) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_SET_OPAQUE_REGION, region); } /** * @ingroup iface_wl_surface * * This request sets the region of the surface that can receive * pointer and touch events. * * Input events happening outside of this region will try the next * surface in the server surface stack. The compositor ignores the * parts of the input region that fall outside of the surface. * * The input region is specified in surface-local coordinates. * * Input region is double-buffered state, see wl_surface.commit. * * wl_surface.set_input_region changes the pending input region. * wl_surface.commit copies the pending region to the current region. * Otherwise the pending and current regions are never changed, * except cursor and icon surfaces are special cases, see * wl_pointer.set_cursor and wl_data_device.start_drag. * * The initial value for an input region is infinite. That means the * whole surface will accept input. Setting the pending input region * has copy semantics, and the wl_region object can be destroyed * immediately. A NULL wl_region causes the input region to be set * to infinite. */ static inline void wl_surface_set_input_region(struct wl_surface *wl_surface, struct wl_region *region) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_SET_INPUT_REGION, region); } /** * @ingroup iface_wl_surface * * Surface state (input, opaque, and damage regions, attached buffers, * etc.) is double-buffered. Protocol requests modify the pending state, * as opposed to the current state in use by the compositor. A commit * request atomically applies all pending state, replacing the current * state. After commit, the new pending state is as documented for each * related request. * * On commit, a pending wl_buffer is applied first, and all other state * second. This means that all coordinates in double-buffered state are * relative to the new wl_buffer coming into use, except for * wl_surface.attach itself. If there is no pending wl_buffer, the * coordinates are relative to the current surface contents. * * All requests that need a commit to become effective are documented * to affect double-buffered state. * * Other interfaces may add further double-buffered surface state. */ static inline void wl_surface_commit(struct wl_surface *wl_surface) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_COMMIT); } /** * @ingroup iface_wl_surface * * This request sets an optional transformation on how the compositor * interprets the contents of the buffer attached to the surface. The * accepted values for the transform parameter are the values for * wl_output.transform. * * Buffer transform is double-buffered state, see wl_surface.commit. * * A newly created surface has its buffer transformation set to normal. * * wl_surface.set_buffer_transform changes the pending buffer * transformation. wl_surface.commit copies the pending buffer * transformation to the current one. Otherwise, the pending and current * values are never changed. * * The purpose of this request is to allow clients to render content * according to the output transform, thus permitting the compositor to * use certain optimizations even if the display is rotated. Using * hardware overlays and scanning out a client buffer for fullscreen * surfaces are examples of such optimizations. Those optimizations are * highly dependent on the compositor implementation, so the use of this * request should be considered on a case-by-case basis. * * Note that if the transform value includes 90 or 270 degree rotation, * the width of the buffer will become the surface height and the height * of the buffer will become the surface width. * * If transform is not one of the values from the * wl_output.transform enum the invalid_transform protocol error * is raised. */ static inline void wl_surface_set_buffer_transform(struct wl_surface *wl_surface, int32_t transform) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_SET_BUFFER_TRANSFORM, transform); } /** * @ingroup iface_wl_surface * * This request sets an optional scaling factor on how the compositor * interprets the contents of the buffer attached to the window. * * Buffer scale is double-buffered state, see wl_surface.commit. * * A newly created surface has its buffer scale set to 1. * * wl_surface.set_buffer_scale changes the pending buffer scale. * wl_surface.commit copies the pending buffer scale to the current one. * Otherwise, the pending and current values are never changed. * * The purpose of this request is to allow clients to supply higher * resolution buffer data for use on high resolution outputs. It is * intended that you pick the same buffer scale as the scale of the * output that the surface is displayed on. This means the compositor * can avoid scaling when rendering the surface on that output. * * Note that if the scale is larger than 1, then you have to attach * a buffer that is larger (by a factor of scale in each dimension) * than the desired surface size. * * If scale is not positive the invalid_scale protocol error is * raised. */ static inline void wl_surface_set_buffer_scale(struct wl_surface *wl_surface, int32_t scale) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_SET_BUFFER_SCALE, scale); } /** * @ingroup iface_wl_surface * * This request is used to describe the regions where the pending * buffer is different from the current surface contents, and where * the surface therefore needs to be repainted. The compositor * ignores the parts of the damage that fall outside of the surface. * * Damage is double-buffered state, see wl_surface.commit. * * The damage rectangle is specified in buffer coordinates, * where x and y specify the upper left corner of the damage rectangle. * * The initial value for pending damage is empty: no damage. * wl_surface.damage_buffer adds pending damage: the new pending * damage is the union of old pending damage and the given rectangle. * * wl_surface.commit assigns pending damage as the current damage, * and clears pending damage. The server will clear the current * damage as it repaints the surface. * * This request differs from wl_surface.damage in only one way - it * takes damage in buffer coordinates instead of surface-local * coordinates. While this generally is more intuitive than surface * coordinates, it is especially desirable when using wp_viewport * or when a drawing library (like EGL) is unaware of buffer scale * and buffer transform. * * Note: Because buffer transformation changes and damage requests may * be interleaved in the protocol stream, it is impossible to determine * the actual mapping between surface and buffer damage until * wl_surface.commit time. Therefore, compositors wishing to take both * kinds of damage into account will have to accumulate damage from the * two requests separately and only transform from one to the other * after receiving the wl_surface.commit. */ static inline void wl_surface_damage_buffer(struct wl_surface *wl_surface, int32_t x, int32_t y, int32_t width, int32_t height) { wl_proxy_marshal((struct wl_proxy *) wl_surface, WL_SURFACE_DAMAGE_BUFFER, x, y, width, height); } #ifndef WL_SEAT_CAPABILITY_ENUM #define WL_SEAT_CAPABILITY_ENUM /** * @ingroup iface_wl_seat * seat capability bitmask * * This is a bitmask of capabilities this seat has; if a member is * set, then it is present on the seat. */ enum wl_seat_capability { /** * the seat has pointer devices */ WL_SEAT_CAPABILITY_POINTER = 1, /** * the seat has one or more keyboards */ WL_SEAT_CAPABILITY_KEYBOARD = 2, /** * the seat has touch devices */ WL_SEAT_CAPABILITY_TOUCH = 4, }; #endif /* WL_SEAT_CAPABILITY_ENUM */ /** * @ingroup iface_wl_seat * @struct wl_seat_listener */ struct wl_seat_listener { /** * seat capabilities changed * * This is emitted whenever a seat gains or loses the pointer, * keyboard or touch capabilities. The argument is a capability * enum containing the complete set of capabilities this seat has. * * When the pointer capability is added, a client may create a * wl_pointer object using the wl_seat.get_pointer request. This * object will receive pointer events until the capability is * removed in the future. * * When the pointer capability is removed, a client should destroy * the wl_pointer objects associated with the seat where the * capability was removed, using the wl_pointer.release request. No * further pointer events will be received on these objects. * * In some compositors, if a seat regains the pointer capability * and a client has a previously obtained wl_pointer object of * version 4 or less, that object may start sending pointer events * again. This behavior is considered a misinterpretation of the * intended behavior and must not be relied upon by the client. * wl_pointer objects of version 5 or later must not send events if * created before the most recent event notifying the client of an * added pointer capability. * * The above behavior also applies to wl_keyboard and wl_touch with * the keyboard and touch capabilities, respectively. * @param capabilities capabilities of the seat */ void (*capabilities)(void *data, struct wl_seat *wl_seat, uint32_t capabilities); /** * unique identifier for this seat * * In a multiseat configuration this can be used by the client to * help identify which physical devices the seat represents. Based * on the seat configuration used by the compositor. * @param name seat identifier * @since 2 */ void (*name)(void *data, struct wl_seat *wl_seat, const char *name); }; /** * @ingroup iface_wl_seat */ static inline int wl_seat_add_listener(struct wl_seat *wl_seat, const struct wl_seat_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_seat, (void (**)(void)) listener, data); } #define WL_SEAT_GET_POINTER 0 #define WL_SEAT_GET_KEYBOARD 1 #define WL_SEAT_GET_TOUCH 2 #define WL_SEAT_RELEASE 3 /** * @ingroup iface_wl_seat */ #define WL_SEAT_CAPABILITIES_SINCE_VERSION 1 /** * @ingroup iface_wl_seat */ #define WL_SEAT_NAME_SINCE_VERSION 2 /** * @ingroup iface_wl_seat */ #define WL_SEAT_GET_POINTER_SINCE_VERSION 1 /** * @ingroup iface_wl_seat */ #define WL_SEAT_GET_KEYBOARD_SINCE_VERSION 1 /** * @ingroup iface_wl_seat */ #define WL_SEAT_GET_TOUCH_SINCE_VERSION 1 /** * @ingroup iface_wl_seat */ #define WL_SEAT_RELEASE_SINCE_VERSION 5 /** @ingroup iface_wl_seat */ static inline void wl_seat_set_user_data(struct wl_seat *wl_seat, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_seat, user_data); } /** @ingroup iface_wl_seat */ static inline void * wl_seat_get_user_data(struct wl_seat *wl_seat) { return wl_proxy_get_user_data((struct wl_proxy *) wl_seat); } static inline uint32_t wl_seat_get_version(struct wl_seat *wl_seat) { return wl_proxy_get_version((struct wl_proxy *) wl_seat); } /** @ingroup iface_wl_seat */ static inline void wl_seat_destroy(struct wl_seat *wl_seat) { wl_proxy_destroy((struct wl_proxy *) wl_seat); } /** * @ingroup iface_wl_seat * * The ID provided will be initialized to the wl_pointer interface * for this seat. * * This request only takes effect if the seat has the pointer * capability, or has had the pointer capability in the past. * It is a protocol violation to issue this request on a seat that has * never had the pointer capability. */ static inline struct wl_pointer * wl_seat_get_pointer(struct wl_seat *wl_seat) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_seat, WL_SEAT_GET_POINTER, &wl_pointer_interface, NULL); return (struct wl_pointer *) id; } /** * @ingroup iface_wl_seat * * The ID provided will be initialized to the wl_keyboard interface * for this seat. * * This request only takes effect if the seat has the keyboard * capability, or has had the keyboard capability in the past. * It is a protocol violation to issue this request on a seat that has * never had the keyboard capability. */ static inline struct wl_keyboard * wl_seat_get_keyboard(struct wl_seat *wl_seat) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_seat, WL_SEAT_GET_KEYBOARD, &wl_keyboard_interface, NULL); return (struct wl_keyboard *) id; } /** * @ingroup iface_wl_seat * * The ID provided will be initialized to the wl_touch interface * for this seat. * * This request only takes effect if the seat has the touch * capability, or has had the touch capability in the past. * It is a protocol violation to issue this request on a seat that has * never had the touch capability. */ static inline struct wl_touch * wl_seat_get_touch(struct wl_seat *wl_seat) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_seat, WL_SEAT_GET_TOUCH, &wl_touch_interface, NULL); return (struct wl_touch *) id; } /** * @ingroup iface_wl_seat * * Using this request a client can tell the server that it is not going to * use the seat object anymore. */ static inline void wl_seat_release(struct wl_seat *wl_seat) { wl_proxy_marshal((struct wl_proxy *) wl_seat, WL_SEAT_RELEASE); wl_proxy_destroy((struct wl_proxy *) wl_seat); } #ifndef WL_POINTER_ERROR_ENUM #define WL_POINTER_ERROR_ENUM enum wl_pointer_error { /** * given wl_surface has another role */ WL_POINTER_ERROR_ROLE = 0, }; #endif /* WL_POINTER_ERROR_ENUM */ #ifndef WL_POINTER_BUTTON_STATE_ENUM #define WL_POINTER_BUTTON_STATE_ENUM /** * @ingroup iface_wl_pointer * physical button state * * Describes the physical state of a button that produced the button * event. */ enum wl_pointer_button_state { /** * the button is not pressed */ WL_POINTER_BUTTON_STATE_RELEASED = 0, /** * the button is pressed */ WL_POINTER_BUTTON_STATE_PRESSED = 1, }; #endif /* WL_POINTER_BUTTON_STATE_ENUM */ #ifndef WL_POINTER_AXIS_ENUM #define WL_POINTER_AXIS_ENUM /** * @ingroup iface_wl_pointer * axis types * * Describes the axis types of scroll events. */ enum wl_pointer_axis { /** * vertical axis */ WL_POINTER_AXIS_VERTICAL_SCROLL = 0, /** * horizontal axis */ WL_POINTER_AXIS_HORIZONTAL_SCROLL = 1, }; #endif /* WL_POINTER_AXIS_ENUM */ #ifndef WL_POINTER_AXIS_SOURCE_ENUM #define WL_POINTER_AXIS_SOURCE_ENUM /** * @ingroup iface_wl_pointer * axis source types * * Describes the source types for axis events. This indicates to the * client how an axis event was physically generated; a client may * adjust the user interface accordingly. For example, scroll events * from a "finger" source may be in a smooth coordinate space with * kinetic scrolling whereas a "wheel" source may be in discrete steps * of a number of lines. * * The "continuous" axis source is a device generating events in a * continuous coordinate space, but using something other than a * finger. One example for this source is button-based scrolling where * the vertical motion of a device is converted to scroll events while * a button is held down. * * The "wheel tilt" axis source indicates that the actual device is a * wheel but the scroll event is not caused by a rotation but a * (usually sideways) tilt of the wheel. */ enum wl_pointer_axis_source { /** * a physical wheel rotation */ WL_POINTER_AXIS_SOURCE_WHEEL = 0, /** * finger on a touch surface */ WL_POINTER_AXIS_SOURCE_FINGER = 1, /** * continuous coordinate space */ WL_POINTER_AXIS_SOURCE_CONTINUOUS = 2, /** * a physical wheel tilt * @since 6 */ WL_POINTER_AXIS_SOURCE_WHEEL_TILT = 3, }; /** * @ingroup iface_wl_pointer */ #define WL_POINTER_AXIS_SOURCE_WHEEL_TILT_SINCE_VERSION 6 #endif /* WL_POINTER_AXIS_SOURCE_ENUM */ /** * @ingroup iface_wl_pointer * @struct wl_pointer_listener */ struct wl_pointer_listener { /** * enter event * * Notification that this seat's pointer is focused on a certain * surface. * * When a seat's focus enters a surface, the pointer image is * undefined and a client should respond to this event by setting * an appropriate pointer image with the set_cursor request. * @param serial serial number of the enter event * @param surface surface entered by the pointer * @param surface_x surface-local x coordinate * @param surface_y surface-local y coordinate */ void (*enter)(void *data, struct wl_pointer *wl_pointer, uint32_t serial, struct wl_surface *surface, wl_fixed_t surface_x, wl_fixed_t surface_y); /** * leave event * * Notification that this seat's pointer is no longer focused on * a certain surface. * * The leave notification is sent before the enter notification for * the new focus. * @param serial serial number of the leave event * @param surface surface left by the pointer */ void (*leave)(void *data, struct wl_pointer *wl_pointer, uint32_t serial, struct wl_surface *surface); /** * pointer motion event * * Notification of pointer location change. The arguments * surface_x and surface_y are the location relative to the focused * surface. * @param time timestamp with millisecond granularity * @param surface_x surface-local x coordinate * @param surface_y surface-local y coordinate */ void (*motion)(void *data, struct wl_pointer *wl_pointer, uint32_t time, wl_fixed_t surface_x, wl_fixed_t surface_y); /** * pointer button event * * Mouse button click and release notifications. * * The location of the click is given by the last motion or enter * event. The time argument is a timestamp with millisecond * granularity, with an undefined base. * * The button is a button code as defined in the Linux kernel's * linux/input-event-codes.h header file, e.g. BTN_LEFT. * * Any 16-bit button code value is reserved for future additions to * the kernel's event code list. All other button codes above * 0xFFFF are currently undefined but may be used in future * versions of this protocol. * @param serial serial number of the button event * @param time timestamp with millisecond granularity * @param button button that produced the event * @param state physical state of the button */ void (*button)(void *data, struct wl_pointer *wl_pointer, uint32_t serial, uint32_t time, uint32_t button, uint32_t state); /** * axis event * * Scroll and other axis notifications. * * For scroll events (vertical and horizontal scroll axes), the * value parameter is the length of a vector along the specified * axis in a coordinate space identical to those of motion events, * representing a relative movement along the specified axis. * * For devices that support movements non-parallel to axes multiple * axis events will be emitted. * * When applicable, for example for touch pads, the server can * choose to emit scroll events where the motion vector is * equivalent to a motion event vector. * * When applicable, a client can transform its content relative to * the scroll distance. * @param time timestamp with millisecond granularity * @param axis axis type * @param value length of vector in surface-local coordinate space */ void (*axis)(void *data, struct wl_pointer *wl_pointer, uint32_t time, uint32_t axis, wl_fixed_t value); /** * end of a pointer event sequence * * Indicates the end of a set of events that logically belong * together. A client is expected to accumulate the data in all * events within the frame before proceeding. * * All wl_pointer events before a wl_pointer.frame event belong * logically together. For example, in a diagonal scroll motion the * compositor will send an optional wl_pointer.axis_source event, * two wl_pointer.axis events (horizontal and vertical) and finally * a wl_pointer.frame event. The client may use this information to * calculate a diagonal vector for scrolling. * * When multiple wl_pointer.axis events occur within the same * frame, the motion vector is the combined motion of all events. * When a wl_pointer.axis and a wl_pointer.axis_stop event occur * within the same frame, this indicates that axis movement in one * axis has stopped but continues in the other axis. When multiple * wl_pointer.axis_stop events occur within the same frame, this * indicates that these axes stopped in the same instance. * * A wl_pointer.frame event is sent for every logical event group, * even if the group only contains a single wl_pointer event. * Specifically, a client may get a sequence: motion, frame, * button, frame, axis, frame, axis_stop, frame. * * The wl_pointer.enter and wl_pointer.leave events are logical * events generated by the compositor and not the hardware. These * events are also grouped by a wl_pointer.frame. When a pointer * moves from one surface to another, a compositor should group the * wl_pointer.leave event within the same wl_pointer.frame. * However, a client must not rely on wl_pointer.leave and * wl_pointer.enter being in the same wl_pointer.frame. * Compositor-specific policies may require the wl_pointer.leave * and wl_pointer.enter event being split across multiple * wl_pointer.frame groups. * @since 5 */ void (*frame)(void *data, struct wl_pointer *wl_pointer); /** * axis source event * * Source information for scroll and other axes. * * This event does not occur on its own. It is sent before a * wl_pointer.frame event and carries the source information for * all events within that frame. * * The source specifies how this event was generated. If the source * is wl_pointer.axis_source.finger, a wl_pointer.axis_stop event * will be sent when the user lifts the finger off the device. * * If the source is wl_pointer.axis_source.wheel, * wl_pointer.axis_source.wheel_tilt or * wl_pointer.axis_source.continuous, a wl_pointer.axis_stop event * may or may not be sent. Whether a compositor sends an axis_stop * event for these sources is hardware-specific and * implementation-dependent; clients must not rely on receiving an * axis_stop event for these scroll sources and should treat scroll * sequences from these scroll sources as unterminated by default. * * This event is optional. If the source is unknown for a * particular axis event sequence, no event is sent. Only one * wl_pointer.axis_source event is permitted per frame. * * The order of wl_pointer.axis_discrete and wl_pointer.axis_source * is not guaranteed. * @param axis_source source of the axis event * @since 5 */ void (*axis_source)(void *data, struct wl_pointer *wl_pointer, uint32_t axis_source); /** * axis stop event * * Stop notification for scroll and other axes. * * For some wl_pointer.axis_source types, a wl_pointer.axis_stop * event is sent to notify a client that the axis sequence has * terminated. This enables the client to implement kinetic * scrolling. See the wl_pointer.axis_source documentation for * information on when this event may be generated. * * Any wl_pointer.axis events with the same axis_source after this * event should be considered as the start of a new axis motion. * * The timestamp is to be interpreted identical to the timestamp in * the wl_pointer.axis event. The timestamp value may be the same * as a preceding wl_pointer.axis event. * @param time timestamp with millisecond granularity * @param axis the axis stopped with this event * @since 5 */ void (*axis_stop)(void *data, struct wl_pointer *wl_pointer, uint32_t time, uint32_t axis); /** * axis click event * * Discrete step information for scroll and other axes. * * This event carries the axis value of the wl_pointer.axis event * in discrete steps (e.g. mouse wheel clicks). * * This event does not occur on its own, it is coupled with a * wl_pointer.axis event that represents this axis value on a * continuous scale. The protocol guarantees that each * axis_discrete event is always followed by exactly one axis event * with the same axis number within the same wl_pointer.frame. Note * that the protocol allows for other events to occur between the * axis_discrete and its coupled axis event, including other * axis_discrete or axis events. * * This event is optional; continuous scrolling devices like * two-finger scrolling on touchpads do not have discrete steps and * do not generate this event. * * The discrete value carries the directional information. e.g. a * value of -2 is two steps towards the negative direction of this * axis. * * The axis number is identical to the axis number in the * associated axis event. * * The order of wl_pointer.axis_discrete and wl_pointer.axis_source * is not guaranteed. * @param axis axis type * @param discrete number of steps * @since 5 */ void (*axis_discrete)(void *data, struct wl_pointer *wl_pointer, uint32_t axis, int32_t discrete); }; /** * @ingroup iface_wl_pointer */ static inline int wl_pointer_add_listener(struct wl_pointer *wl_pointer, const struct wl_pointer_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_pointer, (void (**)(void)) listener, data); } #define WL_POINTER_SET_CURSOR 0 #define WL_POINTER_RELEASE 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_ENTER_SINCE_VERSION 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_LEAVE_SINCE_VERSION 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_MOTION_SINCE_VERSION 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_BUTTON_SINCE_VERSION 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_AXIS_SINCE_VERSION 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_FRAME_SINCE_VERSION 5 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_AXIS_SOURCE_SINCE_VERSION 5 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_AXIS_STOP_SINCE_VERSION 5 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_AXIS_DISCRETE_SINCE_VERSION 5 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_SET_CURSOR_SINCE_VERSION 1 /** * @ingroup iface_wl_pointer */ #define WL_POINTER_RELEASE_SINCE_VERSION 3 /** @ingroup iface_wl_pointer */ static inline void wl_pointer_set_user_data(struct wl_pointer *wl_pointer, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_pointer, user_data); } /** @ingroup iface_wl_pointer */ static inline void * wl_pointer_get_user_data(struct wl_pointer *wl_pointer) { return wl_proxy_get_user_data((struct wl_proxy *) wl_pointer); } static inline uint32_t wl_pointer_get_version(struct wl_pointer *wl_pointer) { return wl_proxy_get_version((struct wl_proxy *) wl_pointer); } /** @ingroup iface_wl_pointer */ static inline void wl_pointer_destroy(struct wl_pointer *wl_pointer) { wl_proxy_destroy((struct wl_proxy *) wl_pointer); } /** * @ingroup iface_wl_pointer * * Set the pointer surface, i.e., the surface that contains the * pointer image (cursor). This request gives the surface the role * of a cursor. If the surface already has another role, it raises * a protocol error. * * The cursor actually changes only if the pointer * focus for this device is one of the requesting client's surfaces * or the surface parameter is the current pointer surface. If * there was a previous surface set with this request it is * replaced. If surface is NULL, the pointer image is hidden. * * The parameters hotspot_x and hotspot_y define the position of * the pointer surface relative to the pointer location. Its * top-left corner is always at (x, y) - (hotspot_x, hotspot_y), * where (x, y) are the coordinates of the pointer location, in * surface-local coordinates. * * On surface.attach requests to the pointer surface, hotspot_x * and hotspot_y are decremented by the x and y parameters * passed to the request. Attach must be confirmed by * wl_surface.commit as usual. * * The hotspot can also be updated by passing the currently set * pointer surface to this request with new values for hotspot_x * and hotspot_y. * * The current and pending input regions of the wl_surface are * cleared, and wl_surface.set_input_region is ignored until the * wl_surface is no longer used as the cursor. When the use as a * cursor ends, the current and pending input regions become * undefined, and the wl_surface is unmapped. */ static inline void wl_pointer_set_cursor(struct wl_pointer *wl_pointer, uint32_t serial, struct wl_surface *surface, int32_t hotspot_x, int32_t hotspot_y) { wl_proxy_marshal((struct wl_proxy *) wl_pointer, WL_POINTER_SET_CURSOR, serial, surface, hotspot_x, hotspot_y); } /** * @ingroup iface_wl_pointer * * Using this request a client can tell the server that it is not going to * use the pointer object anymore. * * This request destroys the pointer proxy object, so clients must not call * wl_pointer_destroy() after using this request. */ static inline void wl_pointer_release(struct wl_pointer *wl_pointer) { wl_proxy_marshal((struct wl_proxy *) wl_pointer, WL_POINTER_RELEASE); wl_proxy_destroy((struct wl_proxy *) wl_pointer); } #ifndef WL_KEYBOARD_KEYMAP_FORMAT_ENUM #define WL_KEYBOARD_KEYMAP_FORMAT_ENUM /** * @ingroup iface_wl_keyboard * keyboard mapping format * * This specifies the format of the keymap provided to the * client with the wl_keyboard.keymap event. */ enum wl_keyboard_keymap_format { /** * no keymap; client must understand how to interpret the raw keycode */ WL_KEYBOARD_KEYMAP_FORMAT_NO_KEYMAP = 0, /** * libxkbcommon compatible; to determine the xkb keycode, clients must add 8 to the key event keycode */ WL_KEYBOARD_KEYMAP_FORMAT_XKB_V1 = 1, }; #endif /* WL_KEYBOARD_KEYMAP_FORMAT_ENUM */ #ifndef WL_KEYBOARD_KEY_STATE_ENUM #define WL_KEYBOARD_KEY_STATE_ENUM /** * @ingroup iface_wl_keyboard * physical key state * * Describes the physical state of a key that produced the key event. */ enum wl_keyboard_key_state { /** * key is not pressed */ WL_KEYBOARD_KEY_STATE_RELEASED = 0, /** * key is pressed */ WL_KEYBOARD_KEY_STATE_PRESSED = 1, }; #endif /* WL_KEYBOARD_KEY_STATE_ENUM */ /** * @ingroup iface_wl_keyboard * @struct wl_keyboard_listener */ struct wl_keyboard_listener { /** * keyboard mapping * * This event provides a file descriptor to the client which can * be memory-mapped to provide a keyboard mapping description. * @param format keymap format * @param fd keymap file descriptor * @param size keymap size, in bytes */ void (*keymap)(void *data, struct wl_keyboard *wl_keyboard, uint32_t format, int32_t fd, uint32_t size); /** * enter event * * Notification that this seat's keyboard focus is on a certain * surface. * @param serial serial number of the enter event * @param surface surface gaining keyboard focus * @param keys the currently pressed keys */ void (*enter)(void *data, struct wl_keyboard *wl_keyboard, uint32_t serial, struct wl_surface *surface, struct wl_array *keys); /** * leave event * * Notification that this seat's keyboard focus is no longer on a * certain surface. * * The leave notification is sent before the enter notification for * the new focus. * @param serial serial number of the leave event * @param surface surface that lost keyboard focus */ void (*leave)(void *data, struct wl_keyboard *wl_keyboard, uint32_t serial, struct wl_surface *surface); /** * key event * * A key was pressed or released. The time argument is a * timestamp with millisecond granularity, with an undefined base. * @param serial serial number of the key event * @param time timestamp with millisecond granularity * @param key key that produced the event * @param state physical state of the key */ void (*key)(void *data, struct wl_keyboard *wl_keyboard, uint32_t serial, uint32_t time, uint32_t key, uint32_t state); /** * modifier and group state * * Notifies clients that the modifier and/or group state has * changed, and it should update its local state. * @param serial serial number of the modifiers event * @param mods_depressed depressed modifiers * @param mods_latched latched modifiers * @param mods_locked locked modifiers * @param group keyboard layout */ void (*modifiers)(void *data, struct wl_keyboard *wl_keyboard, uint32_t serial, uint32_t mods_depressed, uint32_t mods_latched, uint32_t mods_locked, uint32_t group); /** * repeat rate and delay * * Informs the client about the keyboard's repeat rate and delay. * * This event is sent as soon as the wl_keyboard object has been * created, and is guaranteed to be received by the client before * any key press event. * * Negative values for either rate or delay are illegal. A rate of * zero will disable any repeating (regardless of the value of * delay). * * This event can be sent later on as well with a new value if * necessary, so clients should continue listening for the event * past the creation of wl_keyboard. * @param rate the rate of repeating keys in characters per second * @param delay delay in milliseconds since key down until repeating starts * @since 4 */ void (*repeat_info)(void *data, struct wl_keyboard *wl_keyboard, int32_t rate, int32_t delay); }; /** * @ingroup iface_wl_keyboard */ static inline int wl_keyboard_add_listener(struct wl_keyboard *wl_keyboard, const struct wl_keyboard_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_keyboard, (void (**)(void)) listener, data); } #define WL_KEYBOARD_RELEASE 0 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_KEYMAP_SINCE_VERSION 1 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_ENTER_SINCE_VERSION 1 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_LEAVE_SINCE_VERSION 1 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_KEY_SINCE_VERSION 1 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_MODIFIERS_SINCE_VERSION 1 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_REPEAT_INFO_SINCE_VERSION 4 /** * @ingroup iface_wl_keyboard */ #define WL_KEYBOARD_RELEASE_SINCE_VERSION 3 /** @ingroup iface_wl_keyboard */ static inline void wl_keyboard_set_user_data(struct wl_keyboard *wl_keyboard, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_keyboard, user_data); } /** @ingroup iface_wl_keyboard */ static inline void * wl_keyboard_get_user_data(struct wl_keyboard *wl_keyboard) { return wl_proxy_get_user_data((struct wl_proxy *) wl_keyboard); } static inline uint32_t wl_keyboard_get_version(struct wl_keyboard *wl_keyboard) { return wl_proxy_get_version((struct wl_proxy *) wl_keyboard); } /** @ingroup iface_wl_keyboard */ static inline void wl_keyboard_destroy(struct wl_keyboard *wl_keyboard) { wl_proxy_destroy((struct wl_proxy *) wl_keyboard); } /** * @ingroup iface_wl_keyboard */ static inline void wl_keyboard_release(struct wl_keyboard *wl_keyboard) { wl_proxy_marshal((struct wl_proxy *) wl_keyboard, WL_KEYBOARD_RELEASE); wl_proxy_destroy((struct wl_proxy *) wl_keyboard); } /** * @ingroup iface_wl_touch * @struct wl_touch_listener */ struct wl_touch_listener { /** * touch down event and beginning of a touch sequence * * A new touch point has appeared on the surface. This touch * point is assigned a unique ID. Future events from this touch * point reference this ID. The ID ceases to be valid after a touch * up event and may be reused in the future. * @param serial serial number of the touch down event * @param time timestamp with millisecond granularity * @param surface surface touched * @param id the unique ID of this touch point * @param x surface-local x coordinate * @param y surface-local y coordinate */ void (*down)(void *data, struct wl_touch *wl_touch, uint32_t serial, uint32_t time, struct wl_surface *surface, int32_t id, wl_fixed_t x, wl_fixed_t y); /** * end of a touch event sequence * * The touch point has disappeared. No further events will be * sent for this touch point and the touch point's ID is released * and may be reused in a future touch down event. * @param serial serial number of the touch up event * @param time timestamp with millisecond granularity * @param id the unique ID of this touch point */ void (*up)(void *data, struct wl_touch *wl_touch, uint32_t serial, uint32_t time, int32_t id); /** * update of touch point coordinates * * A touch point has changed coordinates. * @param time timestamp with millisecond granularity * @param id the unique ID of this touch point * @param x surface-local x coordinate * @param y surface-local y coordinate */ void (*motion)(void *data, struct wl_touch *wl_touch, uint32_t time, int32_t id, wl_fixed_t x, wl_fixed_t y); /** * end of touch frame event * * Indicates the end of a set of events that logically belong * together. A client is expected to accumulate the data in all * events within the frame before proceeding. * * A wl_touch.frame terminates at least one event but otherwise no * guarantee is provided about the set of events within a frame. A * client must assume that any state not updated in a frame is * unchanged from the previously known state. */ void (*frame)(void *data, struct wl_touch *wl_touch); /** * touch session cancelled * * Sent if the compositor decides the touch stream is a global * gesture. No further events are sent to the clients from that * particular gesture. Touch cancellation applies to all touch * points currently active on this client's surface. The client is * responsible for finalizing the touch points, future touch points * on this surface may reuse the touch point ID. */ void (*cancel)(void *data, struct wl_touch *wl_touch); /** * update shape of touch point * * Sent when a touchpoint has changed its shape. * * This event does not occur on its own. It is sent before a * wl_touch.frame event and carries the new shape information for * any previously reported, or new touch points of that frame. * * Other events describing the touch point such as wl_touch.down, * wl_touch.motion or wl_touch.orientation may be sent within the * same wl_touch.frame. A client should treat these events as a * single logical touch point update. The order of wl_touch.shape, * wl_touch.orientation and wl_touch.motion is not guaranteed. A * wl_touch.down event is guaranteed to occur before the first * wl_touch.shape event for this touch ID but both events may occur * within the same wl_touch.frame. * * A touchpoint shape is approximated by an ellipse through the * major and minor axis length. The major axis length describes the * longer diameter of the ellipse, while the minor axis length * describes the shorter diameter. Major and minor are orthogonal * and both are specified in surface-local coordinates. The center * of the ellipse is always at the touchpoint location as reported * by wl_touch.down or wl_touch.move. * * This event is only sent by the compositor if the touch device * supports shape reports. The client has to make reasonable * assumptions about the shape if it did not receive this event. * @param id the unique ID of this touch point * @param major length of the major axis in surface-local coordinates * @param minor length of the minor axis in surface-local coordinates * @since 6 */ void (*shape)(void *data, struct wl_touch *wl_touch, int32_t id, wl_fixed_t major, wl_fixed_t minor); /** * update orientation of touch point * * Sent when a touchpoint has changed its orientation. * * This event does not occur on its own. It is sent before a * wl_touch.frame event and carries the new shape information for * any previously reported, or new touch points of that frame. * * Other events describing the touch point such as wl_touch.down, * wl_touch.motion or wl_touch.shape may be sent within the same * wl_touch.frame. A client should treat these events as a single * logical touch point update. The order of wl_touch.shape, * wl_touch.orientation and wl_touch.motion is not guaranteed. A * wl_touch.down event is guaranteed to occur before the first * wl_touch.orientation event for this touch ID but both events may * occur within the same wl_touch.frame. * * The orientation describes the clockwise angle of a touchpoint's * major axis to the positive surface y-axis and is normalized to * the -180 to +180 degree range. The granularity of orientation * depends on the touch device, some devices only support binary * rotation values between 0 and 90 degrees. * * This event is only sent by the compositor if the touch device * supports orientation reports. * @param id the unique ID of this touch point * @param orientation angle between major axis and positive surface y-axis in degrees * @since 6 */ void (*orientation)(void *data, struct wl_touch *wl_touch, int32_t id, wl_fixed_t orientation); }; /** * @ingroup iface_wl_touch */ static inline int wl_touch_add_listener(struct wl_touch *wl_touch, const struct wl_touch_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_touch, (void (**)(void)) listener, data); } #define WL_TOUCH_RELEASE 0 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_DOWN_SINCE_VERSION 1 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_UP_SINCE_VERSION 1 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_MOTION_SINCE_VERSION 1 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_FRAME_SINCE_VERSION 1 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_CANCEL_SINCE_VERSION 1 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_SHAPE_SINCE_VERSION 6 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_ORIENTATION_SINCE_VERSION 6 /** * @ingroup iface_wl_touch */ #define WL_TOUCH_RELEASE_SINCE_VERSION 3 /** @ingroup iface_wl_touch */ static inline void wl_touch_set_user_data(struct wl_touch *wl_touch, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_touch, user_data); } /** @ingroup iface_wl_touch */ static inline void * wl_touch_get_user_data(struct wl_touch *wl_touch) { return wl_proxy_get_user_data((struct wl_proxy *) wl_touch); } static inline uint32_t wl_touch_get_version(struct wl_touch *wl_touch) { return wl_proxy_get_version((struct wl_proxy *) wl_touch); } /** @ingroup iface_wl_touch */ static inline void wl_touch_destroy(struct wl_touch *wl_touch) { wl_proxy_destroy((struct wl_proxy *) wl_touch); } /** * @ingroup iface_wl_touch */ static inline void wl_touch_release(struct wl_touch *wl_touch) { wl_proxy_marshal((struct wl_proxy *) wl_touch, WL_TOUCH_RELEASE); wl_proxy_destroy((struct wl_proxy *) wl_touch); } #ifndef WL_OUTPUT_SUBPIXEL_ENUM #define WL_OUTPUT_SUBPIXEL_ENUM /** * @ingroup iface_wl_output * subpixel geometry information * * This enumeration describes how the physical * pixels on an output are laid out. */ enum wl_output_subpixel { /** * unknown geometry */ WL_OUTPUT_SUBPIXEL_UNKNOWN = 0, /** * no geometry */ WL_OUTPUT_SUBPIXEL_NONE = 1, /** * horizontal RGB */ WL_OUTPUT_SUBPIXEL_HORIZONTAL_RGB = 2, /** * horizontal BGR */ WL_OUTPUT_SUBPIXEL_HORIZONTAL_BGR = 3, /** * vertical RGB */ WL_OUTPUT_SUBPIXEL_VERTICAL_RGB = 4, /** * vertical BGR */ WL_OUTPUT_SUBPIXEL_VERTICAL_BGR = 5, }; #endif /* WL_OUTPUT_SUBPIXEL_ENUM */ #ifndef WL_OUTPUT_TRANSFORM_ENUM #define WL_OUTPUT_TRANSFORM_ENUM /** * @ingroup iface_wl_output * transform from framebuffer to output * * This describes the transform that a compositor will apply to a * surface to compensate for the rotation or mirroring of an * output device. * * The flipped values correspond to an initial flip around a * vertical axis followed by rotation. * * The purpose is mainly to allow clients to render accordingly and * tell the compositor, so that for fullscreen surfaces, the * compositor will still be able to scan out directly from client * surfaces. */ enum wl_output_transform { /** * no transform */ WL_OUTPUT_TRANSFORM_NORMAL = 0, /** * 90 degrees counter-clockwise */ WL_OUTPUT_TRANSFORM_90 = 1, /** * 180 degrees counter-clockwise */ WL_OUTPUT_TRANSFORM_180 = 2, /** * 270 degrees counter-clockwise */ WL_OUTPUT_TRANSFORM_270 = 3, /** * 180 degree flip around a vertical axis */ WL_OUTPUT_TRANSFORM_FLIPPED = 4, /** * flip and rotate 90 degrees counter-clockwise */ WL_OUTPUT_TRANSFORM_FLIPPED_90 = 5, /** * flip and rotate 180 degrees counter-clockwise */ WL_OUTPUT_TRANSFORM_FLIPPED_180 = 6, /** * flip and rotate 270 degrees counter-clockwise */ WL_OUTPUT_TRANSFORM_FLIPPED_270 = 7, }; #endif /* WL_OUTPUT_TRANSFORM_ENUM */ #ifndef WL_OUTPUT_MODE_ENUM #define WL_OUTPUT_MODE_ENUM /** * @ingroup iface_wl_output * mode information * * These flags describe properties of an output mode. * They are used in the flags bitfield of the mode event. */ enum wl_output_mode { /** * indicates this is the current mode */ WL_OUTPUT_MODE_CURRENT = 0x1, /** * indicates this is the preferred mode */ WL_OUTPUT_MODE_PREFERRED = 0x2, }; #endif /* WL_OUTPUT_MODE_ENUM */ /** * @ingroup iface_wl_output * @struct wl_output_listener */ struct wl_output_listener { /** * properties of the output * * The geometry event describes geometric properties of the * output. The event is sent when binding to the output object and * whenever any of the properties change. * @param x x position within the global compositor space * @param y y position within the global compositor space * @param physical_width width in millimeters of the output * @param physical_height height in millimeters of the output * @param subpixel subpixel orientation of the output * @param make textual description of the manufacturer * @param model textual description of the model * @param transform transform that maps framebuffer to output */ void (*geometry)(void *data, struct wl_output *wl_output, int32_t x, int32_t y, int32_t physical_width, int32_t physical_height, int32_t subpixel, const char *make, const char *model, int32_t transform); /** * advertise available modes for the output * * The mode event describes an available mode for the output. * * The event is sent when binding to the output object and there * will always be one mode, the current mode. The event is sent * again if an output changes mode, for the mode that is now * current. In other words, the current mode is always the last * mode that was received with the current flag set. * * The size of a mode is given in physical hardware units of the * output device. This is not necessarily the same as the output * size in the global compositor space. For instance, the output * may be scaled, as described in wl_output.scale, or transformed, * as described in wl_output.transform. * @param flags bitfield of mode flags * @param width width of the mode in hardware units * @param height height of the mode in hardware units * @param refresh vertical refresh rate in mHz */ void (*mode)(void *data, struct wl_output *wl_output, uint32_t flags, int32_t width, int32_t height, int32_t refresh); /** * sent all information about output * * This event is sent after all other properties have been sent * after binding to the output object and after any other property * changes done after that. This allows changes to the output * properties to be seen as atomic, even if they happen via * multiple events. * @since 2 */ void (*done)(void *data, struct wl_output *wl_output); /** * output scaling properties * * This event contains scaling geometry information that is not * in the geometry event. It may be sent after binding the output * object or if the output scale changes later. If it is not sent, * the client should assume a scale of 1. * * A scale larger than 1 means that the compositor will * automatically scale surface buffers by this amount when * rendering. This is used for very high resolution displays where * applications rendering at the native resolution would be too * small to be legible. * * It is intended that scaling aware clients track the current * output of a surface, and if it is on a scaled output it should * use wl_surface.set_buffer_scale with the scale of the output. * That way the compositor can avoid scaling the surface, and the * client can supply a higher detail image. * @param factor scaling factor of output * @since 2 */ void (*scale)(void *data, struct wl_output *wl_output, int32_t factor); }; /** * @ingroup iface_wl_output */ static inline int wl_output_add_listener(struct wl_output *wl_output, const struct wl_output_listener *listener, void *data) { return wl_proxy_add_listener((struct wl_proxy *) wl_output, (void (**)(void)) listener, data); } #define WL_OUTPUT_RELEASE 0 /** * @ingroup iface_wl_output */ #define WL_OUTPUT_GEOMETRY_SINCE_VERSION 1 /** * @ingroup iface_wl_output */ #define WL_OUTPUT_MODE_SINCE_VERSION 1 /** * @ingroup iface_wl_output */ #define WL_OUTPUT_DONE_SINCE_VERSION 2 /** * @ingroup iface_wl_output */ #define WL_OUTPUT_SCALE_SINCE_VERSION 2 /** * @ingroup iface_wl_output */ #define WL_OUTPUT_RELEASE_SINCE_VERSION 3 /** @ingroup iface_wl_output */ static inline void wl_output_set_user_data(struct wl_output *wl_output, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_output, user_data); } /** @ingroup iface_wl_output */ static inline void * wl_output_get_user_data(struct wl_output *wl_output) { return wl_proxy_get_user_data((struct wl_proxy *) wl_output); } static inline uint32_t wl_output_get_version(struct wl_output *wl_output) { return wl_proxy_get_version((struct wl_proxy *) wl_output); } /** @ingroup iface_wl_output */ static inline void wl_output_destroy(struct wl_output *wl_output) { wl_proxy_destroy((struct wl_proxy *) wl_output); } /** * @ingroup iface_wl_output * * Using this request a client can tell the server that it is not going to * use the output object anymore. */ static inline void wl_output_release(struct wl_output *wl_output) { wl_proxy_marshal((struct wl_proxy *) wl_output, WL_OUTPUT_RELEASE); wl_proxy_destroy((struct wl_proxy *) wl_output); } #define WL_REGION_DESTROY 0 #define WL_REGION_ADD 1 #define WL_REGION_SUBTRACT 2 /** * @ingroup iface_wl_region */ #define WL_REGION_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_region */ #define WL_REGION_ADD_SINCE_VERSION 1 /** * @ingroup iface_wl_region */ #define WL_REGION_SUBTRACT_SINCE_VERSION 1 /** @ingroup iface_wl_region */ static inline void wl_region_set_user_data(struct wl_region *wl_region, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_region, user_data); } /** @ingroup iface_wl_region */ static inline void * wl_region_get_user_data(struct wl_region *wl_region) { return wl_proxy_get_user_data((struct wl_proxy *) wl_region); } static inline uint32_t wl_region_get_version(struct wl_region *wl_region) { return wl_proxy_get_version((struct wl_proxy *) wl_region); } /** * @ingroup iface_wl_region * * Destroy the region. This will invalidate the object ID. */ static inline void wl_region_destroy(struct wl_region *wl_region) { wl_proxy_marshal((struct wl_proxy *) wl_region, WL_REGION_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_region); } /** * @ingroup iface_wl_region * * Add the specified rectangle to the region. */ static inline void wl_region_add(struct wl_region *wl_region, int32_t x, int32_t y, int32_t width, int32_t height) { wl_proxy_marshal((struct wl_proxy *) wl_region, WL_REGION_ADD, x, y, width, height); } /** * @ingroup iface_wl_region * * Subtract the specified rectangle from the region. */ static inline void wl_region_subtract(struct wl_region *wl_region, int32_t x, int32_t y, int32_t width, int32_t height) { wl_proxy_marshal((struct wl_proxy *) wl_region, WL_REGION_SUBTRACT, x, y, width, height); } #ifndef WL_SUBCOMPOSITOR_ERROR_ENUM #define WL_SUBCOMPOSITOR_ERROR_ENUM enum wl_subcompositor_error { /** * the to-be sub-surface is invalid */ WL_SUBCOMPOSITOR_ERROR_BAD_SURFACE = 0, }; #endif /* WL_SUBCOMPOSITOR_ERROR_ENUM */ #define WL_SUBCOMPOSITOR_DESTROY 0 #define WL_SUBCOMPOSITOR_GET_SUBSURFACE 1 /** * @ingroup iface_wl_subcompositor */ #define WL_SUBCOMPOSITOR_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_subcompositor */ #define WL_SUBCOMPOSITOR_GET_SUBSURFACE_SINCE_VERSION 1 /** @ingroup iface_wl_subcompositor */ static inline void wl_subcompositor_set_user_data(struct wl_subcompositor *wl_subcompositor, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_subcompositor, user_data); } /** @ingroup iface_wl_subcompositor */ static inline void * wl_subcompositor_get_user_data(struct wl_subcompositor *wl_subcompositor) { return wl_proxy_get_user_data((struct wl_proxy *) wl_subcompositor); } static inline uint32_t wl_subcompositor_get_version(struct wl_subcompositor *wl_subcompositor) { return wl_proxy_get_version((struct wl_proxy *) wl_subcompositor); } /** * @ingroup iface_wl_subcompositor * * Informs the server that the client will not be using this * protocol object anymore. This does not affect any other * objects, wl_subsurface objects included. */ static inline void wl_subcompositor_destroy(struct wl_subcompositor *wl_subcompositor) { wl_proxy_marshal((struct wl_proxy *) wl_subcompositor, WL_SUBCOMPOSITOR_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_subcompositor); } /** * @ingroup iface_wl_subcompositor * * Create a sub-surface interface for the given surface, and * associate it with the given parent surface. This turns a * plain wl_surface into a sub-surface. * * The to-be sub-surface must not already have another role, and it * must not have an existing wl_subsurface object. Otherwise a protocol * error is raised. */ static inline struct wl_subsurface * wl_subcompositor_get_subsurface(struct wl_subcompositor *wl_subcompositor, struct wl_surface *surface, struct wl_surface *parent) { struct wl_proxy *id; id = wl_proxy_marshal_constructor((struct wl_proxy *) wl_subcompositor, WL_SUBCOMPOSITOR_GET_SUBSURFACE, &wl_subsurface_interface, NULL, surface, parent); return (struct wl_subsurface *) id; } #ifndef WL_SUBSURFACE_ERROR_ENUM #define WL_SUBSURFACE_ERROR_ENUM enum wl_subsurface_error { /** * wl_surface is not a sibling or the parent */ WL_SUBSURFACE_ERROR_BAD_SURFACE = 0, }; #endif /* WL_SUBSURFACE_ERROR_ENUM */ #define WL_SUBSURFACE_DESTROY 0 #define WL_SUBSURFACE_SET_POSITION 1 #define WL_SUBSURFACE_PLACE_ABOVE 2 #define WL_SUBSURFACE_PLACE_BELOW 3 #define WL_SUBSURFACE_SET_SYNC 4 #define WL_SUBSURFACE_SET_DESYNC 5 /** * @ingroup iface_wl_subsurface */ #define WL_SUBSURFACE_DESTROY_SINCE_VERSION 1 /** * @ingroup iface_wl_subsurface */ #define WL_SUBSURFACE_SET_POSITION_SINCE_VERSION 1 /** * @ingroup iface_wl_subsurface */ #define WL_SUBSURFACE_PLACE_ABOVE_SINCE_VERSION 1 /** * @ingroup iface_wl_subsurface */ #define WL_SUBSURFACE_PLACE_BELOW_SINCE_VERSION 1 /** * @ingroup iface_wl_subsurface */ #define WL_SUBSURFACE_SET_SYNC_SINCE_VERSION 1 /** * @ingroup iface_wl_subsurface */ #define WL_SUBSURFACE_SET_DESYNC_SINCE_VERSION 1 /** @ingroup iface_wl_subsurface */ static inline void wl_subsurface_set_user_data(struct wl_subsurface *wl_subsurface, void *user_data) { wl_proxy_set_user_data((struct wl_proxy *) wl_subsurface, user_data); } /** @ingroup iface_wl_subsurface */ static inline void * wl_subsurface_get_user_data(struct wl_subsurface *wl_subsurface) { return wl_proxy_get_user_data((struct wl_proxy *) wl_subsurface); } static inline uint32_t wl_subsurface_get_version(struct wl_subsurface *wl_subsurface) { return wl_proxy_get_version((struct wl_proxy *) wl_subsurface); } /** * @ingroup iface_wl_subsurface * * The sub-surface interface is removed from the wl_surface object * that was turned into a sub-surface with a * wl_subcompositor.get_subsurface request. The wl_surface's association * to the parent is deleted, and the wl_surface loses its role as * a sub-surface. The wl_surface is unmapped. */ static inline void wl_subsurface_destroy(struct wl_subsurface *wl_subsurface) { wl_proxy_marshal((struct wl_proxy *) wl_subsurface, WL_SUBSURFACE_DESTROY); wl_proxy_destroy((struct wl_proxy *) wl_subsurface); } /** * @ingroup iface_wl_subsurface * * This schedules a sub-surface position change. * The sub-surface will be moved so that its origin (top left * corner pixel) will be at the location x, y of the parent surface * coordinate system. The coordinates are not restricted to the parent * surface area. Negative values are allowed. * * The scheduled coordinates will take effect whenever the state of the * parent surface is applied. When this happens depends on whether the * parent surface is in synchronized mode or not. See * wl_subsurface.set_sync and wl_subsurface.set_desync for details. * * If more than one set_position request is invoked by the client before * the commit of the parent surface, the position of a new request always * replaces the scheduled position from any previous request. * * The initial position is 0, 0. */ static inline void wl_subsurface_set_position(struct wl_subsurface *wl_subsurface, int32_t x, int32_t y) { wl_proxy_marshal((struct wl_proxy *) wl_subsurface, WL_SUBSURFACE_SET_POSITION, x, y); } /** * @ingroup iface_wl_subsurface * * This sub-surface is taken from the stack, and put back just * above the reference surface, changing the z-order of the sub-surfaces. * The reference surface must be one of the sibling surfaces, or the * parent surface. Using any other surface, including this sub-surface, * will cause a protocol error. * * The z-order is double-buffered. Requests are handled in order and * applied immediately to a pending state. The final pending state is * copied to the active state the next time the state of the parent * surface is applied. When this happens depends on whether the parent * surface is in synchronized mode or not. See wl_subsurface.set_sync and * wl_subsurface.set_desync for details. * * A new sub-surface is initially added as the top-most in the stack * of its siblings and parent. */ static inline void wl_subsurface_place_above(struct wl_subsurface *wl_subsurface, struct wl_surface *sibling) { wl_proxy_marshal((struct wl_proxy *) wl_subsurface, WL_SUBSURFACE_PLACE_ABOVE, sibling); } /** * @ingroup iface_wl_subsurface * * The sub-surface is placed just below the reference surface. * See wl_subsurface.place_above. */ static inline void wl_subsurface_place_below(struct wl_subsurface *wl_subsurface, struct wl_surface *sibling) { wl_proxy_marshal((struct wl_proxy *) wl_subsurface, WL_SUBSURFACE_PLACE_BELOW, sibling); } /** * @ingroup iface_wl_subsurface * * Change the commit behaviour of the sub-surface to synchronized * mode, also described as the parent dependent mode. * * In synchronized mode, wl_surface.commit on a sub-surface will * accumulate the committed state in a cache, but the state will * not be applied and hence will not change the compositor output. * The cached state is applied to the sub-surface immediately after * the parent surface's state is applied. This ensures atomic * updates of the parent and all its synchronized sub-surfaces. * Applying the cached state will invalidate the cache, so further * parent surface commits do not (re-)apply old state. * * See wl_subsurface for the recursive effect of this mode. */ static inline void wl_subsurface_set_sync(struct wl_subsurface *wl_subsurface) { wl_proxy_marshal((struct wl_proxy *) wl_subsurface, WL_SUBSURFACE_SET_SYNC); } /** * @ingroup iface_wl_subsurface * * Change the commit behaviour of the sub-surface to desynchronized * mode, also described as independent or freely running mode. * * In desynchronized mode, wl_surface.commit on a sub-surface will * apply the pending state directly, without caching, as happens * normally with a wl_surface. Calling wl_surface.commit on the * parent surface has no effect on the sub-surface's wl_surface * state. This mode allows a sub-surface to be updated on its own. * * If cached state exists when wl_surface.commit is called in * desynchronized mode, the pending state is added to the cached * state, and applied as a whole. This invalidates the cache. * * Note: even if a sub-surface is set to desynchronized, a parent * sub-surface may override it to behave as synchronized. For details, * see wl_subsurface. * * If a surface's parent surface behaves as desynchronized, then * the cached state is applied on set_desync. */ static inline void wl_subsurface_set_desync(struct wl_subsurface *wl_subsurface) { wl_proxy_marshal((struct wl_proxy *) wl_subsurface, WL_SUBSURFACE_SET_DESYNC); } #ifdef __cplusplus } #endif #endif