X Window System Protocol

X Consortium Standard

X Version 11, Release 6.8

Robert W. Scheifler
X Consortium, Inc.

X Window System is a trademark of The Open Group.

Copyright © 1986, 1987, 1988, 1994, 2004 The Open Group

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the ‘‘Software’’), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED ‘‘AS IS’’, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE OPEN GROUP 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.

Except as contained in this notice, the name of the Open Group shall not be used in advertising or otherwise to promote the sale, use or other dealings in this Software without prior written authorization from the Open Group.

Acknowledgments

The primary contributers to the X11 protocol are:

Dave Carver (Digital HPW)
Branko Gerovac (Digital HPW)
Jim Gettys (MIT/Project Athena, Digital)
Phil Karlton (Digital WSL)
Scott McGregor (Digital SSG)
Ram Rao (Digital UEG)
David Rosenthal (Sun)
Dave Winchell (Digital UEG)

The implementors of initial server who provided useful input are:

Susan Angebranndt (Digital)
Raymond Drewry (Digital)
Todd Newman (Digital)

The invited reviewers who provided useful input are:

Andrew Cherenson (Berkeley)
Burns Fisher (Digital)
Dan Garfinkel (HP)
Leo Hourvitz (Next)
Brock Krizan (HP)
David Laidlaw (Stellar)
Dave Mellinger (Interleaf)
Ron Newman (MIT)
John Ousterhout (Berkeley)
Andrew Palay (ITC CMU)
Ralph Swick (MIT)
Craig Taylor (Sun)
Jeffery Vroom (Stellar)

Thanks go to Al Mento of Digital’s UEG Documentation Group for formatting this document.

This document does not attempt to provide the rationale or pragmatics required to fully understand the protocol or to place it in perspective within a complete system.

The protocol contains many management mechanisms that are not intended for normal applications. Not all mechanisms are needed to build a particular user interface. It is important to keep in mind that the protocol is intended to provide mechanism, not policy.

Robert W. Scheifler
X Consortium, Inc.

1. Protocol Formats

Request Format

Every request contains an 8-bit major opcode and a 16-bit length field expressed in units of four bytes. Every request consists of four bytes of a header (containing the major opcode, the length field, and a data byte) followed by zero or more additional bytes of data. The length field defines the total length of the request, including the header. The length field in a request must equal the minimum length required to contain the request. If the specified length is smaller or larger than the required length, an error is generated. Unused bytes in a request are not required to be zero. Major opcodes 128 through 255 are reserved for extensions. Extensions are intended to contain multiple requests, so extension requests typically have an additional minor opcode encoded in the second data byte in the request header. However, the placement and interpretation of this minor opcode and of all other fields in extension requests are not defined by the core protocol. Every request on a given connection is implicitly assigned a sequence number, starting with one, that is used in replies, errors, and events.

Reply Format

Every reply contains a 32-bit length field expressed in units of four bytes. Every reply consists of 32 bytes followed by zero or more additional bytes of data, as specified in the length field. Unused bytes within a reply are not guaranteed to be zero. Every reply also contains the least significant 16 bits of the sequence number of the corresponding request.

Error Format

Error reports are 32 bytes long. Every error includes an 8-bit error code. Error codes 128 through 255 are reserved for extensions. Every error also includes the major and minor opcodes of the failed request and the least significant 16 bits of the sequence number of the request. For the following errors (see section 4), the failing resource ID is also returned: Colormap, Cursor, Drawable, Font, GContext, IDChoice, Pixmap, and Window. For Atom errors, the failing atom is returned. For Value errors, the failing value is returned. Other core errors return no additional data. Unused bytes within an error are not guaranteed to be zero.

Event Format

Events are 32 bytes long. Unused bytes within an event are not guaranteed to be zero. Every event contains an 8-bit type code. The most significant bit in this code is set if the event was generated from a SendEvent request. Event codes 64 through 127 are reserved for extensions, although the core protocol does not define a mechanism for selecting interest in such events. Every core event (with the exception of KeymapNotify) also contains the least significant 16 bits of the sequence number of the last request issued by the client that was (or is currently being) processed by the server.

2. Syntactic Conventions

The rest of this document uses the following syntactic conventions.

RequestName

→

If no → is present in the description, then the request has no reply (it is asynchronous), although errors may still be reported. If →+ is used, then one or more replies can be generated for a single request.

EventName

3. Common Types
Name Value
LISTofFOO
A type name of the form LISTofFOO means a counted
list of elements of type FOO. The size of the
length field may vary (it is not necessarily the
same size as a FOO), and in some cases, it may be
implicit. It is fully specified in Appendix B.
Except where explicitly noted, zero-length lists
are legal.
BITMASK
LISTofVALUE
The types BITMASK and LISTofVALUE are somewhat
special. Various requests contain arguments of the
form:
value-mask: BITMASK
value-list: LISTofVALUE
These are used to allow the client to specify a
subset of a heterogeneous collection of optional
arguments. The value-mask specifies which
arguments are to be provided; each such argument is
assigned a unique bit position. The representation
of the BITMASK will typically contain more bits
than there are defined arguments. The unused bits
in the value-mask must be zero (or the server
generates a Value error). The value-list contains
one value for each bit set to 1 in the mask, from
least significant to most significant bit in the
mask. Each value is represented with four bytes,
but the actual value occupies only the least
significant bytes as required. The values of the
unused bytes do not matter.
OR
A type of the form ‘‘T1 or ... or Tn’’ means the
union of the indicated types. A single-element
type is given as the element without enclosing
braces.
WINDOW 32-bit value (top three bits guaranteed to be zero)
PIXMAP 32-bit value (top three bits guaranteed to be zero)
CURSOR 32-bit value (top three bits guaranteed to be zero)
FONT 32-bit value (top three bits guaranteed to be zero)
GCONTEXT 32-bit value (top three bits guaranteed to be zero)
COLORMAP 32-bit value (top three bits guaranteed to be zero)
DRAWABLE WINDOW or PIXMAP
FONTABLE FONT or GCONTEXT
ATOM 32-bit value (top three bits guaranteed to be zero)
VISUALID 32-bit value (top three bits guaranteed to be zero)
VALUE 32-bit quantity (used only in LISTofVALUE)
BYTE 8-bit value
INT8 8-bit signed integer
INT16 16-bit signed integer
INT32 32-bit signed integer
CARD8 8-bit unsigned integer
CARD16 16-bit unsigned integer
CARD32 32-bit unsigned integer
TIMESTAMP CARD32
BITGRAVITY
{Forget, Static, NorthWest, North, NorthEast, West,
Center,  
East, SouthWest, South, SouthEast}
WINGRAVITY
{Unmap, Static, NorthWest, North, NorthEast, West,
Center,  
East, SouthWest, South, SouthEast}
BOOL
{True, False}
EVENT
{KeyPress, KeyRelease, OwnerGrabButton,
ButtonPress,  
ButtonRelease, EnterWindow, LeaveWindow,
PointerMotion,  
PointerMotionHint, Button1Motion, Button2Motion,  
Button3Motion, Button4Motion, Button5Motion,
ButtonMotion,  
Exposure, VisibilityChange, StructureNotify,
ResizeRedirect,  
SubstructureNotify, SubstructureRedirect,
FocusChange,  
PropertyChange, ColormapChange, KeymapState}
POINTEREVENT
{ButtonPress, ButtonRelease, EnterWindow,
LeaveWindow,  
PointerMotion, PointerMotionHint, Button1Motion,  
Button2Motion, Button3Motion, Button4Motion,
Button5Motion,  
ButtonMotion, KeymapState}
DEVICEEVENT
{KeyPress, KeyRelease, ButtonPress, ButtonRelease,  
PointerMotion, Button1Motion, Button2Motion,
Button3Motion,  
Button4Motion, Button5Motion, ButtonMotion}
KEYSYM 32-bit value (top three bits guaranteed to be zero)
KEYCODE CARD8
BUTTON CARD8
KEYMASK
{Shift, Lock, Control, Mod1, Mod2, Mod3, Mod4,
Mod5}
BUTMASK
{Button1, Button2, Button3, Button4, Button5}
KEYBUTMASK KEYMASK or BUTMASK
STRING8 LISTofCARD8
STRING16 LISTofCHAR2B
CHAR2B [byte1, byte2: CARD8]
POINT [x, y: INT16]
RECTANGLE
[x, y: INT16,  
width, height: CARD16]
ARC
[x, y: INT16,  
width, height: CARD16,  
angle1, angle2: INT16]
HOST
[family: {Internet, InternetV6, ServerInterpreted,
DECnet, Chaos}  
address: LISTofBYTE]

The [x,y] coordinates of a RECTANGLE specify the upper-left corner.

The primary interpretation of large characters in a STRING16 is that they are composed of two bytes used to index a two-dimensional matrix, hence, the use of CHAR2B rather than CARD16. This corresponds to the JIS/ISO method of indexing 2-byte characters. It is expected that most large fonts will be defined with 2-byte matrix indexing. For large fonts constructed with linear indexing, a CHAR2B can be interpreted as a 16-bit number by treating byte1 as the most significant byte. This means that clients should always transmit such 16-bit character values most significant byte first, as the server will never byte-swap CHAR2B quantities.

The length, format, and interpretation of a HOST address are specific to the family (see ChangeHosts request).

4. Errors

In general, when a request terminates with an error, the request has no side effects (that is, there is no partial execution). The only requests for which this is not true are ChangeWindowAttributes, ChangeGC, PolyText8, PolyText16, FreeColors, StoreColors, and ChangeKeyboardControl.

The following error codes result from various requests as follows:
Error Description
Access
An attempt is made to grab a key/button
combination already grabbed by another
client.
An attempt is made to free a colormap
entry not allocated by the client or to
free an entry in a colormap that was
created with all entries writable.
An attempt is made to store into a
read-only or an unallocated colormap
entry.
An attempt is made to modify the access
control list from other than the local
host (or otherwise authorized client).
An attempt is made to select an event type
that only one client can select at a time
when another client has already selected
it.
Alloc
The server failed to allocate the
requested resource. Note that the
explicit listing of Alloc errors in
request only covers allocation errors at a
very coarse level and is not intended to
cover all cases of a server running out of
allocation space in the middle of service.
The semantics when a server runs out of
allocation space are left unspecified, but
a server may generate an Alloc error on
any request for this reason, and clients
should be prepared to receive such errors
and handle or discard them.
Atom
A value for an ATOM argument does not name
a defined ATOM.
Colormap
A value for a COLORMAP argument does not
name a defined COLORMAP.
Cursor
A value for a CURSOR argument does not
name a defined CURSOR.
Drawable
A value for a DRAWABLE argument does not
name a defined WINDOW or PIXMAP.
Font
A value for a FONT argument does not name
a defined FONT.
A value for a FONTABLE argument does not
name a defined FONT or a defined GCONTEXT.
GContext
A value for a GCONTEXT argument does not
name a defined GCONTEXT.
IDChoice
The value chosen for a resource identifier
either is not included in the range
assigned to the client or is already in
use.
Implementation
The server does not implement some aspect
of the request. A server that generates
this error for a core request is
deficient. As such, this error is not
listed for any of the requests, but
clients should be prepared to receive such
errors and handle or discard them.
Length
The length of a request is shorter or
longer than that required to minimally
contain the arguments.
The length of a request exceeds the
maximum length accepted by the server.
Match
An InputOnly window is used as a DRAWABLE.
In a graphics request, the GCONTEXT
argument does not have the same root and
depth as the destination DRAWABLE
argument.
Some argument (or pair of arguments) has
the correct type and range, but it fails
to match in some other way required by the
request.
Name
A font or color of the specified name does
not exist.
Pixmap
A value for a PIXMAP argument does not
name a defined PIXMAP.
Request
The major or minor opcode does not specify
a valid request.
Value
Some numeric value falls outside the range
of values accepted by the request. Unless
a specific range is specified for an
argument, the full range defined by the
argument’s type is accepted. Any argument
defined as a set of alternatives typically
can generate this error (due to the
encoding).
Window
A value for a WINDOW argument does not
name a defined WINDOW.

Note

The Atom, Colormap, Cursor, Drawable, Font, GContext, Pixmap, and Window errors are also used when the argument type is extended by union with a set of fixed alternatives, for example, <WINDOW or PointerRoot or None>.

5. Keyboards

A KEYCODE represents a physical (or logical) key. Keycodes lie in the inclusive range [8,255]. A keycode value carries no intrinsic information, although server implementors may attempt to encode geometry information (for example, matrix) to be interpreted in a server-dependent fashion. The mapping between keys and keycodes cannot be changed using the protocol.

A KEYSYM is an encoding of a symbol on the cap of a key. The set of defined KEYSYMs include the character sets Latin-1, Latin-2, Latin-3, Latin-4, Kana, Arabic, Cyrillic, Greek, Tech, Special, Publish, APL, Hebrew, Thai, and Korean as well as a set of symbols common on keyboards (Return, Help, Tab, and so on). KEYSYMs with the most significant bit (of the 29 bits) set are reserved as vendor-specific.

A list of KEYSYMs is associated with each KEYCODE. The list is intended to convey the set of symbols on the corresponding key. If the list (ignoring trailing NoSymbol entries) is a single KEYSYM ‘‘K’’, then the list is treated as if it were the list ‘‘K NoSymbol K NoSymbol’’. If the list (ignoring trailing NoSymbol entries) is a pair of KEYSYMs ‘‘K1 K2’’, then the list is treated as if it were the list ‘‘K1 K2 K1 K2’’. If the list (ignoring trailing NoSymbol entries) is a triple of KEYSYMs ‘‘K1 K2 K3’’, then the list is treated as if it were the list ‘‘K1 K2 K3 NoSymbol’’. When an explicit ‘‘void’’ element is desired in the list, the value VoidSymbol can be used.

The first four elements of the list are split into two groups of KEYSYMs. Group 1 contains the first and second KEYSYMs, Group 2 contains the third and fourth KEYSYMs. Within each group, if the second element of the group is NoSymbol, then the group should be treated as if the second element were the same as the first element, except when the first element is an alphabetic KEYSYM ‘‘K’’ for which both lowercase and uppercase forms are defined. In that case, the group should be treated as if the first element were the lowercase form of ‘‘K’’ and the second element were the uppercase form of ‘‘K’’.

The standard rules for obtaining a KEYSYM from a KeyPress event make use of only the Group 1 and Group 2 KEYSYMs; no interpretation of other KEYSYMs in the list is defined. The modifier state determines which group to use. Switching between groups is controlled by the KEYSYM named MODE SWITCH, by attaching that KEYSYM to some KEYCODE and attaching that KEYCODE to any one of the modifiers Mod1 through Mod5. This modifier is called the ‘‘group modifier’’. For any KEYCODE, Group 1 is used when the group modifier is off, and Group 2 is used when the group modifier is on.

The Lock modifier is interpreted as CapsLock when the KEYSYM named CAPS LOCK is attached to some KEYCODE and that KEYCODE is attached to the Lock modifier. The Lock modifier is interpreted as ShiftLock when the KEYSYM named SHIFT LOCK is attached to some KEYCODE and that KEYCODE is attached to the Lock modifier. If the Lock modifier could be interpreted as both CapsLock and ShiftLock, the CapsLock interpretation is used.

The operation of ‘‘keypad’’ keys is controlled by the KEYSYM named NUM LOCK, by attaching that KEYSYM to some KEYCODE and attaching that KEYCODE to any one of the modifiers Mod1 through Mod5. This modifier is called the ‘‘numlock modifier’’. The standard KEYSYMs with the prefix KEYPAD in their name are called ‘‘keypad’’ KEYSYMs; these are KEYSYMS with numeric value in the hexadecimal range #xFF80 to #xFFBD inclusive. In addition, vendor-specific KEYSYMS in the hexadecimal range #x11000000 to #x1100FFFF are also keypad KEYSYMs.

Within a group, the choice of KEYSYM is determined by applying the first rule that is satisfied from the following list:

The mapping between KEYCODEs and KEYSYMs is not used directly by the server; it is merely stored for reading and writing by clients.

6. Pointers

Buttons are always numbered starting with one.

7. Predefined Atoms

Predefined atoms are not strictly necessary and may not be useful in all environments, but they will eliminate many InternAtom requests in most applications. Note that they are predefined only in the sense of having numeric values, not in the sense of having required semantics. The core protocol imposes no semantics on these names, but semantics are specified in other X Window System standards, such as the Inter-Client Communication Conventions Manual and the X Logical Font Description Conventions.

The following names have predefined atom values. Note that uppercase and lowercase matter.
ARC ITALIC_ANGLE STRING
ATOM MAX_SPACE SUBSCRIPT_X
BITMAP MIN_SPACE SUBSCRIPT_Y
CAP_HEIGHT NORM_SPACE SUPERSCRIPT_X
CARDINAL NOTICE SUPERSCRIPT_Y
COLORMAP PIXMAP UNDERLINE_POSITION
COPYRIGHT POINT UNDERLINE_THICKNESS
CURSOR POINT_SIZE VISUALID
CUT_BUFFER0 PRIMARY WEIGHT
CUT_BUFFER1 QUAD_WIDTH WINDOW
CUT_BUFFER2 RECTANGLE WM_CLASS
CUT_BUFFER3 RESOLUTION WM_CLIENT_MACHINE
CUT_BUFFER4 RESOURCE_MANAGER WM_COMMAND
CUT_BUFFER5 RGB_BEST_MAP WM_HINTS
CUT_BUFFER6 RGB_BLUE_MAP WM_ICON_NAME
CUT_BUFFER7 RGB_COLOR_MAP WM_ICON_SIZE
DRAWABLE RGB_DEFAULT_MAP WM_NAME
END_SPACE RGB_GRAY_MAP WM_NORMAL_HINTS
FAMILY_NAME RGB_GREEN_MAP WM_SIZE_HINTS
FONT RGB_RED_MAP WM_TRANSIENT_FOR
FONT_NAME SECONDARY WM_ZOOM_HINTS
FULL_NAME STRIKEOUT_ASCENT X_HEIGHT
INTEGER STRIKEOUT_DESCENT

To avoid conflicts with possible future names for which semantics might be imposed (either at the protocol level or in terms of higher level user interface models), names beginning with an underscore should be used for atoms that are private to a particular vendor or organization. To guarantee no conflicts between vendors and organizations, additional prefixes need to be used. However, the protocol does not define the mechanism for choosing such prefixes. For names private to a single application or end user but stored in globally accessible locations, it is suggested that two leading underscores be used to avoid conflicts with other names.

8. Connection Setup

For remote clients, the X protocol can be built on top of any reliable byte stream.

Connection Initiation

The client must send an initial byte of data to identify the byte order to be employed. The value of the byte must be octal 102 or 154. The value 102 (ASCII uppercase B) means values are transmitted most significant byte first, and value 154 (ASCII lowercase l) means values are transmitted least significant byte first. Except where explicitly noted in the protocol, all 16-bit and 32-bit quantities sent by the client must be transmitted with this byte order, and all 16-bit and 32-bit quantities returned by the server will be transmitted with this byte order.

Following the byte-order byte, the client sends the following information at connection setup:

protocol-major-version: CARD16
protocol-minor-version: CARD16
authorization-protocol-name: STRING8
authorization-protocol-data: STRING8

The version numbers indicate what version of the protocol the client expects the server to implement.

The authorization name indicates what authorization (and authentication) protocol the client expects the server to use, and the data is specific to that protocol. Specification of valid authorization mechanisms is not part of the core X protocol. A server that does not implement the protocol the client expects or that only implements the host-based mechanism may simply ignore this information. If both name and data strings are empty, this is to be interpreted as ‘‘no explicit authorization.’’

Server Response

The client receives the following information at connection setup:

success: {Failed, Success, Authenticate}

The client receives the following additional data if the returned success value is Failed, and the connection is not successfully established:

protocol-major-version: CARD16
protocol-minor-version: CARD16
reason: STRING8

The client receives the following additional data if the returned success value is Authenticate, and further authentication negotiation is required:

reason: STRING8

The contents of the reason string are specific to the authorization protocol in use. The semantics of this authentication negotiation are not constrained, except that the negotiation must eventually terminate with a reply from the server containing a success value of Failed or Success.

The client receives the following additional data if the returned success value is Success, and the connection is successfully established:

protocol-major-version: CARD16
protocol-minor-version: CARD16
vendor: STRING8
release-number: CARD32
resource-id-base, resource-id-mask: CARD32
image-byte-order: {LSBFirst, MSBFirst}
bitmap-scanline-unit: {8, 16, 32}
bitmap-scanline-pad: {8, 16, 32}
bitmap-bit-order: {LeastSignificant, MostSignificant}
pixmap-formats: LISTofFORMAT
roots: LISTofSCREEN
motion-buffer-size: CARD32
maximum-request-length: CARD16
min-keycode, max-keycode: KEYCODE

where:
FORMAT:
[depth: CARD8,  
bits-per-pixel: {1, 4, 8, 16, 24, 32}  
scanline-pad: {8, 16, 32}]

SCREEN:
[root: WINDOW  
width-in-pixels, height-in-pixels:
CARD16  
width-in-millimeters,
height-in-millimeters: CARD16  
allowed-depths: LISTofDEPTH  
root-depth: CARD8  
root-visual: VISUALID  
default-colormap: COLORMAP  
white-pixel, black-pixel: CARD32  
min-installed-maps, max-installed-maps:
CARD16  
backing-stores: {Never, WhenMapped,
Always}  
save-unders: BOOL  
current-input-masks: SETofEVENT]

DEPTH:
[depth: CARD8  
visuals: LISTofVISUALTYPE]

VISUALTYPE:
[visual-id: VISUALID  
class: {StaticGray, StaticColor,
TrueColor, GrayScale,           
PseudoColor, DirectColor}  
red-mask, green-mask, blue-mask: CARD32  
bits-per-rgb-value: CARD8  
colormap-entries: CARD16]

Server Information

The information that is global to the server is:

The protocol version numbers are an escape hatch in case future revisions of the protocol are necessary. In general, the major version would increment for incompatible changes, and the minor version would increment for small upward compatible changes. Barring changes, the major version will be 11, and the minor version will be 0. The protocol version numbers returned indicate the protocol the server actually supports. This might not equal the version sent by the client. The server can (but need not) refuse connections from clients that offer a different version than the server supports. A server can (but need not) support more than one version simultaneously.

The vendor string gives some identification of the owner of the server implementation. The vendor controls the semantics of the release number.

The resource-id-mask contains a single contiguous set of bits (at least 18). The client allocates resource IDs for types WINDOW, PIXMAP, CURSOR, FONT, GCONTEXT, and COLORMAP by choosing a value with only some subset of these bits set and ORing it with resource-id-base. Only values constructed in this way can be used to name newly created resources over this connection. Resource IDs never have the top three bits set. The client is not restricted to linear or contiguous allocation of resource IDs. Once an ID has been freed, it can be reused. An ID must be unique with respect to the IDs of all other resources, not just other resources of the same type. However, note that the value spaces of resource identifiers, atoms, visualids, and keysyms are distinguished by context, and as such, are not required to be disjoint; for example, a given numeric value might be both a valid window ID, a valid atom, and a valid keysym.

Although the server is in general responsible for byte-swapping data to match the client, images are always transmitted and received in formats (including byte order) specified by the server. The byte order for images is given by image-byte-order and applies to each scanline unit in XY format (bitmap format) and to each pixel value in Z format.

A bitmap is represented in scanline order. Each scanline is padded to a multiple of bits as given by bitmap-scanline-pad. The pad bits are of arbitrary value. The scanline is quantized in multiples of bits as given by bitmap-scanline-unit. The bitmap-scanline-unit is always less than or equal to the bitmap-scanline-pad. Within each unit, the leftmost bit in the bitmap is either the least significant or most significant bit in the unit, as given by bitmap-bit-order. If a pixmap is represented in XY format, each plane is represented as a bitmap, and the planes appear from most significant to least significant in bit order with no padding between planes.

Pixmap-formats contains one entry for each depth value. The entry describes the Z format used to represent images of that depth. An entry for a depth is included if any screen supports that depth, and all screens supporting that depth must support only that Z format for that depth. In Z format, the pixels are in scanline order, left to right within a scanline. The number of bits used to hold each pixel is given by bits-per-pixel. Bits-per-pixel may be larger than strictly required by the depth, in which case the least significant bits are used to hold the pixmap data, and the values of the unused high-order bits are undefined. When the bits-per-pixel is 4, the order of nibbles in the byte is the same as the image byte-order. When the bits-per-pixel is 1, the format is identical for bitmap format. Each scanline is padded to a multiple of bits as given by scanline-pad. When bits-per-pixel is 1, this will be identical to bitmap-scanline-pad.

How a pointing device roams the screens is up to the server implementation and is transparent to the protocol. No geometry is defined among screens.

The server may retain the recent history of pointer motion and do so to a finer granularity than is reported by MotionNotify events. The GetMotionEvents request makes such history available. The motion-buffer-size gives the approximate maximum number of elements in the history buffer.

Maximum-request-length specifies the maximum length of a request accepted by the server, in 4-byte units. That is, length is the maximum value that can appear in the length field of a request. Requests larger than this maximum generate a Length error, and the server will read and simply discard the entire request. Maximum-request-length will always be at least 4096 (that is, requests of length up to and including 16384 bytes will be accepted by all servers).

Min-keycode and max-keycode specify the smallest and largest keycode values transmitted by the server. Min-keycode is never less than 8, and max-keycode is never greater than 255. Not all keycodes in this range are required to have corresponding keys.

Screen Information

The information that applies per screen is:

The allowed-depths specifies what pixmap and window depths are supported. Pixmaps are supported for each depth listed, and windows of that depth are supported if at least one visual type is listed for the depth. A pixmap depth of one is always supported and listed, but windows of depth one might not be supported. A depth of zero is never listed, but zero-depth InputOnly windows are always supported.

Root-depth and root-visual specify the depth and visual type of the root window. Width-in-pixels and height-in-pixels specify the size of the root window (which cannot be changed). The class of the root window is always InputOutput. Width-in-millimeters and height-in-millimeters can be used to determine the physical size and the aspect ratio.

The default-colormap is the one initially associated with the root window. Clients with minimal color requirements creating windows of the same depth as the root may want to allocate from this map by default.

Black-pixel and white-pixel can be used in implementing a monochrome application. These pixel values are for permanently allocated entries in the default-colormap. The actual RGB values may be settable on some screens and, in any case, may not actually be black and white. The names are intended to convey the expected relative intensity of the colors.

The border of the root window is initially a pixmap filled with the black-pixel. The initial background of the root window is a pixmap filled with some unspecified two-color pattern using black-pixel and white-pixel.

Min-installed-maps specifies the number of maps that can be guaranteed to be installed simultaneously (with InstallColormap), regardless of the number of entries allocated in each map. Max-installed-maps specifies the maximum number of maps that might possibly be installed simultaneously, depending on their allocations. Multiple static-visual colormaps with identical contents but differing in resource ID should be considered as a single map for the purposes of this number. For the typical case of a single hardware colormap, both values will be 1.

Backing-stores indicates when the server supports backing stores for this screen, although it may be storage limited in the number of windows it can support at once. If save-unders is True, the server can support the save-under mode in CreateWindow and ChangeWindowAttributes, although again it may be storage limited.

The current-input-events is what GetWindowAttributes would return for the all-event-masks for the root window.

Visual Information

The information that applies per visual-type is:

A given visual type might be listed for more than one depth or for more than one screen.

For PseudoColor, a pixel value indexes a colormap to produce independent RGB values; the RGB values can be changed dynamically. GrayScale is treated in the same way as PseudoColor except which primary drives the screen is undefined; thus, the client should always store the same value for red, green, and blue in colormaps. For DirectColor, a pixel value is decomposed into separate RGB subfields, and each subfield separately indexes the colormap for the corresponding value. The RGB values can be changed dynamically. TrueColor is treated in the same way as DirectColor except the colormap has predefined read-only RGB values. These values are server-dependent but provide linear or near-linear increasing ramps in each primary. StaticColor is treated in the same way as PseudoColor except the colormap has predefined read-only RGB values, which are server-dependent. StaticGray is treated in the same way as StaticColor except the red, green, and blue values are equal for any single pixel value, resulting in shades of gray. StaticGray with a two-entry colormap can be thought of as monochrome.

The red-mask, green-mask, and blue-mask are only defined for DirectColor and TrueColor. Each has one contiguous set of bits set to 1 with no intersections. Usually each mask has the same number of bits set to 1.

The bits-per-rgb-value specifies the log base 2 of the number of distinct color intensity values (individually) of red, green, and blue. This number need not bear any relation to the number of colormap entries. Actual RGB values are always passed in the protocol within a 16-bit spectrum, with 0 being minimum intensity and 65535 being the maximum intensity. On hardware that provides a linear zero-based intensity ramp, the following relationship exists:

hw-intensity = protocol-intensity / (65536 / total-hw-intensities)

Colormap entries are indexed from 0. The colormap-entries defines the number of available colormap entries in a newly created colormap. For DirectColor and TrueColor, this will usually be 2 to the power of the maximum number of bits set to 1 in red-mask, green-mask, and blue-mask.

9. Requests __ │
CreateWindow

wid, parent: WINDOW
class: {InputOutput, InputOnly, CopyFromParent}
depth: CARD8
visual: VISUALID or CopyFromParent
x, y: INT16
width, height, border-width: CARD16
value-mask: BITMASK
value-list: LISTofVALUE

Errors: Alloc, Colormap, Cursor, IDChoice, Match, Pixmap,
Value, Window│__

This request creates an unmapped window and assigns the identifier wid to it.

A class of CopyFromParent means the class is taken from the parent. A depth of zero for class InputOutput or CopyFromParent means the depth is taken from the parent. A visual of CopyFromParent means the visual type is taken from the parent. For class InputOutput, the visual type and depth must be a combination supported for the screen (or a Match error results). The depth need not be the same as the parent, but the parent must not be of class InputOnly (or a Match error results). For class InputOnly, the depth must be zero (or a Match error results), and the visual must be one supported for the screen (or a Match error results). However, the parent can have any depth and class.

The server essentially acts as if InputOnly windows do not exist for the purposes of graphics requests, exposure processing, and VisibilityNotify events. An InputOnly window cannot be used as a drawable (as a source or destination for graphics requests). InputOnly and InputOutput windows act identically in other respects−properties, grabs, input control, and so on.

The coordinate system has the X axis horizontal and the Y axis vertical with the origin [0, 0] at the upper-left corner. Coordinates are integral, in terms of pixels, and coincide with pixel centers. Each window and pixmap has its own coordinate system. For a window, the origin is inside the border at the inside, upper-left corner.

The x and y coordinates for the window are relative to the parent’s origin and specify the position of the upper-left outer corner of the window (not the origin). The width and height specify the inside size (not including the border) and must be nonzero (or a Value error results). The border-width for an InputOnly window must be zero (or a Match error results).

The window is placed on top in the stacking order with respect to siblings.

The value-mask and value-list specify attributes of the window that are to be explicitly initialized. The possible values are:
Attribute Type
background-pixmap
PIXMAP or None or
ParentRelative
background-pixel
CARD32
border-pixmap
PIXMAP or CopyFromParent
border-pixel
CARD32
bit-gravity
BITGRAVITY
win-gravity
WINGRAVITY
backing-store
{NotUseful, WhenMapped,
Always}
backing-planes
CARD32
backing-pixel
CARD32
save-under
BOOL
event-mask
SETofEVENT
do-not-propagate-mask
SETofDEVICEEVENT
override-redirect
BOOL
colormap
COLORMAP or CopyFromParent
cursor
CURSOR or None

The default values when attributes are not explicitly initialized are:
Attribute Default
background-pixmap
None
border-pixmap
CopyFromParent
bit-gravity
Forget
win-gravity
NorthWest
backing-store
NotUseful
backing-planes
all ones
backing-pixel
zero
save-under
False
event-mask
{} (empty set)
do-not-propagate-mask
{} (empty set)
override-redirect
False
colormap
CopyFromParent
cursor
None

Only the following attributes are defined for InputOnly windows:

It is a Match error to specify any other attributes for InputOnly windows.

If background-pixmap is given, it overrides the default background-pixmap. The background pixmap and the window must have the same root and the same depth (or a Match error results). Any size pixmap can be used, although some sizes may be faster than others. If background None is specified, the window has no defined background. If background ParentRelative is specified, the parent’s background is used, but the window must have the same depth as the parent (or a Match error results). If the parent has background None, then the window will also have background None. A copy of the parent’s background is not made. The parent’s background is reexamined each time the window background is required. If background-pixel is given, it overrides the default background-pixmap and any background-pixmap given explicitly, and a pixmap of undefined size filled with background-pixel is used for the background. Range checking is not performed on the background-pixel value; it is simply truncated to the appropriate number of bits. For a ParentRelative background, the background tile origin always aligns with the parent’s background tile origin. Otherwise, the background tile origin is always the window origin.

When no valid contents are available for regions of a window and the regions are either visible or the server is maintaining backing store, the server automatically tiles the regions with the window’s background unless the window has a background of None. If the background is None, the previous screen contents from other windows of the same depth as the window are simply left in place if the contents come from the parent of the window or an inferior of the parent; otherwise, the initial contents of the exposed regions are undefined. Exposure events are then generated for the regions, even if the background is None.

The border tile origin is always the same as the background tile origin. If border-pixmap is given, it overrides the default border-pixmap. The border pixmap and the window must have the same root and the same depth (or a Match error results). Any size pixmap can be used, although some sizes may be faster than others. If CopyFromParent is given, the parent’s border pixmap is copied (subsequent changes to the parent’s border attribute do not affect the child), but the window must have the same depth as the parent (or a Match error results). The pixmap might be copied by sharing the same pixmap object between the child and parent or by making a complete copy of the pixmap contents. If border-pixel is given, it overrides the default border-pixmap and any border-pixmap given explicitly, and a pixmap of undefined size filled with border-pixel is used for the border. Range checking is not performed on the border-pixel value; it is simply truncated to the appropriate number of bits.

Output to a window is always clipped to the inside of the window, so that the border is never affected.

The bit-gravity defines which region of the window should be retained if the window is resized, and win-gravity defines how the window should be repositioned if the parent is resized (see ConfigureWindow request).

A backing-store of WhenMapped advises the server that maintaining contents of obscured regions when the window is mapped would be beneficial. A backing-store of Always advises the server that maintaining contents even when the window is unmapped would be beneficial. In this case, the server may generate an exposure event when the window is created. A value of NotUseful advises the server that maintaining contents is unnecessary, although a server may still choose to maintain contents while the window is mapped. Note that if the server maintains contents, then the server should maintain complete contents not just the region within the parent boundaries, even if the window is larger than its parent. While the server maintains contents, exposure events will not normally be generated, but the server may stop maintaining contents at any time.

If save-under is True, the server is advised that when this window is mapped, saving the contents of windows it obscures would be beneficial.

When the contents of obscured regions of a window are being maintained, regions obscured by noninferior windows are included in the destination (and source, when the window is the source) of graphics requests, but regions obscured by inferior windows are not included.

The backing-planes indicates (with bits set to 1) which bit planes of the window hold dynamic data that must be preserved in backing-stores and during save-unders. The backing-pixel specifies what value to use in planes not covered by backing-planes. The server is free to save only the specified bit planes in the backing-store or save-under and regenerate the remaining planes with the specified pixel value. Any bits beyond the specified depth of the window in these values are simply ignored.

The event-mask defines which events the client is interested in for this window (or for some event types, inferiors of the window). The do-not-propagate-mask defines which events should not be propagated to ancestor windows when no client has the event type selected in this window.

The override-redirect specifies whether map and configure requests on this window should override a SubstructureRedirect on the parent, typically to inform a window manager not to tamper with the window.

The colormap specifies the colormap that best reflects the true colors of the window. Servers capable of supporting multiple hardware colormaps may use this information, and window managers may use it for InstallColormap requests. The colormap must have the same visual type and root as the window (or a Match error results). If CopyFromParent is specified, the parent’s colormap is copied (subsequent changes to the parent’s colormap attribute do not affect the child). However, the window must have the same visual type as the parent (or a Match error results), and the parent must not have a colormap of None (or a Match error results). For an explanation of None, see FreeColormap request. The colormap is copied by sharing the colormap object between the child and the parent, not by making a complete copy of the colormap contents.

If a cursor is specified, it will be used whenever the pointer is in the window. If None is specified, the parent’s cursor will be used when the pointer is in the window, and any change in the parent’s cursor will cause an immediate change in the displayed cursor.

This request generates a CreateNotify event.

The background and border pixmaps and the cursor may be freed immediately if no further explicit references to them are to be made.

Subsequent drawing into the background or border pixmap has an undefined effect on the window state. The server might or might not make a copy of the pixmap. __ │
ChangeWindowAttributes

window: WINDOW
value-mask: BITMASK
value-list: LISTofVALUE

Errors: Access, Colormap, Cursor, Match, Pixmap, Value,
Window│__

The value-mask and value-list specify which attributes are to be changed. The values and restrictions are the same as for CreateWindow.

Setting a new background, whether by background-pixmap or background-pixel, overrides any previous background. Setting a new border, whether by border-pixel or border-pixmap, overrides any previous border.

Changing the background does not cause the window contents to be changed. Setting the border or changing the background such that the border tile origin changes causes the border to be repainted. Changing the background of a root window to None or ParentRelative restores the default background pixmap. Changing the border of a root window to CopyFromParent restores the default border pixmap.

Changing the win-gravity does not affect the current position of the window.

Changing the backing-store of an obscured window to WhenMapped or Always or changing the backing-planes, backing-pixel, or save-under of a mapped window may have no immediate effect.

Multiple clients can select input on the same window; their event-masks are disjoint. When an event is generated, it will be reported to all interested clients. However, only one client at a time can select for SubstructureRedirect, only one client at a time can select for ResizeRedirect, and only one client at a time can select for ButtonPress. An attempt to violate these restrictions results in an Access error.

There is only one do-not-propagate-mask for a window, not one per client.

Changing the colormap of a window (by defining a new map, not by changing the contents of the existing map) generates a ColormapNotify event. Changing the colormap of a visible window might have no immediate effect on the screen (see InstallColormap request).

Changing the cursor of a root window to None restores the default cursor.

The order in which attributes are verified and altered is server-dependent. If an error is generated, a subset of the attributes may have been altered. __ │
GetWindowAttributes

window: WINDOW

→

visual: VISUALID
class: {InputOutput, InputOnly}
bit-gravity: BITGRAVITY
win-gravity: WINGRAVITY
backing-store: {NotUseful, WhenMapped, Always}
backing-planes: CARD32
backing-pixel: CARD32
save-under: BOOL
colormap: COLORMAP or None
map-is-installed: BOOL
map-state: {Unmapped, Unviewable, Viewable}
all-event-masks, your-event-mask: SETofEVENT
do-not-propagate-mask: SETofDEVICEEVENT
override-redirect: BOOL

Errors: Window│__

This request returns the current attributes of the window. A window is Unviewable if it is mapped but some ancestor is unmapped. All-event-masks is the inclusive-OR of all event masks selected on the window by clients. Your-event-mask is the event mask selected by the querying client. __ │
DestroyWindow

window: WINDOW

Errors: Window│__

If the argument window is mapped, an UnmapWindow request is performed automatically. The window and all inferiors are then destroyed, and a DestroyNotify event is generated for each window. The ordering of the DestroyNotify events is such that for any given window, DestroyNotify is generated on all inferiors of the window before being generated on the window itself. The ordering among siblings and across subhierarchies is not otherwise constrained.

Normal exposure processing on formerly obscured windows is performed.

If the window is a root window, this request has no effect. __ │
DestroySubwindows

window: WINDOW

Errors: Window│__

This request performs a DestroyWindow request on all children of the window, in bottom-to-top stacking order. __ │
ChangeSaveSet

window: WINDOW
mode: {Insert, Delete}

Errors:

Match, Value, Window│__

This request adds or removes the specified window from the client’s save-set. The window must have been created by some other client (or a Match error results). For further information about the use of the save-set, see section 10.

When windows are destroyed, the server automatically removes them from the save-set. __ │
ReparentWindow

window, parent: WINDOW
x, y: INT16

Errors: Match, Window│__

If the window is mapped, an UnmapWindow request is performed automatically first. The window is then removed from its current position in the hierarchy and is inserted as a child of the specified parent. The x and y coordinates are relative to the parent’s origin and specify the new position of the upper-left outer corner of the window. The window is placed on top in the stacking order with respect to siblings. A ReparentNotify event is then generated. The override-redirect attribute of the window is passed on in this event; a value of True indicates that a window manager should not tamper with this window. Finally, if the window was originally mapped, a MapWindow request is performed automatically.

Normal exposure processing on formerly obscured windows is performed. The server might not generate exposure events for regions from the initial unmap that are immediately obscured by the final map.

A Match error is generated if:

MapWindow

window: WINDOW

Errors: Window│__

If the window is already mapped, this request has no effect.

If the override-redirect attribute of the window is False and some other client has selected SubstructureRedirect on the parent, then a MapRequest event is generated, but the window remains unmapped. Otherwise, the window is mapped, and a MapNotify event is generated.

If the window is now viewable and its contents have been discarded, the window is tiled with its background (if no background is defined, the existing screen contents are not altered), and zero or more exposure events are generated. If a backing-store has been maintained while the window was unmapped, no exposure events are generated. If a backing-store will now be maintained, a full-window exposure is always generated. Otherwise, only visible regions may be reported. Similar tiling and exposure take place for any newly viewable inferiors. __ │
MapSubwindows

window: WINDOW

Errors: Window│__

This request performs a MapWindow request on all unmapped children of the window, in top-to-bottom stacking order. __ │
UnmapWindow

window: WINDOW

Errors: Window│__

If the window is already unmapped, this request has no effect. Otherwise, the window is unmapped, and an UnmapNotify event is generated. Normal exposure processing on formerly obscured windows is performed. __ │
UnmapSubwindows

window: WINDOW

Errors: Window│__

This request performs an UnmapWindow request on all mapped children of the window, in bottom-to-top stacking order. __ │
ConfigureWindow

window: WINDOW
value-mask: BITMASK
value-list: LISTofVALUE

Errors: Match, Value, Window│__

This request changes the configuration of the window. The value-mask and value-list specify which values are to be given. The possible values are:
Attribute Type
x
INT16
y
INT16
width
CARD16
height
CARD16
border-width
CARD16
sibling
WINDOW
stack-mode
{Above, Below, TopIf, BottomIf,
Opposite}

The x and y coordinates are relative to the parent’s origin and specify the position of the upper-left outer corner of the window. The width and height specify the inside size, not including the border, and must be nonzero (or a Value error results). Those values not specified are taken from the existing geometry of the window. Note that changing just the border-width leaves the outer-left corner of the window in a fixed position but moves the absolute position of the window’s origin. It is a Match error to attempt to make the border-width of an InputOnly window nonzero.

If the override-redirect attribute of the window is False and some other client has selected SubstructureRedirect on the parent, a ConfigureRequest event is generated, and no further processing is performed. Otherwise, the following is performed:

If some other client has selected ResizeRedirect on the window and the inside width or height of the window is being changed, a ResizeRequest event is generated, and the current inside width and height are used instead. Note that the override-redirect attribute of the window has no effect on ResizeRedirect and that SubstructureRedirect on the parent has precedence over ResizeRedirect on the window.

The geometry of the window is changed as specified, the window is restacked among siblings, and a ConfigureNotify event is generated if the state of the window actually changes. If the inside width or height of the window has actually changed, then children of the window are affected, according to their win-gravity. Exposure processing is performed on formerly obscured windows (including the window itself and its inferiors if regions of them were obscured but now are not). Exposure processing is also performed on any new regions of the window (as a result of increasing the width or height) and on any regions where window contents are lost.

If the inside width or height of a window is not changed but the window is moved or its border is changed, then the contents of the window are not lost but move with the window. Changing the inside width or height of the window causes its contents to be moved or lost, depending on the bit-gravity of the window. It also causes children to be reconfigured, depending on their win-gravity. For a change of width and height of W and H, we define the [x, y] pairs as:
Direction Deltas
NorthWest
[0, 0]
North
[W/2, 0]
NorthEast
[W, 0]
West
[0, H/2]
Center
[W/2, H/2]
East
[W, H/2]
SouthWest
[0, H]
South
[W/2, H]
SouthEast
[W, H]

When a window with one of these bit-gravities is resized, the corresponding pair defines the change in position of each pixel in the window. When a window with one of these win-gravities has its parent window resized, the corresponding pair defines the change in position of the window within the parent. This repositioning generates a GravityNotify event. GravityNotify events are generated after the ConfigureNotify event is generated.

A gravity of Static indicates that the contents or origin should not move relative to the origin of the root window. If the change in size of the window is coupled with a change in position of [X, Y], then for bit-gravity the change in position of each pixel is [−X, −Y] and for win-gravity the change in position of a child when its parent is so resized is [−X, −Y]. Note that Static gravity still only takes effect when the width or height of the window is changed, not when the window is simply moved.

A bit-gravity of Forget indicates that the window contents are always discarded after a size change, even if backing-store or save-under has been requested. The window is tiled with its background (except, if no background is defined, the existing screen contents are not altered) and zero or more exposure events are generated.

The contents and borders of inferiors are not affected by their parent’s bit-gravity. A server is permitted to ignore the specified bit-gravity and use Forget instead.

A win-gravity of Unmap is like NorthWest, but the child is also unmapped when the parent is resized, and an UnmapNotify event is generated. UnmapNotify events are generated after the ConfigureNotify event is generated.

If a sibling and a stack-mode are specified, the window is restacked as follows:
Above
The window is placed just above the sibling.
Below
The window is placed just below the sibling.
TopIf
If the sibling occludes the window, then the
window is placed at the top of the stack.
BottomIf
If the window occludes the sibling, then the
window is placed at the bottom of the stack.
Opposite
If the sibling occludes the window, then the
window is placed at the top of the stack.
Otherwise, if the window occludes the sibling,
then the window is placed at the bottom of the
stack.

If a stack-mode is specified but no sibling is specified, the window is restacked as follows:
Above
The window is placed at the top of the stack.
Below
The window is placed at the bottom of the
stack.
TopIf
If any sibling occludes the window, then the
window is placed at the top of the stack.
BottomIf
If the window occludes any sibling, then the
window is placed at the bottom of the stack.
Opposite
If any sibling occludes the window, then the
window is placed at the top of the stack.
Otherwise, if the window occludes any sibling,
then the window is placed at the bottom of the
stack.

It is a Match error if a sibling is specified without a stack-mode or if the window is not actually a sibling.

Note that the computations for BottomIf, TopIf, and Opposite are performed with respect to the window’s final geometry (as controlled by the other arguments to the request), not to its initial geometry.

Attempts to configure a root window have no effect. __ │
CirculateWindow

window: WINDOW
direction: {RaiseLowest, LowerHighest}

Errors: Value, Window│__

If some other client has selected SubstructureRedirect on the window, then a CirculateRequest event is generated, and no further processing is performed. Otherwise, the following is performed, and then a CirculateNotify event is generated if the window is actually restacked.

For RaiseLowest, CirculateWindow raises the lowest mapped child (if any) that is occluded by another child to the top of the stack. For LowerHighest, CirculateWindow lowers the highest mapped child (if any) that occludes another child to the bottom of the stack. Exposure processing is performed on formerly obscured windows. __ │
GetGeometry

drawable: DRAWABLE

→

root: WINDOW
depth: CARD8
x, y: INT16
width, height, border-width: CARD16

Errors: Drawable│__

This request returns the root and current geometry of the drawable. The depth is the number of bits per pixel for the object. The x, y, and border-width will always be zero for pixmaps. For a window, the x and y coordinates specify the upper-left outer corner of the window relative to its parent’s origin, and the width and height specify the inside size, not including the border.

It is legal to pass an InputOnly window as a drawable to this request. __ │
QueryTree

window: WINDOW

→

root: WINDOW
parent: WINDOW or None
children: LISTofWINDOW

Errors: Window│__

This request returns the root, the parent, and the children of the window. The children are listed in bottom-to-top stacking order. __ │
InternAtom

name: STRING8
only-if-exists: BOOL

→

atom: ATOM or None

Errors: Alloc, Value│__

This request returns the atom for the given name. If only-if-exists is False, then the atom is created if it does not exist. The string should use the ISO Latin-1 encoding. Uppercase and lowercase matter.

The lifetime of an atom is not tied to the interning client. Atoms remain defined until server reset (see section 10). __ │
GetAtomName

atom: ATOM

→

name: STRING8

Errors: Atom│__

This request returns the name for the given atom. __ │
ChangeProperty

window: WINDOW
property, type: ATOM
format: {8, 16, 32}
mode: {Replace, Prepend, Append}
data: LISTofINT8 or LISTofINT16 or LISTofINT32

Errors: Alloc, Atom, Match, Value, Window│__

This request alters the property for the specified window. The type is uninterpreted by the server. The format specifies whether the data should be viewed as a list of 8-bit, 16-bit, or 32-bit quantities so that the server can correctly byte-swap as necessary.

If the mode is Replace, the previous property value is discarded. If the mode is Prepend or Append, then the type and format must match the existing property value (or a Match error results). If the property is undefined, it is treated as defined with the correct type and format with zero-length data. For Prepend, the data is tacked on to the beginning of the existing data, and for Append, it is tacked on to the end of the existing data.

This request generates a PropertyNotify event on the window.

The lifetime of a property is not tied to the storing client. Properties remain until explicitly deleted, until the window is destroyed, or until server reset (see section 10).

The maximum size of a property is server-dependent and may vary dynamically. __ │
DeleteProperty

window: WINDOW
property: ATOM

Errors: Atom, Window│__

This request deletes the property from the specified window if the property exists and generates a PropertyNotify event on the window unless the property does not exist. __ │
GetProperty

window: WINDOW
property: ATOM
type: ATOM or AnyPropertyType
long-offset, long-length: CARD32
delete: BOOL

→

type: ATOM or None
format: {0, 8, 16, 32}
bytes-after: CARD32
value: LISTofINT8 or LISTofINT16 or LISTofINT32

Errors: Atom, Value, Window│__

If the specified property does not exist for the specified window, then the return type is None, the format and bytes-after are zero, and the value is empty. The delete argument is ignored in this case. If the specified property exists but its type does not match the specified type, then the return type is the actual type of the property, the format is the actual format of the property (never zero), the bytes-after is the length of the property in bytes (even if the format is 16 or 32), and the value is empty. The delete argument is ignored in this case. If the specified property exists and either AnyPropertyType is specified or the specified type matches the actual type of the property, then the return type is the actual type of the property, the format is the actual format of the property (never zero), and the bytes-after and value are as follows, given:

N = actual length of the stored property in bytes     
(even if the format is 16 or 32)
I = 4 * long-offset
T = N − I
L = MINIMUM(T, 4 * long-length)
A = N − (I + L)

The returned value starts at byte index I in the property (indexing from 0), and its length in bytes is L. However, it is a Value error if long-offset is given such that L is negative. The value of bytes-after is A, giving the number of trailing unread bytes in the stored property. If delete is True and the bytes-after is zero, the property is also deleted from the window, and a PropertyNotify event is generated on the window. __ │
RotateProperties

window: WINDOW
delta: INT16
properties: LISTofATOM

Errors: Atom, Match, Window│__

If the property names in the list are viewed as being numbered starting from zero, and there are N property names in the list, then the value associated with property name I becomes the value associated with property name (I + delta) mod N, for all I from zero to N − 1. The effect is to rotate the states by delta places around the virtual ring of property names (right for positive delta, left for negative delta).

If delta mod N is nonzero, a PropertyNotify event is generated for each property in the order listed.

If an atom occurs more than once in the list or no property with that name is defined for the window, a Match error is generated. If an Atom or Match error is generated, no properties are changed. __ │
ListProperties

window: WINDOW

→

atoms: LISTofATOM

Errors: Window│__

This request returns the atoms of properties currently defined on the window. __ │
SetSelectionOwner

selection: ATOM
owner: WINDOW or None
time: TIMESTAMP or CurrentTime

Errors: Atom, Window│__

This request changes the owner, owner window, and last-change time of the specified selection. This request has no effect if the specified time is earlier than the current last-change time of the specified selection or is later than the current server time. Otherwise, the last-change time is set to the specified time with CurrentTime replaced by the current server time. If the owner window is specified as None, then the owner of the selection becomes None (that is, no owner). Otherwise, the owner of the selection becomes the client executing the request. If the new owner (whether a client or None) is not the same as the current owner and the current owner is not None, then the current owner is sent a SelectionClear event.

If the client that is the owner of a selection is later terminated (that is, its connection is closed) or if the owner window it has specified in the request is later destroyed, then the owner of the selection automatically reverts to None, but the last-change time is not affected.

The selection atom is uninterpreted by the server. The owner window is returned by the GetSelectionOwner request and is reported in SelectionRequest and SelectionClear events.

Selections are global to the server. __ │
GetSelectionOwner

selection: ATOM

→

owner: WINDOW or None

Errors: Atom│__

This request returns the current owner window of the specified selection, if any. If None is returned, then there is no owner for the selection. __ │
ConvertSelection

selection, target: ATOM
property: ATOM or None
requestor: WINDOW
time: TIMESTAMP or CurrentTime

Errors: Atom, Window│__

If the specified selection has an owner, the server sends a SelectionRequest event to that owner. If no owner for the specified selection exists, the server generates a SelectionNotify event to the requestor with property None. The arguments are passed on unchanged in either of the events. __ │
SendEvent

destination: WINDOW or PointerWindow or InputFocus
propagate: BOOL
event-mask: SETofEVENT
event: <normal-event-format>

Errors: Value, Window│__

If PointerWindow is specified, destination is replaced with the window that the pointer is in. If InputFocus is specified and the focus window contains the pointer, destination is replaced with the window that the pointer is in. Otherwise, destination is replaced with the focus window.

If the event-mask is the empty set, then the event is sent to the client that created the destination window. If that client no longer exists, no event is sent.

If propagate is False, then the event is sent to every client selecting on destination any of the event types in event-mask.

If propagate is True and no clients have selected on destination any of the event types in event-mask, then destination is replaced with the closest ancestor of destination for which some client has selected a type in event-mask and no intervening window has that type in its do-not-propagate-mask. If no such window exists or if the window is an ancestor of the focus window and InputFocus was originally specified as the destination, then the event is not sent to any clients. Otherwise, the event is reported to every client selecting on the final destination any of the types specified in event-mask.

The event code must be one of the core events or one of the events defined by an extension (or a Value error results) so that the server can correctly byte-swap the contents as necessary. The contents of the event are otherwise unaltered and unchecked by the server except to force on the most significant bit of the event code and to set the sequence number in the event correctly.

Active grabs are ignored for this request. __ │
GrabPointer

grab-window: WINDOW
owner-events: BOOL
event-mask: SETofPOINTEREVENT
pointer-mode, keyboard-mode: {Synchronous, Asynchronous}
confine-to: WINDOW or None
cursor: CURSOR or None
time: TIMESTAMP or CurrentTime

→

status: {Success, AlreadyGrabbed, Frozen, InvalidTime,
NotViewable}

Errors: Cursor, Value, Window│__

This request actively grabs control of the pointer. Further pointer events are only reported to the grabbing client. The request overrides any active pointer grab by this client.

If owner-events is False, all generated pointer events are reported with respect to grab-window and are only reported if selected by event-mask. If owner-events is True and a generated pointer event would normally be reported to this client, it is reported normally. Otherwise, the event is reported with respect to the grab-window and is only reported if selected by event-mask. For either value of owner-events, unreported events are simply discarded.

If pointer-mode is Asynchronous, pointer event processing continues normally. If the pointer is currently frozen by this client, then processing of pointer events is resumed. If pointer-mode is Synchronous, the state of the pointer (as seen by means of the protocol) appears to freeze, and no further pointer events are generated by the server until the grabbing client issues a releasing AllowEvents request or until the pointer grab is released. Actual pointer changes are not lost while the pointer is frozen. They are simply queued for later processing.

If keyboard-mode is Asynchronous, keyboard event processing is unaffected by activation of the grab. If keyboard-mode is Synchronous, the state of the keyboard (as seen by means of the protocol) appears to freeze, and no further keyboard events are generated by the server until the grabbing client issues a releasing AllowEvents request or until the pointer grab is released. Actual keyboard changes are not lost while the keyboard is frozen. They are simply queued for later processing.

If a cursor is specified, then it is displayed regardless of what window the pointer is in. If no cursor is specified, then when the pointer is in grab-window or one of its subwindows, the normal cursor for that window is displayed. Otherwise, the cursor for grab-window is displayed.

If a confine-to window is specified, then the pointer will be restricted to stay contained in that window. The confine-to window need have no relationship to the grab-window. If the pointer is not initially in the confine-to window, then it is warped automatically to the closest edge (and enter/leave events are generated normally) just before the grab activates. If the confine-to window is subsequently reconfigured, the pointer will be warped automatically as necessary to keep it contained in the window.

This request generates EnterNotify and LeaveNotify events.

The request fails with status AlreadyGrabbed if the pointer is actively grabbed by some other client. The request fails with status Frozen if the pointer is frozen by an active grab of another client. The request fails with status NotViewable if grab-window or confine-to window is not viewable or if the confine-to window lies completely outside the boundaries of the root window. The request fails with status InvalidTime if the specified time is earlier than the last-pointer-grab time or later than the current server time. Otherwise, the last-pointer-grab time is set to the specified time, with CurrentTime replaced by the current server time. __ │
UngrabPointer

time: TIMESTAMP or CurrentTime│__

This request releases the pointer if this client has it actively grabbed (from either GrabPointer or GrabButton or from a normal button press) and releases any queued events. The request has no effect if the specified time is earlier than the last-pointer-grab time or is later than the current server time.

This request generates EnterNotify and LeaveNotify events.

An UngrabPointer request is performed automatically if the event window or confine-to window for an active pointer grab becomes not viewable or if window reconfiguration causes the confine-to window to lie completely outside the boundaries of the root window. __ │
GrabButton

modifiers: SETofKEYMASK or AnyModifier
button: BUTTON or AnyButton
grab-window: WINDOW
owner-events: BOOL
event-mask: SETofPOINTEREVENT
pointer-mode, keyboard-mode: {Synchronous, Asynchronous}
confine-to: WINDOW or None
cursor: CURSOR or None

Errors: Access, Cursor, Value, Window│__

This request establishes a passive grab. In the future, the pointer is actively grabbed as described in GrabPointer, the last-pointer-grab time is set to the time at which the button was pressed (as transmitted in the ButtonPress event), and the ButtonPress event is reported if all of the following conditions are true:

The interpretation of the remaining arguments is the same as for GrabPointer. The active grab is terminated automatically when the logical state of the pointer has all buttons released, independent of the logical state of modifier keys. Note that the logical state of a device (as seen by means of the protocol) may lag the physical state if device event processing is frozen.

This request overrides all previous passive grabs by the same client on the same button/key combinations on the same window. A modifier of AnyModifier is equivalent to issuing the request for all possible modifier combinations (including the combination of no modifiers). It is not required that all specified modifiers have currently assigned keycodes. A button of AnyButton is equivalent to issuing the request for all possible buttons. Otherwise, it is not required that the button specified currently be assigned to a physical button.

An Access error is generated if some other client has already issued a GrabButton request with the same button/key combination on the same window. When using AnyModifier or AnyButton, the request fails completely (no grabs are established), and an Access error is generated if there is a conflicting grab for any combination. The request has no effect on an active grab. __ │
UngrabButton

modifiers: SETofKEYMASK or AnyModifier
button: BUTTON or AnyButton
grab-window: WINDOW

Errors: Value, Window│__

This request releases the passive button/key combination on the specified window if it was grabbed by this client. A modifiers argument of AnyModifier is equivalent to issuing the request for all possible modifier combinations (including the combination of no modifiers). A button of AnyButton is equivalent to issuing the request for all possible buttons. The request has no effect on an active grab. __ │
ChangeActivePointerGrab

event-mask: SETofPOINTEREVENT
cursor: CURSOR or None
time: TIMESTAMP or CurrentTime

Errors: Cursor, Value│__

This request changes the specified dynamic parameters if the pointer is actively grabbed by the client and the specified time is no earlier than the last-pointer-grab time and no later than the current server time. The interpretation of event-mask and cursor are the same as in GrabPointer. This request has no effect on the parameters of any passive grabs established with GrabButton. __ │
GrabKeyboard

grab-window: WINDOW
owner-events: BOOL
pointer-mode, keyboard-mode: {Synchronous, Asynchronous}
time: TIMESTAMP or CurrentTime

→

status: {Success, AlreadyGrabbed, Frozen, InvalidTime,
NotViewable}

Errors: Value, Window│__

This request actively grabs control of the keyboard. Further key events are reported only to the grabbing client. This request overrides any active keyboard grab by this client.

If owner-events is False, all generated key events are reported with respect to grab-window. If owner-events is True and if a generated key event would normally be reported to this client, it is reported normally. Otherwise, the event is reported with respect to the grab-window. Both KeyPress and KeyRelease events are always reported, independent of any event selection made by the client.

If keyboard-mode is Asynchronous, keyboard event processing continues normally. If the keyboard is currently frozen by this client, then processing of keyboard events is resumed. If keyboard-mode is Synchronous, the state of the keyboard (as seen by means of the protocol) appears to freeze. No further keyboard events are generated by the server until the grabbing client issues a releasing AllowEvents request or until the keyboard grab is released. Actual keyboard changes are not lost while the keyboard is frozen. They are simply queued for later processing.

If pointer-mode is Asynchronous, pointer event processing is unaffected by activation of the grab. If pointer-mode is Synchronous, the state of the pointer (as seen by means of the protocol) appears to freeze. No further pointer events are generated by the server until the grabbing client issues a releasing AllowEvents request or until the keyboard grab is released. Actual pointer changes are not lost while the pointer is frozen. They are simply queued for later processing.

This request generates FocusIn and FocusOut events.

The request fails with status AlreadyGrabbed if the keyboard is actively grabbed by some other client. The request fails with status Frozen if the keyboard is frozen by an active grab of another client. The request fails with status NotViewable if grab-window is not viewable. The request fails with status InvalidTime if the specified time is earlier than the last-keyboard-grab time or later than the current server time. Otherwise, the last-keyboard-grab time is set to the specified time with CurrentTime replaced by the current server time. __ │
UngrabKeyboard

time: TIMESTAMP or CurrentTime│__

This request releases the keyboard if this client has it actively grabbed (as a result of either GrabKeyboard or GrabKey) and releases any queued events. The request has no effect if the specified time is earlier than the last-keyboard-grab time or is later than the current server time.

This request generates FocusIn and FocusOut events.

An UngrabKeyboard is performed automatically if the event window for an active keyboard grab becomes not viewable. __ │
GrabKey

key: KEYCODE or AnyKey
modifiers: SETofKEYMASK or AnyModifier
grab-window: WINDOW
owner-events: BOOL
pointer-mode, keyboard-mode: {Synchronous, Asynchronous}

Errors: Access, Value, Window│__

This request establishes a passive grab on the keyboard. In the future, the keyboard is actively grabbed as described in GrabKeyboard, the last-keyboard-grab time is set to the time at which the key was pressed (as transmitted in the KeyPress event), and the KeyPress event is reported if all of the following conditions are true:

The interpretation of the remaining arguments is the same as for GrabKeyboard. The active grab is terminated automatically when the logical state of the keyboard has the specified key released, independent of the logical state of modifier keys. Note that the logical state of a device (as seen by means of the protocol) may lag the physical state if device event processing is frozen.

This request overrides all previous passive grabs by the same client on the same key combinations on the same window. A modifier of AnyModifier is equivalent to issuing the request for all possible modifier combinations (including the combination of no modifiers). It is not required that all modifiers specified have currently assigned keycodes. A key of AnyKey is equivalent to issuing the request for all possible keycodes. Otherwise, the key must be in the range specified by min-keycode and max-keycode in the connection setup (or a Value error results).

An Access error is generated if some other client has issued a GrabKey with the same key combination on the same window. When using AnyModifier or AnyKey, the request fails completely (no grabs are established), and an Access error is generated if there is a conflicting grab for any combination. __ │
UngrabKey

key: KEYCODE or AnyKey
modifiers: SETofKEYMASK or AnyModifier
grab-window: WINDOW

Errors: Value, Window│__

This request releases the key combination on the specified window if it was grabbed by this client. A modifiers argument of AnyModifier is equivalent to issuing the request for all possible modifier combinations (including the combination of no modifiers). A key of AnyKey is equivalent to issuing the request for all possible keycodes. This request has no effect on an active grab. __ │
AllowEvents

mode: {AsyncPointer, SyncPointer, ReplayPointer, AsyncKey-
board,           
SyncKeyboard, ReplayKeyboard, AsyncBoth,
SyncBoth}
time: TIMESTAMP or CurrentTime

Errors: Value│__

This request releases some queued events if the client has caused a device to freeze. The request has no effect if the specified time is earlier than the last-grab time of the most recent active grab for the client or if the specified time is later than the current server time.

For AsyncPointer, if the pointer is frozen by the client, pointer event processing continues normally. If the pointer is frozen twice by the client on behalf of two separate grabs, AsyncPointer thaws for both. AsyncPointer has no effect if the pointer is not frozen by the client, but the pointer need not be grabbed by the client.

For SyncPointer, if the pointer is frozen and actively grabbed by the client, pointer event processing continues normally until the next ButtonPress or ButtonRelease event is reported to the client, at which time the pointer again appears to freeze. However, if the reported event causes the pointer grab to be released, then the pointer does not freeze. SyncPointer has no effect if the pointer is not frozen by the client or if the pointer is not grabbed by the client.

For ReplayPointer, if the pointer is actively grabbed by the client and is frozen as the result of an event having been sent to the client (either from the activation of a GrabButton or from a previous AllowEvents with mode SyncPointer but not from a GrabPointer), then the pointer grab is released and that event is completely reprocessed, this time ignoring any passive grabs at or above (towards the root) the grab-window of the grab just released. The request has no effect if the pointer is not grabbed by the client or if the pointer is not frozen as the result of an event.

For AsyncKeyboard, if the keyboard is frozen by the client, keyboard event processing continues normally. If the keyboard is frozen twice by the client on behalf of two separate grabs, AsyncKeyboard thaws for both. AsyncKeyboard has no effect if the keyboard is not frozen by the client, but the keyboard need not be grabbed by the client.

For SyncKeyboard, if the keyboard is frozen and actively grabbed by the client, keyboard event processing continues normally until the next KeyPress or KeyRelease event is reported to the client, at which time the keyboard again appears to freeze. However, if the reported event causes the keyboard grab to be released, then the keyboard does not freeze. SyncKeyboard has no effect if the keyboard is not frozen by the client or if the keyboard is not grabbed by the client.

For ReplayKeyboard, if the keyboard is actively grabbed by the client and is frozen as the result of an event having been sent to the client (either from the activation of a GrabKey or from a previous AllowEvents with mode SyncKeyboard but not from a GrabKeyboard), then the keyboard grab is released and that event is completely reprocessed, this time ignoring any passive grabs at or above (towards the root) the grab-window of the grab just released. The request has no effect if the keyboard is not grabbed by the client or if the keyboard is not frozen as the result of an event.

For SyncBoth, if both pointer and keyboard are frozen by the client, event processing (for both devices) continues normally until the next ButtonPress, ButtonRelease, KeyPress, or KeyRelease event is reported to the client for a grabbed device (button event for the pointer, key event for the keyboard), at which time the devices again appear to freeze. However, if the reported event causes the grab to be released, then the devices do not freeze (but if the other device is still grabbed, then a subsequent event for it will still cause both devices to freeze). SyncBoth has no effect unless both pointer and keyboard are frozen by the client. If the pointer or keyboard is frozen twice by the client on behalf of two separate grabs, SyncBoth thaws for both (but a subsequent freeze for SyncBoth will only freeze each device once).

For AsyncBoth, if the pointer and the keyboard are frozen by the client, event processing for both devices continues normally. If a device is frozen twice by the client on behalf of two separate grabs, AsyncBoth thaws for both. AsyncBoth has no effect unless both pointer and keyboard are frozen by the client.

AsyncPointer, SyncPointer, and ReplayPointer have no effect on processing of keyboard events. AsyncKeyboard, SyncKeyboard, and ReplayKeyboard have no effect on processing of pointer events.

It is possible for both a pointer grab and a keyboard grab to be active simultaneously (by the same or different clients). When a device is frozen on behalf of either grab, no event processing is performed for the device. It is possible for a single device to be frozen because of both grabs. In this case, the freeze must be released on behalf of both grabs before events can again be processed. If a device is frozen twice by a single client, then a single AllowEvents releases both. __ │
GrabServer│__

This request disables processing of requests and close-downs on all connections other than the one this request arrived on. __ │
UngrabServer│__

This request restarts processing of requests and close-downs on other connections. __ │
QueryPointer

window: WINDOW

→

root: WINDOW
child: WINDOW or None
same-screen: BOOL
root-x, root-y, win-x, win-y: INT16
mask: SETofKEYBUTMASK

Errors: Window│__

The root window the pointer is logically on and the pointer coordinates relative to the root’s origin are returned. If same-screen is False, then the pointer is not on the same screen as the argument window, child is None, and win-x and win-y are zero. If same-screen is True, then win-x and win-y are the pointer coordinates relative to the argument window’s origin, and child is the child containing the pointer, if any. The current logical state of the modifier keys and the buttons are also returned. Note that the logical state of a device (as seen by means of the protocol) may lag the physical state if device event processing is frozen. __ │
GetMotionEvents

start, stop: TIMESTAMP or CurrentTime
window: WINDOW

→

events: LISTofTIMECOORD

where:

TIMECOORD: [x, y: INT16  
time: TIMESTAMP]

Errors: Window│__

This request returns all events in the motion history buffer that fall between the specified start and stop times (inclusive) and that have coordinates that lie within (including borders) the specified window at its present placement. The x and y coordinates are reported relative to the origin of the window.

If the start time is later than the stop time or if the start time is in the future, no events are returned. If the stop time is in the future, it is equivalent to specifying CurrentTime. __ │
TranslateCoordinates

src-window, dst-window: WINDOW
src-x, src-y: INT16

→

same-screen: BOOL
child: WINDOW or None
dst-x, dst-y: INT16

Errors: Window│__

The src-x and src-y coordinates are taken relative to src-window’s origin and are returned as dst-x and dst-y coordinates relative to dst-window’s origin. If same-screen is False, then src-window and dst-window are on different screens, and dst-x and dst-y are zero. If the coordinates are contained in a mapped child of dst-window, then that child is returned. __ │
WarpPointer

src-window: WINDOW or None
dst-window: WINDOW or None
src-x, src-y: INT16
src-width, src-height: CARD16
dst-x, dst-y: INT16

Errors: Window│__

If dst-window is None, this request moves the pointer by offsets [dst-x, dst-y] relative to the current position of the pointer. If dst-window is a window, this request moves the pointer to [dst-x, dst-y] relative to dst-window’s origin. However, if src-window is not None, the move only takes place if src-window contains the pointer and the pointer is contained in the specified rectangle of src-window.

The src-x and src-y coordinates are relative to src-window’s origin. If src-height is zero, it is replaced with the current height of src-window minus src-y. If src-width is zero, it is replaced with the current width of src-window minus src-x.

This request cannot be used to move the pointer outside the confine-to window of an active pointer grab. An attempt will only move the pointer as far as the closest edge of the confine-to window.

This request will generate events just as if the user had instantaneously moved the pointer. __ │
SetInputFocus

focus: WINDOW or PointerRoot or None
revert-to: {Parent, PointerRoot, None}
time: TIMESTAMP or CurrentTime

Errors: Match, Value, Window│__

This request changes the input focus and the last-focus-change time. The request has no effect if the specified time is earlier than the current last-focus-change time or is later than the current server time. Otherwise, the last-focus-change time is set to the specified time with CurrentTime replaced by the current server time.

If None is specified as the focus, all keyboard events are discarded until a new focus window is set. In this case, the revert-to argument is ignored.

If a window is specified as the focus, it becomes the keyboard’s focus window. If a generated keyboard event would normally be reported to this window or one of its inferiors, the event is reported normally. Otherwise, the event is reported with respect to the focus window.

If PointerRoot is specified as the focus, the focus window is dynamically taken to be the root window of whatever screen the pointer is on at each keyboard event. In this case, the revert-to argument is ignored.

This request generates FocusIn and FocusOut events.

The specified focus window must be viewable at the time of the request (or a Match error results). If the focus window later becomes not viewable, the new focus window depends on the revert-to argument. If revert-to is Parent, the focus reverts to the parent (or the closest viewable ancestor) and the new revert-to value is taken to be None. If revert-to is PointerRoot or None, the focus reverts to that value. When the focus reverts, FocusIn and FocusOut events are generated, but the last-focus-change time is not affected. __ │
GetInputFocus

→

focus: WINDOW or PointerRoot or None
revert-to: {Parent, PointerRoot, None}│__

This request returns the current focus state. __ │
QueryKeymap

→

keys: LISTofCARD8│__

This request returns a bit vector for the logical state of the keyboard. Each bit set to 1 indicates that the corresponding key is currently pressed. The vector is represented as 32 bytes. Byte N (from 0) contains the bits for keys 8N to 8N + 7 with the least significant bit in the byte representing key 8N. Note that the logical state of a device (as seen by means of the protocol) may lag the physical state if device event processing is frozen. __ │
OpenFont

fid: FONT
name: STRING8

Errors: Alloc, IDChoice, Name│__

This request loads the specified font, if necessary, and associates identifier fid with it. The font name should use the ISO Latin-1 encoding, and uppercase and lowercase do not matter. When the characters ‘‘?’’ and ‘‘*’’ are used in a font name, a pattern match is performed and any matching font is used. In the pattern, the ‘‘?’’ character (octal value 77) will match any single character, and the ‘‘*’’ character (octal value 52) will match any number of characters. A structured format for font names is specified in the X.Org standard X Logical Font Description Conventions.

Fonts are not associated with a particular screen and can be stored as a component of any graphics context. __ │
CloseFont

font: FONT

Errors: Font│__

This request deletes the association between the resource ID and the font. The font itself will be freed when no other resource references it. __ │
QueryFont

font: FONTABLE

→

font-info: FONTINFO
char-infos: LISTofCHARINFO

where:

FONTINFO:
[draw-direction: {LeftToRight, RightToLeft}  

min-char-or-byte2, max-char-or-byte2: CARD16  
min-byte1, max-byte1: CARD8  
all-chars-exist: BOOL  
default-char: CARD16  
min-bounds: CHARINFO  
max-bounds: CHARINFO  
font-ascent: INT16  
font-descent: INT16  
properties: LISTofFONTPROP]
FONTPROP: [name: ATOM  
value: <32-bit-value>]
CHARINFO: [left-side-bearing: INT16  
right-side-bearing: INT16  
character-width: INT16  
ascent: INT16  
descent: INT16  
attributes: CARD16]

Errors: Font│__

This request returns logical information about a font. If a gcontext is given for font, the currently contained font is used.

The draw-direction is just a hint and indicates whether most char-infos have a positive, LeftToRight, or a negative, RightToLeft, character-width metric. The core protocol defines no support for vertical text.

If min-byte1 and max-byte1 are both zero, then min-char-or-byte2 specifies the linear character index corresponding to the first element of char-infos, and max-char-or-byte2 specifies the linear character index of the last element. If either min-byte1 or max-byte1 are nonzero, then both min-char-or-byte2 and max-char-or-byte2 will be less than 256, and the 2-byte character index values corresponding to char-infos element N (counting from 0) are:

byte1 = N/D + min-byte1
byte2 = N\\D + min-char-or-byte2

where:

D = max-char-or-byte2 − min-char-or-byte2 + 1
/ = integer division
\\ = integer modulus

If char-infos has length zero, then min-bounds and max-bounds will be identical, and the effective char-infos is one filled with this char-info, of length:

L = D * (max-byte1 − min-byte1 + 1)

That is, all glyphs in the specified linear or matrix range have the same information, as given by min-bounds (and max-bounds). If all-chars-exist is True, then all characters in char-infos have nonzero bounding boxes.

The default-char specifies the character that will be used when an undefined or nonexistent character is used. Note that default-char is a CARD16, not CHAR2B. For a font using 2-byte matrix format, the default-char has byte1 in the most significant byte and byte2 in the least significant byte. If the default-char itself specifies an undefined or nonexistent character, then no printing is performed for an undefined or nonexistent character.

The min-bounds and max-bounds contain the minimum and maximum values of each individual CHARINFO component over all char-infos (ignoring nonexistent characters). The bounding box of the font (that is, the smallest rectangle enclosing the shape obtained by superimposing all characters at the same origin [x,y]) has its upper-left coordinate at:

[x + min-bounds.left-side-bearing, y − max-bounds.ascent]

with a width of:

max-bounds.right-side-bearing − min-bounds.left-side-bearing

and a height of:

max-bounds.ascent + max-bounds.descent

The font-ascent is the logical extent of the font above the baseline and is used for determining line spacing. Specific characters may extend beyond this. The font-descent is the logical extent of the font at or below the baseline and is used for determining line spacing. Specific characters may extend beyond this. If the baseline is at Y-coordinate y, then the logical extent of the font is inclusive between the Y-coordinate values (y − font-ascent) and (y + font-descent − 1).

A font is not guaranteed to have any properties. The interpretation of the property value (for example, INT32, CARD32) must be derived from a priori knowledge of the property. A basic set of font properties is specified in the X.Org standard X Logical Font Description Conventions.

For a character origin at [x,y], the bounding box of a character (that is, the smallest rectangle enclosing the character’s shape), described in terms of CHARINFO components, is a rectangle with its upper-left corner at:

[x + left-side-bearing, y − ascent]

with a width of:

right-side-bearing − left-side-bearing

and a height of:

ascent + descent

and the origin for the next character is defined to be:

[x + character-width, y]

Note that the baseline is logically viewed as being just below nondescending characters (when descent is zero, only pixels with Y-coordinates less than y are drawn) and that the origin is logically viewed as being coincident with the left edge of a nonkerned character (when left-side-bearing is zero, no pixels with X-coordinate less than x are drawn).

Note that CHARINFO metric values can be negative.

A nonexistent character is represented with all CHARINFO components zero.

The interpretation of the per-character attributes field is server-dependent. __ │
QueryTextExtents

font: FONTABLE
string: STRING16

→

draw-direction: {LeftToRight, RightToLeft}
font-ascent: INT16
font-descent: INT16
overall-ascent: INT16
overall-descent: INT16
overall-width: INT32
overall-left: INT32
overall-right: INT32

Errors: Font│__

This request returns the logical extents of the specified string of characters in the specified font. If a gcontext is given for font, the currently contained font is used. The draw-direction, font-ascent, and font-descent are the same as described in QueryFont. The overall-ascent is the maximum of the ascent metrics of all characters in the string, and the overall-descent is the maximum of the descent metrics. The overall-width is the sum of the character-width metrics of all characters in the string. For each character in the string, let W be the sum of the character-width metrics of all characters preceding it in the string, let L be the left-side-bearing metric of the character plus W, and let R be the right-side-bearing metric of the character plus W. The overall-left is the minimum L of all characters in the string, and the overall-right is the maximum R.

For fonts defined with linear indexing rather than 2-byte matrix indexing, the server will interpret each CHAR2B as a 16-bit number that has been transmitted most significant byte first (that is, byte1 of the CHAR2B is taken as the most significant byte).

Characters with all zero metrics are ignored. If the font has no defined default-char, then undefined characters in the string are also ignored. __ │
ListFonts

pattern: STRING8
max-names: CARD16

→

names: LISTofSTRING8│__

This request returns a list of available font names (as controlled by the font search path; see SetFontPath request) that match the pattern. At most, max-names names will be returned. The pattern should use the ISO Latin-1 encoding, and uppercase and lowercase do not matter. In the pattern, the ‘‘?’’ character (octal value 77) will match any single character, and the ‘‘*’’ character (octal value 52) will match any number of characters. The returned names are in lowercase. __ │
ListFontsWithInfo

pattern: STRING8
max-names: CARD16

→

name: STRING8
info FONTINFO
replies-hint: CARD32

where:

FONTINFO: <same type definition as in QueryFont>│__

This request is similar to ListFonts, but it also returns information about each font. The information returned for each font is identical to what QueryFont would return except that the per-character metrics are not returned. Note that this request can generate multiple replies. With each reply, replies-hint may provide an indication of how many more fonts will be returned. This number is a hint only and may be larger or smaller than the number of fonts actually returned. A zero value does not guarantee that no more fonts will be returned. After the font replies, a reply with a zero-length name is sent to indicate the end of the reply sequence. __ │
SetFontPath

path: LISTofSTRING8

Errors: Value│__

This request defines the search path for font lookup. There is only one search path per server, not one per client. The interpretation of the strings is operating-system-dependent, but the strings are intended to specify directories to be searched in the order listed.

Setting the path to the empty list restores the default path defined for the server.

As a side effect of executing this request, the server is guaranteed to flush all cached information about fonts for which there currently are no explicit resource IDs allocated.

The meaning of an error from this request is system specific. __ │
GetFontPath

→

path: LISTofSTRING8│__

This request returns the current search path for fonts. __ │
CreatePixmap

pid: PIXMAP
drawable: DRAWABLE
depth: CARD8
width, height: CARD16

Errors: Alloc, Drawable, IDChoice, Value│__

This request creates a pixmap and assigns the identifier pid to it. The width and height must be nonzero (or a Value error results). The depth must be one of the depths supported by the root of the specified drawable (or a Value error results). The initial contents of the pixmap are undefined.

It is legal to pass an InputOnly window as a drawable to this request. __ │
FreePixmap

pixmap: PIXMAP

Errors: Pixmap│__

This request deletes the association between the resource ID and the pixmap. The pixmap storage will be freed when no other resource references it. __ │
CreateGC

cid: GCONTEXT
drawable: DRAWABLE
value-mask: BITMASK
value-list: LISTofVALUE

Errors: Alloc, Drawable, Font, IDChoice, Match, Pixmap,
Value│__

This request creates a graphics context and assigns the identifier cid to it. The gcontext can be used with any destination drawable having the same root and depth as the specified drawable; use with other drawables results in a Match error.

The value-mask and value-list specify which components are to be explicitly initialized. The context components are:
Component Type
function
{Clear, And, AndReverse, Copy,
AndInverted, NoOp, Xor,  
Or, Nor, Equiv, Invert, OrReverse,
CopyInverted,  
OrInverted, Nand, Set}
plane-mask
CARD32
foreground
CARD32
background
CARD32
line-width
CARD16
line-style
{Solid, OnOffDash, DoubleDash}
cap-style
{NotLast, Butt, Round, Projecting}
join-style
{Miter, Round, Bevel}
fill-style
{Solid, Tiled, OpaqueStippled, Stippled}
fill-rule
{EvenOdd, Winding}
arc-mode
{Chord, PieSlice}
tile
PIXMAP
stipple
PIXMAP
tile-stipple-x-origin
INT16
tile-stipple-y-origin
INT16
font
FONT
subwindow-mode
{ClipByChildren, IncludeInferiors}
graphics-exposures
BOOL
clip-x-origin
INT16
clip-y-origin
INT16
clip-mask
PIXMAP or None
dash-offset
CARD16
dashes
CARD8

In graphics operations, given a source and destination pixel, the result is computed bitwise on corresponding bits of the pixels; that is, a Boolean operation is performed in each bit plane. The plane-mask restricts the operation to a subset of planes, so the result is:

((src FUNC dst) AND plane-mask) OR (dst AND (NOT plane-mask))

Range checking is not performed on the values for foreground, background, or plane-mask. They are simply truncated to the appropriate number of bits.

The meanings of the functions are:
Function Operation
Clear
0
And
src AND dst
AndReverse
src AND (NOT dst)
Copy
src
AndInverted
(NOT src) AND dst
NoOp
dst
Xor
src XOR dst
Or
src OR dst
Nor
(NOT src) AND (NOT
dst)
Equiv
(NOT src) XOR dst
Invert
NOT dst
OrReverse
src OR (NOT dst)
CopyInverted
NOT src
OrInverted
(NOT src) OR dst
Nand
(NOT src) OR (NOT
dst)
Set
1

The line-width is measured in pixels and can be greater than or equal to one, a wide line, or the special value zero, a thin line.

Wide lines are drawn centered on the path described by the graphics request. Unless otherwise specified by the join or cap style, the bounding box of a wide line with endpoints [x1, y1], [x2, y2] and width w is a rectangle with vertices at the following real coordinates:

[x1−(w*sn/2), y1+(w*cs/2)], [x1+(w*sn/2), y1−(w*cs/2)],
[x2−(w*sn/2), y2+(w*cs/2)], [x2+(w*sn/2), y2−(w*cs/2)]

The sn is the sine of the angle of the line and cs is the cosine of the angle of the line. A pixel is part of the line (and hence drawn) if the center of the pixel is fully inside the bounding box, which is viewed as having infinitely thin edges. If the center of the pixel is exactly on the bounding box, it is part of the line if and only if the interior is immediately to its right (x increasing direction). Pixels with centers on a horizontal edge are a special case and are part of the line if and only if the interior or the boundary is immediately below (y increasing direction) and if the interior or the boundary is immediately to the right (x increasing direction). Note that this description is a mathematical model describing the pixels that are drawn for a wide line and does not imply that trigonometry is required to implement such a model. Real or fixed point arithmetic is recommended for computing the corners of the line endpoints for lines greater than one pixel in width.

Thin lines (zero line-width) are nominally one pixel wide lines drawn using an unspecified, device-dependent algorithm. There are only two constraints on this algorithm. First, if a line is drawn unclipped from [x1,y1] to [x2,y2] and another line is drawn unclipped from [x1+dx,y1+dy] to [x2+dx,y2+dy], then a point [x,y] is touched by drawing the first line if and only if the point [x+dx,y+dy] is touched by drawing the second line. Second, the effective set of points comprising a line cannot be affected by clipping. Thus, a point is touched in a clipped line if and only if the point lies inside the clipping region and the point would be touched by the line when drawn unclipped.

Note that a wide line drawn from [x1,y1] to [x2,y2] always draws the same pixels as a wide line drawn from [x2,y2] to [x1,y1], not counting cap-style and join-style. Implementors are encouraged to make this property true for thin lines, but it is not required. A line-width of zero may differ from a line-width of one in which pixels are drawn. In general, drawing a thin line will be faster than drawing a wide line of width one, but thin lines may not mix well aesthetically with wide lines because of the different drawing algorithms. If it is desirable to obtain precise and uniform results across all displays, a client should always use a line-width of one, rather than a line-width of zero.

The line-style defines which sections of a line are drawn:
Solid
The full path of the line is drawn.
DoubleDash
The full path of the line is drawn, but the
even dashes are filled differently than the odd
dashes (see fill-style), with Butt cap-style
used where even and odd dashes meet.
OnOffDash
Only the even dashes are drawn, and cap-style
applies to all internal ends of the individual
dashes (except NotLast is treated as Butt).

The cap-style defines how the endpoints of a path are drawn:
NotLast
The result is equivalent to Butt, except that
for a line-width of zero the final endpoint is
not drawn.
Butt
The result is square at the endpoint
(perpendicular to the slope of the line) with
no projection beyond.
Round
The result is a circular arc with its diameter
equal to the line-width, centered on the
endpoint; it is equivalent to Butt for
line-width zero.
Projecting
The result is square at the end, but the path
continues beyond the endpoint for a distance
equal to half the line-width; it is equivalent
to Butt for line-width zero.

The join-style defines how corners are drawn for wide lines:
Miter
The outer edges of the two lines extend to meet
at an angle. However, if the angle is less
than 11 degrees, a Bevel join-style is used
instead.
Round
The result is a circular arc with a diameter
equal to the line-width, centered on the
joinpoint.
Bevel
The result is Butt endpoint styles, and then
the triangular notch is filled.

For a line with coincident endpoints (x1=x2, y1=y2), when the cap-style is applied to both endpoints, the semantics depends on the line-width and the cap-style:
NotLast
thin
This is device-dependent, but the desired
effect is that nothing is drawn.
Butt
thin
This is device-dependent, but the desired
effect is that a single pixel is drawn.
Round
thin
This is the same as Butt/thin.
Projecting
thin
This is the same as Butt/thin.
Butt
wide
Nothing is drawn.
Round
wide
The closed path is a circle, centered at
the endpoint and with a diameter equal to
the line-width.
Projecting
wide
The closed path is a square, aligned with
the coordinate axes, centered at the
endpoint and with sides equal to the
line-width.

For a line with coincident endpoints (x1=x2, y1=y2), when the join-style is applied at one or both endpoints, the effect is as if the line was removed from the overall path. However, if the total path consists of (or is reduced to) a single point joined with itself, the effect is the same as when the cap-style is applied at both endpoints.

The tile/stipple represents an infinite two-dimensional plane with the tile/stipple replicated in all dimensions. When that plane is superimposed on the drawable for use in a graphics operation, the upper-left corner of some instance of the tile/stipple is at the coordinates within the drawable specified by the tile/stipple origin. The tile/stipple and clip origins are interpreted relative to the origin of whatever destination drawable is specified in a graphics request.

The tile pixmap must have the same root and depth as the gcontext (or a Match error results). The stipple pixmap must have depth one and must have the same root as the gcontext (or a Match error results). For fill-style Stippled (but not fill-style OpaqueStippled), the stipple pattern is tiled in a single plane and acts as an additional clip mask to be ANDed with the clip-mask. Any size pixmap can be used for tiling or stippling, although some sizes may be faster to use than others.

The fill-style defines the contents of the source for line, text, and fill requests. For all text and fill requests (for example, PolyText8, PolyText16, PolyFillRectangle, FillPoly, and PolyFillArc) as well as for line requests with line-style Solid, (for example, PolyLine, PolySegment, PolyRectangle, PolyArc) and for the even dashes for line requests with line-style OnOffDash or DoubleDash:
Solid
Foreground
Tiled
Tile
OpaqueStippled
A tile with the same width and height as
stipple but with background everywhere
stipple has a zero and with foreground
everywhere stipple has a one
Stippled
Foreground masked by stipple

For the odd dashes for line requests with line-style DoubleDash:
Solid
Background
Tiled
Same as for even dashes
OpaqueStippled
Same as for even dashes
Stippled
Background masked by stipple

The dashes value allowed here is actually a simplified form of the more general patterns that can be set with SetDashes. Specifying a value of N here is equivalent to specifying the two element list [N, N] in SetDashes. The value must be nonzero (or a Value error results). The meaning of dash-offset and dashes are explained in the SetDashes request.

The clip-mask restricts writes to the destination drawable. Only pixels where the clip-mask has bits set to 1 are drawn. Pixels are not drawn outside the area covered by the clip-mask or where the clip-mask has bits set to 0. The clip-mask affects all graphics requests, but it does not clip sources. The clip-mask origin is interpreted relative to the origin of whatever destination drawable is specified in a graphics request. If a pixmap is specified as the clip-mask, it must have depth 1 and have the same root as the gcontext (or a Match error results). If clip-mask is None, then pixels are always drawn, regardless of the clip origin. The clip-mask can also be set with the SetClipRectangles request.

For ClipByChildren, both source and destination windows are additionally clipped by all viewable InputOutput children. For IncludeInferiors, neither source nor destination window is clipped by inferiors. This will result in including subwindow contents in the source and drawing through subwindow boundaries of the destination. The use of IncludeInferiors with a source or destination window of one depth with mapped inferiors of differing depth is not illegal, but the semantics is undefined by the core protocol.

The fill-rule defines what pixels are inside (that is, are drawn) for paths given in FillPoly requests. EvenOdd means a point is inside if an infinite ray with the point as origin crosses the path an odd number of times. For Winding, a point is inside if an infinite ray with the point as origin crosses an unequal number of clockwise and counterclockwise directed path segments. A clockwise directed path segment is one that crosses the ray from left to right as observed from the point. A counter-clockwise segment is one that crosses the ray from right to left as observed from the point. The case where a directed line segment is coincident with the ray is uninteresting because one can simply choose a different ray that is not coincident with a segment.

For both fill rules, a point is infinitely small and the path is an infinitely thin line. A pixel is inside if the center point of the pixel is inside and the center point is not on the boundary. If the center point is on the boundary, the pixel is inside if and only if the polygon interior is immediately to its right (x increasing direction). Pixels with centers along a horizontal edge are a special case and are inside if and only if the polygon interior is immediately below (y increasing direction).

The arc-mode controls filling in the PolyFillArc request.

The graphics-exposures flag controls GraphicsExposure event generation for CopyArea and CopyPlane requests (and any similar requests defined by extensions).

The default component values are:
Component Default
function
Copy
plane-mask
all ones
foreground
0
background
1
line-width
0
line-style
Solid
cap-style
Butt
join-style
Miter
fill-style
Solid
fill-rule
EvenOdd
arc-mode
PieSlice
tile
Pixmap of unspecified size filled with
foreground pixel
(that is, client specified pixel if any,
else 0)
(subsequent changes to foreground do not
affect this pixmap)
stipple
Pixmap of unspecified size filled with
ones
tile-stipple-x-origin
0
tile-stipple-y-origin
0
font
<server-dependent-font>
subwindow-mode
ClipByChildren
graphics-exposures
True
clip-x-origin
0
clip-y-origin
0
clip-mask
None
dash-offset
0
dashes
4 (that is, the list [4, 4])

Storing a pixmap in a gcontext might or might not result in a copy being made. If the pixmap is later used as the destination for a graphics request, the change might or might not be reflected in the gcontext. If the pixmap is used simultaneously in a graphics request as both a destination and as a tile or stipple, the results are not defined.

It is quite likely that some amount of gcontext information will be cached in display hardware and that such hardware can only cache a small number of gcontexts. Given the number and complexity of components, clients should view switching between gcontexts with nearly identical state as significantly more expensive than making minor changes to a single gcontext. __ │
ChangeGC

gc: GCONTEXT
value-mask: BITMASK
value-list: LISTofVALUE

Errors: Alloc, Font, GContext, Match, Pixmap, Value│__

This request changes components in gc. The value-mask and value-list specify which components are to be changed. The values and restrictions are the same as for CreateGC.

Changing the clip-mask also overrides any previous SetClipRectangles request on the context. Changing dash-offset or dashes overrides any previous SetDashes request on the context.

The order in which components are verified and altered is server-dependent. If an error is generated, a subset of the components may have been altered. __ │
CopyGC

src-gc, dst-gc: GCONTEXT
value-mask: BITMASK

Errors: Alloc, GContext, Match, Value│__

This request copies components from src-gc to dst-gc. The value-mask specifies which components to copy, as for CreateGC. The two gcontexts must have the same root and the same depth (or a Match error results). __ │
SetDashes

gc: GCONTEXT
dash-offset: CARD16
dashes: LISTofCARD8

Errors: Alloc, GContext, Value│__

This request sets dash-offset and dashes in gc for dashed line styles. Dashes cannot be empty (or a Value error results). Specifying an odd-length list is equivalent to specifying the same list concatenated with itself to produce an even-length list. The initial and alternating elements of dashes are the even dashes; the others are the odd dashes. Each element specifies a dash length in pixels. All of the elements must be nonzero (or a Value error results). The dash-offset defines the phase of the pattern, specifying how many pixels into dashes the pattern should actually begin in any single graphics request. Dashing is continuous through path elements combined with a join-style but is reset to the dash-offset between each sequence of joined lines.

The unit of measure for dashes is the same as in the ordinary coordinate system. Ideally, a dash length is measured along the slope of the line, but implementations are only required to match this ideal for horizontal and vertical lines. Failing the ideal semantics, it is suggested that the length be measured along the major axis of the line. The major axis is defined as the x axis for lines drawn at an angle of between −45 and +45 degrees or between 135 and 225 degrees from the x axis. For all other lines, the major axis is the y axis.

For any graphics primitive, the computation of the endpoint of an individual dash only depends on the geometry of the primitive, the start position of the dash, the direction of the dash, and the dash length.

For any graphics primitive, the total set of pixels used to render the primitive (both even and odd numbered dash elements) with DoubleDash line-style is the same as the set of pixels used to render the primitive with Solid line-style.

For any graphics primitive, if the primitive is drawn with OnOffDash or DoubleDash line-style unclipped at position [x,y] and again at position [x+dx,y+dy], then a point [x1,y1] is included in a dash in the first instance if and only if the point [x1+dx,y1+dy] is included in the dash in the second instance. In addition, the effective set of points comprising a dash cannot be affected by clipping. A point is included in a clipped dash if and only if the point lies inside the clipping region and the point would be included in the dash when drawn unclipped. __ │
SetClipRectangles

gc: GCONTEXT
clip-x-origin, clip-y-origin: INT16
rectangles: LISTofRECTANGLE
ordering: {UnSorted, YSorted, YXSorted, YXBanded}

Errors: Alloc, GContext, Match, Value│__

This request changes clip-mask in gc to the specified list of rectangles and sets the clip origin. Output will be clipped to remain contained within the rectangles. The clip origin is interpreted relative to the origin of whatever destination drawable is specified in a graphics request. The rectangle coordinates are interpreted relative to the clip origin. The rectangles should be nonintersecting, or graphics results will be undefined. Note that the list of rectangles can be empty, which effectively disables output. This is the opposite of passing None as the clip-mask in CreateGC and ChangeGC.

If known by the client, ordering relations on the rectangles can be specified with the ordering argument. This may provide faster operation by the server. If an incorrect ordering is specified, the server may generate a Match error, but it is not required to do so. If no error is generated, the graphics results are undefined. UnSorted means that the rectangles are in arbitrary order. YSorted means that the rectangles are nondecreasing in their Y origin. YXSorted additionally constrains YSorted order in that all rectangles with an equal Y origin are nondecreasing in their X origin. YXBanded additionally constrains YXSorted by requiring that, for every possible Y scanline, all rectangles that include that scanline have identical Y origins and Y extents. __ │
FreeGC

gc: GCONTEXT

Errors: GContext│__

This request deletes the association between the resource ID and the gcontext and destroys the gcontext. __ │
ClearArea

window: WINDOW
x, y: INT16
width, height: CARD16
exposures: BOOL

Errors: Match, Value, Window│__

The x and y coordinates are relative to the window’s origin and specify the upper-left corner of the rectangle. If width is zero, it is replaced with the current width of the window minus x. If height is zero, it is replaced with the current height of the window minus y. If the window has a defined background tile, the rectangle is tiled with a plane-mask of all ones and function of Copy and a subwindow-mode of ClipByChildren. If the window has background None, the contents of the window are not changed. In either case, if exposures is True, then one or more exposure events are generated for regions of the rectangle that are either visible or are being retained in a backing store.

It is a Match error to use an InputOnly window in this request. __ │
CopyArea

src-drawable, dst-drawable: DRAWABLE
gc: GCONTEXT
src-x, src-y: INT16
width, height: CARD16
dst-x, dst-y: INT16

Errors: Drawable, GContext, Match│__

This request combines the specified rectangle of src-drawable with the specified rectangle of dst-drawable. The src-x and src-y coordinates are relative to src-drawable’s origin. The dst-x and dst-y are relative to dst-drawable’s origin, each pair specifying the upper-left corner of the rectangle. The src-drawable must have the same root and the same depth as dst-drawable (or a Match error results).

If regions of the source rectangle are obscured and have not been retained in backing store or if regions outside the boundaries of the source drawable are specified, then those regions are not copied, but the following occurs on all corresponding destination regions that are either visible or are retained in backing-store. If the dst-drawable is a window with a background other than None, these corresponding destination regions are tiled (with plane-mask of all ones and function Copy) with that background. Regardless of tiling and whether the destination is a window or a pixmap, if graphics-exposures in gc is True, then GraphicsExposure events for all corresponding destination regions are generated.

If graphics-exposures is True but no GraphicsExposure events are generated, then a NoExposure event is generated.

GC components: function, plane-mask, subwindow-mode, graphics-exposures, clip-x-origin, clip-y-origin, clip-mask __ │
CopyPlane

src-drawable, dst-drawable: DRAWABLE
gc: GCONTEXT
src-x, src-y: INT16
width, height: CARD16
dst-x, dst-y: INT16
bit-plane: CARD32

Errors: Drawable, GContext, Match, Value│__

The src-drawable must have the same root as dst-drawable (or a Match error results), but it need not have the same depth. The bit-plane must have exactly one bit set to 1 and the value of bit-plane must be less than where n is the depth of src-drawable (or a Value error results). Effectively, a pixmap of the same depth as dst-drawable and with size specified by the source region is formed using the foreground/background pixels in gc (foreground everywhere the bit-plane in src-drawable contains a bit set to 1, background everywhere the bit-plane contains a bit set to 0), and the equivalent of a CopyArea is performed, with all the same exposure semantics. This can also be thought of as using the specified region of the source bit-plane as a stipple with a fill-style of OpaqueStippled for filling a rectangular area of the destination.

GC components: function, plane-mask, foreground, background, subwindow-mode, graphics-exposures, clip-x-origin, clip-y-origin, clip-mask __ │
PolyPoint

drawable: DRAWABLE
gc: GCONTEXT
coordinate-mode: {Origin, Previous}
points: LISTofPOINT

Errors: Drawable, GContext, Match, Value│__

This request combines the foreground pixel in gc with the pixel at each point in the drawable. The points are drawn in the order listed.

The first point is always relative to the drawable’s origin. The rest are relative either to that origin or the previous point, depending on the coordinate-mode.

GC components: function, plane-mask, foreground, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask __ │
PolyLine

drawable: DRAWABLE
gc: GCONTEXT
coordinate-mode: {Origin, Previous}
points: LISTofPOINT

Errors: Drawable, GContext, Match, Value│__

This request draws lines between each pair of points (point[i], point[i+1]). The lines are drawn in the order listed. The lines join correctly at all intermediate points, and if the first and last points coincide, the first and last lines also join correctly.

For any given line, no pixel is drawn more than once. If thin (zero line-width) lines intersect, the intersecting pixels are drawn multiple times. If wide lines intersect, the intersecting pixels are drawn only once, as though the entire PolyLine were a single filled shape.

The first point is always relative to the drawable’s origin. The rest are relative either to that origin or the previous point, depending on the coordinate-mode.

When either of the two lines involved in a Bevel join is neither vertical nor horizontal, then the slope and position of the line segment defining the bevel join edge is implementation dependent. However, the computation of the slope and distance (relative to the join point) only depends on the line width and the slopes of the two lines.

GC components: function, plane-mask, line-width, line-style, cap-style, join-style, fill-style, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin, dash-offset, dashes __ │
PolySegment

drawable: DRAWABLE
gc: GCONTEXT
segments: LISTofSEGMENT

where:

SEGMENT: [x1, y1, x2, y2: INT16]

Errors: Drawable, GContext, Match│__

For each segment, this request draws a line between [x1, y1] and [x2, y2]. The lines are drawn in the order listed. No joining is performed at coincident endpoints. For any given line, no pixel is drawn more than once. If lines intersect, the intersecting pixels are drawn multiple times.

GC components: function, plane-mask, line-width, line-style, cap-style, fill-style, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin, dash-offset, dashes __ │
PolyRectangle

drawable: DRAWABLE
gc: GCONTEXT
rectangles: LISTofRECTANGLE

Errors: Drawable, GContext, Match│__

This request draws the outlines of the specified rectangles, as if a five-point PolyLine were specified for each rectangle:

[x,y] [x+width,y] [x+width,y+height] [x,y+height] [x,y]

The x and y coordinates of each rectangle are relative to the drawable’s origin and define the upper-left corner of the rectangle.

The rectangles are drawn in the order listed. For any given rectangle, no pixel is drawn more than once. If rectangles intersect, the intersecting pixels are drawn multiple times.

GC components: function, plane-mask, line-width, line-style, cap-style, join-style, fill-style, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin, dash-offset, dashes __ │
PolyArc

drawable: DRAWABLE
gc: GCONTEXT
arcs: LISTofARC

Errors: Drawable, GContext, Match│__

This request draws circular or elliptical arcs. Each arc is specified by a rectangle and two angles. The angles are signed integers in degrees scaled by 64, with positive indicating counterclockwise motion and negative indicating clockwise motion. The start of the arc is specified by angle1 relative to the three-o’clock position from the center of the rectangle, and the path and extent of the arc is specified by angle2 relative to the start of the arc. If the magnitude of angle2 is greater than 360 degrees, it is truncated to 360 degrees. The x and y coordinates of the rectangle are relative to the origin of the drawable. For an arc specified as [x,y,w,h,a1,a2], the origin of the major and minor axes is at [x+(w/2),y+(h/2)], and the infinitely thin path describing the entire circle/ellipse intersects the horizontal axis at [x,y+(h/2)] and [x+w,y+(h/2)] and intersects the vertical axis at [x+(w/2),y] and [x+(w/2),y+h]. These coordinates are not necessarily integral; that is, they are not truncated to discrete coordinates.

For a wide line with line-width lw, the ideal bounding outlines for filling are given by the two infinitely thin paths consisting of all points whose perpendicular distance from a tangent to the path of the circle/ellipse is equal to lw/2 (which may be a fractional value). When the width and height of the arc are not equal and both are nonzero, then the actual bounding outlines are implementation dependent. However, the computation of the shape and position of the bounding outlines (relative to the center of the arc) only depends on the width and height of the arc and the line-width.

The cap-style is applied the same as for a line corresponding to the tangent of the circle/ellipse at the endpoint. When the angle of an arc face is not an integral multiple of 90 degrees, and the width and height of the arc are both are nonzero, then the shape and position of the cap at that face is implementation dependent. However, for a Butt cap, the face is defined by a straight line, and the computation of the position (relative to the center of the arc) and the slope of the line only depends on the width and height of the arc and the angle of the arc face. For other cap styles, the computation of the position (relative to the center of the arc) and the shape of the cap only depends on the width and height of the arc, the line-width, the angle of the arc face, and the direction (clockwise or counter clockwise) of the arc from the endpoint.

The join-style is applied the same as for two lines corresponding to the tangents of the circles/ellipses at the join point. When the width and height of both arcs are nonzero, and the angle of either arc face is not an integral multiple of 90 degrees, then the shape of the join is implementation dependent. However, the computation of the shape only depends on the width and height of each arc, the line-width, the angles of the two arc faces, the direction (clockwise or counter clockwise) of the arcs from the join point, and the relative orientation of the two arc center points.

For an arc specified as [x,y,w,h,a1,a2], the angles must be specified in the effectively skewed coordinate system of the ellipse (for a circle, the angles and coordinate systems are identical). The relationship between these angles and angles expressed in the normal coordinate system of the screen (as measured with a protractor) is as follows:

skewed-angle = atan(tan(normal-angle) * w/h) + adjust

The skewed-angle and normal-angle are expressed in radians (rather than in degrees scaled by 64) in the range [0,2*PI). The atan returns a value in the range [−PI/2,PI/2]. The adjust is:

0 for normal-angle in the range [0,PI/2)
PI for normal-angle in the range [PI/2,(3*PI)/2)
2*PI for normal-angle in the range [(3*PI)/2,2*PI)

The arcs are drawn in the order listed. If the last point in one arc coincides with the first point in the following arc, the two arcs will join correctly. If the first point in the first arc coincides with the last point in the last arc, the two arcs will join correctly. For any given arc, no pixel is drawn more than once. If two arcs join correctly and the line-width is greater than zero and the arcs intersect, no pixel is drawn more than once. Otherwise, the intersecting pixels of intersecting arcs are drawn multiple times. Specifying an arc with one endpoint and a clockwise extent draws the same pixels as specifying the other endpoint and an equivalent counterclockwise extent, except as it affects joins.

By specifying one axis to be zero, a horizontal or vertical line can be drawn.

Angles are computed based solely on the coordinate system, ignoring the aspect ratio.

GC components: function, plane-mask, line-width, line-style, cap-style, join-style, fill-style, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin, dash-offset, dashes __ │
FillPoly

drawable: DRAWABLE
gc: GCONTEXT
shape: {Complex, Nonconvex, Convex}
coordinate-mode: {Origin, Previous}
points: LISTofPOINT

Errors: Drawable, GContext, Match, Value│__

This request fills the region closed by the specified path. The path is closed automatically if the last point in the list does not coincide with the first point. No pixel of the region is drawn more than once.

The first point is always relative to the drawable’s origin. The rest are relative either to that origin or the previous point, depending on the coordinate-mode.

The shape parameter may be used by the server to improve performance. Complex means the path may self-intersect. Contiguous coincident points in the path are not treated as self-intersection.

Nonconvex means the path does not self-intersect, but the shape is not wholly convex. If known by the client, specifying Nonconvex over Complex may improve performance. If Nonconvex is specified for a self-intersecting path, the graphics results are undefined.

Convex means that for every pair of points inside the polygon, the line segment connecting them does not intersect the path. If known by the client, specifying Convex can improve performance. If Convex is specified for a path that is not convex, the graphics results are undefined.

GC components: function, plane-mask, fill-style, fill-rule, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin __ │
PolyFillRectangle

drawable: DRAWABLE
gc: GCONTEXT
rectangles: LISTofRECTANGLE

Errors: Drawable, GContext, Match│__

This request fills the specified rectangles, as if a four-point FillPoly were specified for each rectangle:

[x,y] [x+width,y] [x+width,y+height] [x,y+height]

The x and y coordinates of each rectangle are relative to the drawable’s origin and define the upper-left corner of the rectangle.

The rectangles are drawn in the order listed. For any given rectangle, no pixel is drawn more than once. If rectangles intersect, the intersecting pixels are drawn multiple times.

GC components: function, plane-mask, fill-style, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin __ │
PolyFillArc

drawable: DRAWABLE
gc: GCONTEXT
arcs: LISTofARC

Errors: Drawable, GContext, Match│__

For each arc, this request fills the region closed by the infinitely thin path described by the specified arc and one or two line segments, depending on the arc-mode. For Chord, the single line segment joining the endpoints of the arc is used. For PieSlice, the two line segments joining the endpoints of the arc with the center point are used.

For an arc specified as [x,y,w,h,a1,a2], the origin of the major and minor axes is at [x+(w/2),y+(h/2)], and the infinitely thin path describing the entire circle/ellipse intersects the horizontal axis at [x,y+(h/2)] and [x+w,y+(h/2)] and intersects the vertical axis at [x+(w/2),y] and [x+(w/2),y+h]. These coordinates are not necessarily integral; that is, they are not truncated to discrete coordinates.

The arc angles are interpreted as specified in the PolyArc request. When the angle of an arc face is not an integral multiple of 90 degrees, then the precise endpoint on the arc is implementation dependent. However, for Chord arc-mode, the computation of the pair of endpoints (relative to the center of the arc) only depends on the width and height of the arc and the angles of the two arc faces. For PieSlice arc-mode, the computation of an endpoint only depends on the angle of the arc face for that endpoint and the ratio of the arc width to arc height.

The arcs are filled in the order listed. For any given arc, no pixel is drawn more than once. If regions intersect, the intersecting pixels are drawn multiple times.

GC components: function, plane-mask, fill-style, arc-mode, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin __ │
PutImage

drawable: DRAWABLE
gc: GCONTEXT
depth: CARD8
width, height: CARD16
dst-x, dst-y: INT16
left-pad: CARD8
format: {Bitmap, XYPixmap, ZPixmap}
data: LISTofBYTE

Errors: Drawable, GContext, Match, Value│__

This request combines an image with a rectangle of the drawable. The dst-x and dst-y coordinates are relative to the drawable’s origin.

If Bitmap format is used, then depth must be one (or a Match error results), and the image must be in XY format. The foreground pixel in gc defines the source for bits set to 1 in the image, and the background pixel defines the source for the bits set to 0.

For XYPixmap and ZPixmap, the depth must match the depth of the drawable (or a Match error results). For XYPixmap, the image must be sent in XY format. For ZPixmap, the image must be sent in the Z format defined for the given depth.

The left-pad must be zero for ZPixmap format (or a Match error results). For Bitmap and XYPixmap format, left-pad must be less than bitmap-scanline-pad as given in the server connection setup information (or a Match error results). The first left-pad bits in every scanline are to be ignored by the server. The actual image begins that many bits into the data. The width argument defines the width of the actual image and does not include left-pad.

GC components: function, plane-mask, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background __ │
GetImage

drawable: DRAWABLE
x, y: INT16
width, height: CARD16
plane-mask: CARD32
format: {XYPixmap, ZPixmap}

→

depth: CARD8
visual: VISUALID or None
data: LISTofBYTE

Errors: Drawable, Match, Value│__

This request returns the contents of the given rectangle of the drawable in the given format. The x and y coordinates are relative to the drawable’s origin and define the upper-left corner of the rectangle. If XYPixmap is specified, only the bit planes specified in plane-mask are transmitted, with the planes appearing from most significant to least significant in bit order. If ZPixmap is specified, then bits in all planes not specified in plane-mask are transmitted as zero. Range checking is not performed on plane-mask; extraneous bits are simply ignored. The returned depth is as specified when the drawable was created and is the same as a depth component in a FORMAT structure (in the connection setup), not a bits-per-pixel component. If the drawable is a window, its visual type is returned. If the drawable is a pixmap, the visual is None.

If the drawable is a pixmap, then the given rectangle must be wholly contained within the pixmap (or a Match error results). If the drawable is a window, the window must be viewable, and it must be the case that, if there were no inferiors or overlapping windows, the specified rectangle of the window would be fully visible on the screen and wholly contained within the outside edges of the window (or a Match error results). Note that the borders of the window can be included and read with this request. If the window has a backing store, then the backing-store contents are returned for regions of the window that are obscured by noninferior windows; otherwise, the returned contents of such obscured regions are undefined. Also undefined are the returned contents of visible regions of inferiors of different depth than the specified window. The pointer cursor image is not included in the contents returned.

This request is not general-purpose in the same sense as other graphics-related requests. It is intended specifically for rudimentary hardcopy support. __ │
PolyText8

drawable: DRAWABLE
gc: GCONTEXT
x, y: INT16
items: LISTofTEXTITEM8

where:

TEXTITEM8: TEXTELT8 or FONT
TEXTELT8: [delta: INT8  
string: STRING8]

Errors: Drawable, Font, GContext, Match│__

The x and y coordinates are relative to the drawable’s origin and specify the baseline starting position (the initial character origin). Each text item is processed in turn. A font item causes the font to be stored in gc and to be used for subsequent text. Switching among fonts does not affect the next character origin. A text element delta specifies an additional change in the position along the x axis before the string is drawn; the delta is always added to the character origin. Each character image, as defined by the font in gc, is treated as an additional mask for a fill operation on the drawable.

All contained FONTs are always transmitted most significant byte first.

If a Font error is generated for an item, the previous items may have been drawn.

For fonts defined with 2-byte matrix indexing, each STRING8 byte is interpreted as a byte2 value of a CHAR2B with a byte1 value of zero.

GC components: function, plane-mask, fill-style, font, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask

GC mode-dependent components: foreground, background, tile, stipple, tile-stipple-x-origin, tile-stipple-y-origin __ │
PolyText16

drawable: DRAWABLE
gc: GCONTEXT
x, y: INT16
items: LISTofTEXTITEM16

where:

TEXTITEM16: TEXTELT16 or FONT
TEXTELT16: [delta: INT8  
string: STRING16]

Errors: Drawable, Font, GContext, Match│__

This request is similar to PolyText8, except 2-byte (or 16-bit) characters are used. For fonts defined with linear indexing rather than 2-byte matrix indexing, the server will interpret each CHAR2B as a 16-bit number that has been transmitted most significant byte first (that is, byte1 of the CHAR2B is taken as the most significant byte). __ │
ImageText8

drawable: DRAWABLE
gc: GCONTEXT
x, y: INT16
string: STRING8

Errors: Drawable, GContext, Match│__

The x and y coordinates are relative to the drawable’s origin and specify the baseline starting position (the initial character origin). The effect is first to fill a destination rectangle with the background pixel defined in gc and then to paint the text with the foreground pixel. The upper-left corner of the filled rectangle is at:

[x, y − font-ascent]

the width is:

overall-width

and the height is:

font-ascent + font-descent

The overall-width, font-ascent, and font-descent are as they would be returned by a QueryTextExtents call using gc and string.

The function and fill-style defined in gc are ignored for this request. The effective function is Copy, and the effective fill-style Solid.

For fonts defined with 2-byte matrix indexing, each STRING8 byte is interpreted as a byte2 value of a CHAR2B with a byte1 value of zero.

GC components: plane-mask, foreground, background, font, subwindow-mode, clip-x-origin, clip-y-origin, clip-mask __ │
ImageText16

drawable: DRAWABLE
gc: GCONTEXT
x, y: INT16
string: STRING16

Errors: Drawable, GContext, Match│__

This request is similar to ImageText8, except 2-byte (or 16-bit) characters are used. For fonts defined with linear indexing rather than 2-byte matrix indexing, the server will interpret each CHAR2B as a 16-bit number that has been transmitted most significant byte first (that is, byte1 of the CHAR2B is taken as the most significant byte). __ │
CreateColormap

mid: COLORMAP
visual: VISUALID
window: WINDOW
alloc: {None, All}

Errors: Alloc, IDChoice, Match, Value, Window│__

This request creates a colormap of the specified visual type for the screen on which the window resides and associates the identifier mid with it. The visual type must be one supported by the screen (or a Match error results). The initial values of the colormap entries are undefined for classes GrayScale, PseudoColor, and DirectColor. For StaticGray, StaticColor, and TrueColor, the entries will have defined values, but those values are specific to the visual and are not defined by the core protocol. For StaticGray, StaticColor, and TrueColor, alloc must be specified as None (or a Match error results). For the other classes, if alloc is None, the colormap initially has no allocated entries, and clients can allocate entries.

If alloc is All, then the entire colormap is allocated writable. The initial values of all allocated entries are undefined. For GrayScale and PseudoColor, the effect is as if an AllocColorCells request returned all pixel values from zero to N − 1, where N is the colormap-entries value in the specified visual. For DirectColor, the effect is as if an AllocColorPlanes request returned a pixel value of zero and red-mask, green-mask, and blue-mask values containing the same bits as the corresponding masks in the specified visual. However, in all cases, none of these entries can be freed with FreeColors. __ │
FreeColormap

cmap: COLORMAP

Errors: Colormap│__

This request deletes the association between the resource ID and the colormap and frees the colormap storage. If the colormap is an installed map for a screen, it is uninstalled (see UninstallColormap request). If the colormap is defined as the colormap for a window (by means of CreateWindow or ChangeWindowAttributes), the colormap for the window is changed to None, and a ColormapNotify event is generated. The protocol does not define the colors displayed for a window with a colormap of None.

This request has no effect on a default colormap for a screen. __ │
CopyColormapAndFree

mid, src-cmap: COLORMAP

Errors: Alloc, Colormap, IDChoice│__

This request creates a colormap of the same visual type and for the same screen as src-cmap, and it associates identifier mid with it. It also moves all of the client’s existing allocations from src-cmap to the new colormap with their color values intact and their read-only or writable characteristics intact, and it frees those entries in src-cmap. Color values in other entries in the new colormap are undefined. If src-cmap was created by the client with alloc All (see CreateColormap request), then the new colormap is also created with alloc All, all color values for all entries are copied from src-cmap, and then all entries in src-cmap are freed. If src-cmap was not created by the client with alloc All, then the allocations to be moved are all those pixels and planes that have been allocated by the client using either AllocColor, AllocNamedColor, AllocColorCells, or AllocColorPlanes and that have not been freed since they were allocated. __ │
InstallColormap

cmap: COLORMAP

Errors: Colormap│__

This request makes this colormap an installed map for its screen. All windows associated with this colormap immediately display with true colors. As a side effect, additional colormaps might be implicitly installed or uninstalled by the server. Which other colormaps get installed or uninstalled is server-dependent except that the required list must remain installed.

If cmap is not already an installed map, a ColormapNotify event is generated on every window having cmap as an attribute. In addition, for every other colormap that is installed or uninstalled as a result of the request, a ColormapNotify event is generated on every window having that colormap as an attribute.

At any time, there is a subset of the installed maps that are viewed as an ordered list and are called the required list. The length of the required list is at most M, where M is the min-installed-maps specified for the screen in the connection setup. The required list is maintained as follows. When a colormap is an explicit argument to InstallColormap, it is added to the head of the list; the list is truncated at the tail, if necessary, to keep the length of the list to at most M. When a colormap is an explicit argument to UninstallColormap and it is in the required list, it is removed from the list. A colormap is not added to the required list when it is installed implicitly by the server, and the server cannot implicitly uninstall a colormap that is in the required list.

Initially the default colormap for a screen is installed (but is not in the required list). __ │
UninstallColormap

cmap: COLORMAP

Errors: Colormap│__

If cmap is on the required list for its screen (see InstallColormap request), it is removed from the list. As a side effect, cmap might be uninstalled, and additional colormaps might be implicitly installed or uninstalled. Which colormaps get installed or uninstalled is server-dependent except that the required list must remain installed.

If cmap becomes uninstalled, a ColormapNotify event is generated on every window having cmap as an attribute. In addition, for every other colormap that is installed or uninstalled as a result of the request, a ColormapNotify event is generated on every window having that colormap as an attribute. __ │
ListInstalledColormaps

window: WINDOW

→

cmaps: LISTofCOLORMAP

Errors: Window│__

This request returns a list of the currently installed colormaps for the screen of the specified window. The order of colormaps is not significant, and there is no explicit indication of the required list (see InstallColormap request). __ │
AllocColor

cmap: COLORMAP
red, green, blue: CARD16

→

pixel: CARD32
red, green, blue: CARD16

Errors: Alloc, Colormap│__

This request allocates a read-only colormap entry corresponding to the closest RGB values provided by the hardware. It also returns the pixel and the RGB values actually used. Multiple clients requesting the same effective RGB values can be assigned the same read-only entry, allowing entries to be shared. __ │
AllocNamedColor

cmap: COLORMAP
name: STRING8

→

pixel: CARD32
exact-red, exact-green, exact-blue: CARD16
visual-red, visual-green, visual-blue: CARD16

Errors: Alloc, Colormap, Name│__

This request looks up the named color with respect to the screen associated with the colormap. Then, it does an AllocColor on cmap. The name should use the ISO Latin-1 encoding, and uppercase and lowercase do not matter. The exact RGB values specify the true values for the color, and the visual values specify the values actually used in the colormap. __ │
AllocColorCells

cmap: COLORMAP
colors, planes: CARD16
contiguous: BOOL

→

pixels, masks: LISTofCARD32

Errors: Alloc, Colormap, Value│__

The number of colors must be positive, and the number of planes must be nonnegative (or a Value error results). If C colors and P planes are requested, then C pixels and P masks are returned. No mask will have any bits in common with any other mask or with any of the pixels. By ORing together masks and pixels, C* distinct pixels can be produced; all of these are allocated writable by the request. For GrayScale or PseudoColor, each mask will have exactly one bit set to 1; for DirectColor, each will have exactly three bits set to 1. If contiguous is True and if all masks are ORed together, a single contiguous set of bits will be formed for GrayScale or PseudoColor, and three contiguous sets of bits (one within each pixel subfield) for DirectColor. The RGB values of the allocated entries are undefined. __ │
AllocColorPlanes

cmap: COLORMAP
colors, reds, greens, blues: CARD16
contiguous: BOOL

→

pixels: LISTofCARD32
red-mask, green-mask, blue-mask: CARD32

Errors: Alloc, Colormap, Value│__

The number of colors must be positive, and the reds, greens, and blues must be nonnegative (or a Value error results). If C colors, R reds, G greens, and B blues are requested, then C pixels are returned, and the masks have R, G, and B bits set, respectively. If contiguous is True, then each mask will have a contiguous set of bits. No mask will have any bits in common with any other mask or with any of the pixels. For DirectColor, each mask will lie within the corresponding pixel subfield. By ORing together subsets of masks with pixels, C* distinct pixels can be produced; all of these are allocated writable by the request. The initial RGB values of the allocated entries are undefined. In the colormap, there are only C* independent red entries, C* independent green entries, and C* independent blue entries. This is true even for PseudoColor. When the colormap entry for a pixel value is changed using StoreColors or StoreNamedColor, the pixel is decomposed according to the masks and the corresponding independent entries are updated. __ │
FreeColors

cmap: COLORMAP
pixels: LISTofCARD32
plane-mask: CARD32

Errors: Access, Colormap, Value│__

The plane-mask should not have any bits in common with any of the pixels. The set of all pixels is produced by ORing together subsets of plane-mask with the pixels. The request frees all of these pixels that were allocated by the client (using AllocColor, AllocNamedColor, AllocColorCells, and AllocColorPlanes). Note that freeing an individual pixel obtained from AllocColorPlanes may not actually allow it to be reused until all of its related pixels are also freed. Similarly, a read-only entry is not actually freed until it has been freed by all clients, and if a client allocates the same read-only entry multiple times, it must free the entry that many times before the entry is actually freed.

All specified pixels that are allocated by the client in cmap are freed, even if one or more pixels produce an error. A Value error is generated if a specified pixel is not a valid index into cmap. An Access error is generated if a specified pixel is not allocated by the client (that is, is unallocated or is only allocated by another client) or if the colormap was created with all entries writable (using an alloc value of All in CreateColormap). If more than one pixel is in error, it is arbitrary as to which pixel is reported. __ │
StoreColors

cmap: COLORMAP
items: LISTofCOLORITEM

where:

COLORITEM: [pixel: CARD32  
do-red, do-green, do-blue: BOOL  
red, green, blue: CARD16]

Errors: Access, Colormap, Value│__

This request changes the colormap entries of the specified pixels. The do-red, do-green, and do-blue fields indicate which components should actually be changed. If the colormap is an installed map for its screen, the changes are visible immediately.

All specified pixels that are allocated writable in cmap (by any client) are changed, even if one or more pixels produce an error. A Value error is generated if a specified pixel is not a valid index into cmap, and an Access error is generated if a specified pixel is unallocated or is allocated read-only. If more than one pixel is in error, it is arbitrary as to which pixel is reported. __ │
StoreNamedColor

cmap: COLORMAP
pixel: CARD32
name: STRING8
do-red, do-green, do-blue: BOOL

Errors: Access, Colormap, Name, Value│__

This request looks up the named color with respect to the screen associated with cmap and then does a StoreColors in cmap. The name should use the ISO Latin-1 encoding, and uppercase and lowercase do not matter. The Access and Value errors are the same as in StoreColors. __ │
QueryColors

cmap: COLORMAP
pixels: LISTofCARD32

→

colors: LISTofRGB

where:

RGB: [red, green, blue: CARD16]

Errors: Colormap, Value│__

This request returns the hardware-specific color values stored in cmap for the specified pixels. The values returned for an unallocated entry are undefined. A Value error is generated if a pixel is not a valid index into cmap. If more than one pixel is in error, it is arbitrary as to which pixel is reported. __ │
LookupColor

cmap: COLORMAP
name: STRING8

→

exact-red, exact-green, exact-blue: CARD16
visual-red, visual-green, visual-blue: CARD16

Errors: Colormap, Name│__

This request looks up the string name of a color with respect to the screen associated with cmap and returns both the exact color values and the closest values provided by the hardware with respect to the visual type of cmap. The name should use the ISO Latin-1 encoding, and uppercase and lowercase do not matter. __ │
CreateCursor

cid: CURSOR
source: PIXMAP
mask: PIXMAP or None
fore-red, fore-green, fore-blue: CARD16
back-red, back-green, back-blue: CARD16
x, y: CARD16

Errors: Alloc, IDChoice, Match, Pixmap│__

This request creates a cursor and associates identifier cid with it. The foreground and background RGB values must be specified, even if the server only has a StaticGray or GrayScale screen. The foreground is used for the bits set to 1 in the source, and the background is used for the bits set to 0. Both source and mask (if specified) must have depth one (or a Match error results), but they can have any root. The mask pixmap defines the shape of the cursor. That is, the bits set to 1 in the mask define which source pixels will be displayed, and where the mask has bits set to 0, the corresponding bits of the source pixmap are ignored. If no mask is given, all pixels of the source are displayed. The mask, if present, must be the same size as the source (or a Match error results). The x and y coordinates define the hotspot relative to the source’s origin and must be a point within the source (or a Match error results).

The components of the cursor may be transformed arbitrarily to meet display limitations.

The pixmaps can be freed immediately if no further explicit references to them are to be made.

Subsequent drawing in the source or mask pixmap has an undefined effect on the cursor. The server might or might not make a copy of the pixmap. __ │
CreateGlyphCursor

cid: CURSOR
source-font: FONT
mask-font: FONT or None
source-char, mask-char: CARD16
fore-red, fore-green, fore-blue: CARD16
back-red, back-green, back-blue: CARD16

Errors: Alloc, Font, IDChoice, Value│__

This request is similar to CreateCursor, except the source and mask bitmaps are obtained from the specified font glyphs. The source-char must be a defined glyph in source-font, and if mask-font is given, mask-char must be a defined glyph in mask-font (or a Value error results). The mask font and character are optional. The origins of the source and mask (if it is defined) glyphs are positioned coincidently and define the hotspot. The source and mask need not have the same bounding box metrics, and there is no restriction on the placement of the hotspot relative to the bounding boxes. If no mask is given, all pixels of the source are displayed. Note that source-char and mask-char are CARD16, not CHAR2B. For 2-byte matrix fonts, the 16-bit value should be formed with byte1 in the most significant byte and byte2 in the least significant byte.

The components of the cursor may be transformed arbitrarily to meet display limitations.

The fonts can be freed immediately if no further explicit references to them are to be made. __ │
FreeCursor

cursor: CURSOR

Errors: Cursor│__

This request deletes the association between the resource ID and the cursor. The cursor storage will be freed when no other resource references it. __ │
RecolorCursor

cursor: CURSOR
fore-red, fore-green, fore-blue: CARD16
back-red, back-green, back-blue: CARD16

Errors: Cursor│__

This request changes the color of a cursor. If the cursor is being displayed on a screen, the change is visible immediately. __ │
QueryBestSize

class: {Cursor, Tile, Stipple}
drawable: DRAWABLE
width, height: CARD16

→

width, height: CARD16

Errors: Drawable, Match, Value│__

This request returns the best size that is closest to the argument size. For Cursor, this is the largest size that can be fully displayed. For Tile, this is the size that can be tiled fastest. For Stipple, this is the size that can be stippled fastest.

For Cursor, the drawable indicates the desired screen. For Tile and Stipple, the drawable indicates the screen and also possibly the window class and depth. An InputOnly window cannot be used as the drawable for Tile or Stipple (or a Match error results). __ │
QueryExtension

name: STRING8

→

present: BOOL
major-opcode: CARD8
first-event: CARD8
first-error: CARD8│__

This request determines if the named extension is present. If so, the major opcode for the extension is returned, if it has one. Otherwise, zero is returned. Any minor opcode and the request formats are specific to the extension. If the extension involves additional event types, the base event type code is returned. Otherwise, zero is returned. The format of the events is specific to the extension. If the extension involves additional error codes, the base error code is returned. Otherwise, zero is returned. The format of additional data in the errors is specific to the extension.

The extension name should use the ISO Latin-1 encoding, and uppercase and lowercase matter. __ │
ListExtensions

→

names: LISTofSTRING8│__

This request returns a list of all extensions supported by the server. __ │
SetModifierMapping

keycodes-per-modifier: CARD8
keycodes: LISTofKEYCODE

→

status: {Success, Busy, Failed}

Errors: Alloc, Value│__

This request specifies the keycodes (if any) of the keys to be used as modifiers. The number of keycodes in the list must be 8*keycodes-per-modifier (or a Length error results). The keycodes are divided into eight sets, with each set containing keycodes-per-modifier elements. The sets are assigned to the modifiers Shift, Lock, Control, Mod1, Mod2, Mod3, Mod4, and Mod5, in order. Only nonzero keycode values are used within each set; zero values are ignored. All of the nonzero keycodes must be in the range specified by min-keycode and max-keycode in the connection setup (or a Value error results). The order of keycodes within a set does not matter. If no nonzero values are specified in a set, the use of the corresponding modifier is disabled, and the modifier bit will always be zero. Otherwise, the modifier bit will be one whenever at least one of the keys in the corresponding set is in the down position.

A server can impose restrictions on how modifiers can be changed (for example, if certain keys do not generate up transitions in hardware, if auto-repeat cannot be disabled on certain keys, or if multiple keys per modifier are not supported). The status reply is Failed if some such restriction is violated, and none of the modifiers is changed.

If the new nonzero keycodes specified for a modifier differ from those currently defined and any (current or new) keys for that modifier are logically in the down state, then the status reply is Busy, and none of the modifiers is changed.

This request generates a MappingNotify event on a Success status. __ │
GetModifierMapping

→

keycodes-per-modifier: CARD8
keycodes: LISTofKEYCODE│__

This request returns the keycodes of the keys being used as modifiers. The number of keycodes in the list is 8*keycodes-per-modifier. The keycodes are divided into eight sets, with each set containing keycodes-per-modifier elements. The sets are assigned to the modifiers Shift, Lock, Control, Mod1, Mod2, Mod3, Mod4, and Mod5, in order. The keycodes-per-modifier value is chosen arbitrarily by the server; zeroes are used to fill in unused elements within each set. If only zero values are given in a set, the use of the corresponding modifier has been disabled. The order of keycodes within each set is chosen arbitrarily by the server. __ │
ChangeKeyboardMapping

first-keycode: KEYCODE
keysyms-per-keycode: CARD8
keysyms: LISTofKEYSYM

Errors: Alloc, Value│__

This request defines the symbols for the specified number of keycodes, starting with the specified keycode. The symbols for keycodes outside this range remained unchanged. The number of elements in the keysyms list must be a multiple of keysyms-per-keycode (or a Length error results). The first-keycode must be greater than or equal to min-keycode as returned in the connection setup (or a Value error results) and:

first-keycode + (keysyms-length / keysyms-per-keycode) − 1

must be less than or equal to max-keycode as returned in the connection setup (or a Value error results). KEYSYM number N (counting from zero) for keycode K has an index (counting from zero) of:

(K − first-keycode) * keysyms-per-keycode + N

in keysyms. The keysyms-per-keycode can be chosen arbitrarily by the client to be large enough to hold all desired symbols. A special KEYSYM value of NoSymbol should be used to fill in unused elements for individual keycodes. It is legal for NoSymbol to appear in nontrailing positions of the effective list for a keycode.

This request generates a MappingNotify event.

There is no requirement that the server interpret this mapping; it is merely stored for reading and writing by clients (see section 5). __ │
GetKeyboardMapping

first-keycode: KEYCODE
count: CARD8

→

keysyms-per-keycode: CARD8
keysyms: LISTofKEYSYM

Errors: Value│__

This request returns the symbols for the specified number of keycodes, starting with the specified keycode. The first-keycode must be greater than or equal to min-keycode as returned in the connection setup (or a Value error results), and:

first-keycode + count − 1

must be less than or equal to max-keycode as returned in the connection setup (or a Value error results). The number of elements in the keysyms list is:

count * keysyms-per-keycode

and KEYSYM number N (counting from zero) for keycode K has an index (counting from zero) of:

(K − first-keycode) * keysyms-per-keycode + N

in keysyms. The keysyms-per-keycode value is chosen arbitrarily by the server to be large enough to report all requested symbols. A special KEYSYM value of NoSymbol is used to fill in unused elements for individual keycodes. __ │
ChangeKeyboardControl

value-mask: BITMASK
value-list: LISTofVALUE

Errors: Match, Value│__

This request controls various aspects of the keyboard. The value-mask and value-list specify which controls are to be changed. The possible values are:
Control Type
key-click-percent
INT8
bell-percent
INT8
bell-pitch
INT16
bell-duration
INT16
led
CARD8
led-mode
{On, Off}
key
KEYCODE
auto-repeat-mode
{On, Off, Default}

The key-click-percent sets the volume for key clicks between 0 (off) and 100 (loud) inclusive, if possible. Setting to −1 restores the default. Other negative values generate a Value error.

The bell-percent sets the base volume for the bell between 0 (off) and 100 (loud) inclusive, if possible. Setting to −1 restores the default. Other negative values generate a Value error.

The bell-pitch sets the pitch (specified in Hz) of the bell, if possible. Setting to −1 restores the default. Other negative values generate a Value error.

The bell-duration sets the duration of the bell (specified in milliseconds), if possible. Setting to −1 restores the default. Other negative values generate a Value error.

If both led-mode and led are specified, then the state of that LED is changed, if possible. If only led-mode is specified, then the state of all LEDs are changed, if possible. At most 32 LEDs, numbered from one, are supported. No standard interpretation of LEDs is defined. It is a Match error if an led is specified without an led-mode.

If both auto-repeat-mode and key are specified, then the auto-repeat mode of that key is changed, if possible. If only auto-repeat-mode is specified, then the global auto-repeat mode for the entire keyboard is changed, if possible, without affecting the per-key settings. It is a Match error if a key is specified without an auto-repeat-mode. Each key has an individual mode of whether or not it should auto-repeat and a default setting for that mode. In addition, there is a global mode of whether auto-repeat should be enabled or not and a default setting for that mode. When the global mode is On, keys should obey their individual auto-repeat modes. When the global mode is Off, no keys should auto-repeat. An auto-repeating key generates alternating KeyPress and KeyRelease events. When a key is used as a modifier, it is desirable for the key not to auto-repeat, regardless of the auto-repeat setting for that key.

A bell generator connected with the console but not directly on the keyboard is treated as if it were part of the keyboard.

The order in which controls are verified and altered is server-dependent. If an error is generated, a subset of the controls may have been altered. __ │
GetKeyboardControl

→

key-click-percent: CARD8
bell-percent: CARD8
bell-pitch: CARD16
bell-duration: CARD16
led-mask: CARD32
global-auto-repeat: {On, Off}
auto-repeats: LISTofCARD8│__

This request returns the current control values for the keyboard. For the LEDs, the least significant bit of led-mask corresponds to LED one, and each one bit in led-mask indicates an LED that is lit. The auto-repeats is a bit vector; each one bit indicates that auto-repeat is enabled for the corresponding key. The vector is represented as 32 bytes. Byte N (from 0) contains the bits for keys 8N to 8N + 7, with the least significant bit in the byte representing key 8N. __ │
Bell

percent: INT8

Errors: Value│__

This request rings the bell on the keyboard at a volume relative to the base volume for the keyboard, if possible. Percent can range from −100 to 100 inclusive (or a Value error results). The volume at which the bell is rung when percent is nonnegative is:

base − [(base * percent) / 100] + percent

When percent is negative, it is:

base + [(base * percent) / 100] __ │

SetPointerMapping

map: LISTofCARD8

→

status: {Success, Busy}

Errors: Value│__

This request sets the mapping of the pointer. Elements of the list are indexed starting from one. The length of the list must be the same as GetPointerMapping would return (or a Value error results). The index is a core button number, and the element of the list defines the effective number.

A zero element disables a button. Elements are not restricted in value by the number of physical buttons, but no two elements can have the same nonzero value (or a Value error results).

If any of the buttons to be altered are logically in the down state, the status reply is Busy, and the mapping is not changed.

This request generates a MappingNotify event on a Success status. __ │
GetPointerMapping

→

map: LISTofCARD8│__

This request returns the current mapping of the pointer. Elements of the list are indexed starting from one. The length of the list indicates the number of physical buttons.

The nominal mapping for a pointer is the identity mapping: map[i]=i. __ │
ChangePointerControl

do-acceleration, do-threshold: BOOL
acceleration-numerator, acceleration-denominator: INT16
threshold: INT16

Errors: Value│__

This request defines how the pointer moves. The acceleration is a multiplier for movement expressed as a fraction. For example, specifying 3/1 means the pointer moves three times as fast as normal. The fraction can be rounded arbitrarily by the server. Acceleration only takes effect if the pointer moves more than threshold number of pixels at once and only applies to the amount beyond the threshold. Setting a value to −1 restores the default. Other negative values generate a Value error, as does a zero value for acceleration-denominator. __ │
GetPointerControl

→

acceleration-numerator, acceleration-denominator: CARD16
threshold: CARD16│__

This request returns the current acceleration and threshold for the pointer. __ │
SetScreenSaver

timeout, interval: INT16
prefer-blanking: {Yes, No, Default}
allow-exposures: {Yes, No, Default}

Errors: Value│__

The timeout and interval are specified in seconds; setting a value to −1 restores the default. Other negative values generate a Value error. If the timeout value is zero, screen-saver is disabled (but an activated screen-saver is not deactivated). If the timeout value is nonzero, screen-saver is enabled. Once screen-saver is enabled, if no input from the keyboard or pointer is generated for timeout seconds, screen-saver is activated. For each screen, if blanking is preferred and the hardware supports video blanking, the screen will simply go blank. Otherwise, if either exposures are allowed or the screen can be regenerated without sending exposure events to clients, the screen is changed in a server-dependent fashion to avoid phosphor burn. Otherwise, the state of the screens does not change, and screen-saver is not activated. At the next keyboard or pointer input or at the next ForceScreenSaver with mode Reset, screen-saver is deactivated, and all screen states are restored.

If the server-dependent screen-saver method is amenable to periodic change, interval serves as a hint about how long the change period should be, with zero hinting that no periodic change should be made. Examples of ways to change the screen include scrambling the color map periodically, moving an icon image about the screen periodically, or tiling the screen with the root window background tile, randomly reorigined periodically. __ │
GetScreenSaver

→

timeout, interval: CARD16
prefer-blanking: {Yes, No}
allow-exposures: {Yes, No}│__

This request returns the current screen-saver control values. __ │
ForceScreenSaver

mode: {Activate, Reset}

Errors: Value│__

If the mode is Activate and screen-saver is currently deactivated, then screen-saver is activated (even if screen-saver has been disabled with a timeout value of zero). If the mode is Reset and screen-saver is currently enabled, then screen-saver is deactivated (if it was activated), and the activation timer is reset to its initial state as if device input had just been received. __ │
ChangeHosts

mode: {Insert, Delete}
host: HOST

Errors: Access, Value│__

This request adds or removes the specified host from the access control list. When the access control mechanism is enabled and a client attempts to establish a connection to the server, the host on which the client resides must be in the access control list, or the client must have been granted permission by a server-dependent method, or the server will refuse the connection.

The client must reside on the same host as the server and/or have been granted permission by a server-dependent method to execute this request (or an Access error results).

An initial access control list can usually be specified, typically by naming a file that the server reads at startup and reset.

The following address families are defined. A server is not required to support these families and may support families not listed here. Use of an unsupported family, an improper address format, or an improper address length within a supported family results in a Value error.

For the Internet family, the address must be four bytes long. The address bytes are in standard IP order; the server performs no automatic swapping on the address bytes. The Internet family supports IP version 4 addresses only.

For the InternetV6 family, the address must be sixteen bytes long. The address bytes are in standard IP order; the server performs no automatic swapping on the address bytes. The InternetV6 family supports IP version 6 addresses only.

For the DECnet family, the server performs no automatic swapping on the address bytes. A Phase IV address is two bytes long: the first byte contains the least significant eight bits of the node number, and the second byte contains the most significant two bits of the node number in the least significant two bits of the byte and the area in the most significant six bits of the byte.

For the Chaos family, the address must be two bytes long. The host number is always the first byte in the address, and the subnet number is always the second byte. The server performs no automatic swapping on the address bytes.

For the ServerInterpreted family, the address may be of any length up to 65535 bytes. The address consists of two strings of ASCII characters, separated by a byte with a value of 0. The first string represents the type of address, and the second string contains the address value. Address types and the syntax for their associated values will be registered via the X.Org Registry. Implementors who wish to add implementation specific types may register a unique prefix with the X.Org registry to prevent namespace collisions.

Use of a host address in the ChangeHosts request is deprecated. It is only useful when a host has a unique, constant address, a requirement that is increasingly unmet as sites adopt dynamically assigned addresses, network address translation gateways, IPv6 link local addresses, and various other technologies. It also assumes all users of a host share equivalent access rights, and as such has never been suitable for many multi-user machine environments. Instead, more secure forms of authentication, such as those based on shared secrets or public key encryption, are recommended. __ │
ListHosts

→

mode: {Enabled, Disabled}
hosts: LISTofHOST│__

This request returns the hosts on the access control list and whether use of the list at connection setup is currently enabled or disabled.

Each HOST is padded to a multiple of four bytes. __ │
SetAccessControl

mode: {Enable, Disable}

Errors: Access, Value│__

This request enables or disables the use of the access control list at connection setups.

The client must reside on the same host as the server and/or have been granted permission by a server-dependent method to execute this request (or an Access error results). __ │
SetCloseDownMode

mode: {Destroy, RetainPermanent, RetainTemporary}

Errors: Value│__

This request defines what will happen to the client’s resources at connection close. A connection starts in Destroy mode. The meaning of the close-down mode is described in section 10. __ │
KillClient

resource: CARD32 or AllTemporary

Errors: Value│__

If a valid resource is specified, KillClient forces a close-down of the client that created the resource. If the client has already terminated in either RetainPermanent or RetainTemporary mode, all of the client’s resources are destroyed (see section 10). If AllTemporary is specified, then the resources of all clients that have terminated in RetainTemporary are destroyed. __ │
NoOperation│__

This request has no arguments and no results, but the request length field allows the request to be any multiple of four bytes in length. The bytes contained in the request are uninterpreted by the server.

This request can be used in its minimum four byte form as padding where necessary by client libraries that find it convenient to force requests to begin on 64-bit boundaries.

10. Connection Close

At connection close, all event selections made by the client are discarded. If the client has the pointer actively grabbed, an UngrabPointer is performed. If the client has the keyboard actively grabbed, an UngrabKeyboard is performed. All passive grabs by the client are released. If the client has the server grabbed, an UngrabServer is performed. All selections (see SetSelectionOwner request) owned by the client are disowned. If close-down mode (see SetCloseDownMode request) is RetainPermanent or RetainTemporary, then all resources (including colormap entries) allocated by the client are marked as permanent or temporary, respectively (but this does not prevent other clients from explicitly destroying them). If the mode is Destroy, all of the client’s resources are destroyed.

When a client’s resources are destroyed, for each window in the client’s save-set, if the window is an inferior of a window created by the client, the save-set window is reparented to the closest ancestor such that the save-set window is not an inferior of a window created by the client. If the save-set window is unmapped, a MapWindow request is performed on it (even if it was not an inferior of a window created by the client). The reparenting leaves unchanged the absolute coordinates (with respect to the root window) of the upper-left outer corner of the save-set window. After save-set processing, all windows created by the client are destroyed. For each nonwindow resource created by the client, the appropriate Free request is performed. All colors and colormap entries allocated by the client are freed.

A server goes through a cycle of having no connections and having some connections. At every transition to the state of having no connections as a result of a connection closing with a Destroy close-down mode, the server resets its state as if it had just been started. This starts by destroying all lingering resources from clients that have terminated in RetainPermanent or RetainTemporary mode. It additionally includes deleting all but the predefined atom identifiers, deleting all properties on all root windows, resetting all device maps and attributes (key click, bell volume, acceleration), resetting the access control list, restoring the standard root tiles and cursors, restoring the default font path, and restoring the input focus to state PointerRoot.

Note that closing a connection with a close-down mode of RetainPermanent or RetainTemporary will not cause the server to reset.

11. Events

When a button press is processed with the pointer in some window W and no active pointer grab is in progress, the ancestors of W are searched from the root down, looking for a passive grab to activate. If no matching passive grab on the button exists, then an active grab is started automatically for the client receiving the event, and the last-pointer-grab time is set to the current server time. The effect is essentially equivalent to a GrabButton with arguments:
Argument Value
event-window
Event window
event-mask
Client’s selected pointer events
on the event window
pointer-mode and
keyboard-mode
Asynchronous
owner-events
True if the client has
OwnerGrabButton selected on the
event window, otherwise False
confine-to
None
cursor
None

The grab is terminated automatically when the logical state of the pointer has all buttons released. UngrabPointer and ChangeActivePointerGrab can both be used to modify the active grab. __ │
KeyPress
KeyRelease
ButtonPress
ButtonRelease
MotionNotify

root, event: WINDOW
child: WINDOW or None
same-screen: BOOL
root-x, root-y, event-x, event-y: INT16
detail: <see below>
state: SETofKEYBUTMASK
time: TIMESTAMP│__

These events are generated either when a key or button logically changes state or when the pointer logically moves. The generation of these logical changes may lag the physical changes if device event processing is frozen. Note that KeyPress and KeyRelease are generated for all keys, even those mapped to modifier bits. The source of the event is the window the pointer is in. The window the event is reported with respect to is called the event window. The event window is found by starting with the source window and looking up the hierarchy for the first window on which any client has selected interest in the event (provided no intervening window prohibits event generation by including the event type in its do-not-propagate-mask). The actual window used for reporting can be modified by active grabs and, in the case of keyboard events, can be modified by the focus window.

The root is the root window of the source window, and root-x and root-y are the pointer coordinates relative to root’s origin at the time of the event. Event is the event window. If the event window is on the same screen as root, then event-x and event-y are the pointer coordinates relative to the event window’s origin. Otherwise, event-x and event-y are zero. If the source window is an inferior of the event window, then child is set to the child of the event window that is an ancestor of (or is) the source window. Otherwise, it is set to None. The state component gives the logical state of the buttons and modifier keys just before the event. The detail component type varies with the event type:
Event Component
KeyPress, KeyRelease
KEYCODE
ButtonPress,
ButtonRelease
BUTTON
MotionNotify
{Normal, Hint}

MotionNotify events are only generated when the motion begins and ends in the window. The granularity of motion events is not guaranteed, but a client selecting for motion events is guaranteed to get at least one event when the pointer moves and comes to rest. Selecting PointerMotion receives events independent of the state of the pointer buttons. By selecting some subset of Button[1-5]Motion instead, MotionNotify events will only be received when one or more of the specified buttons are pressed. By selecting ButtonMotion, MotionNotify events will be received only when at least one button is pressed. The events are always of type MotionNotify, independent of the selection. If PointerMotionHint is selected, the server is free to send only one MotionNotify event (with detail Hint) to the client for the event window until either the key or button state changes, the pointer leaves the event window, or the client issues a QueryPointer or GetMotionEvents request. __ │
EnterNotify
LeaveNotify

root, event: WINDOW
child: WINDOW or None
same-screen: BOOL
root-x, root-y, event-x, event-y: INT16
mode: {Normal, Grab, Ungrab}
detail: {Ancestor, Virtual, Inferior, Nonlinear, Nonlin-
earVirtual}
focus: BOOL
state: SETofKEYBUTMASK
time: TIMESTAMP│__

If pointer motion or window hierarchy change causes the pointer to be in a different window than before, EnterNotify and LeaveNotify events are generated instead of a MotionNotify event. Only clients selecting EnterWindow on a window receive EnterNotify events, and only clients selecting LeaveWindow receive LeaveNotify events. The pointer position reported in the event is always the final position, not the initial position of the pointer. The root is the root window for this position, and root-x and root-y are the pointer coordinates relative to root’s origin at the time of the event. Event is the event window. If the event window is on the same screen as root, then event-x and event-y are the pointer coordinates relative to the event window’s origin. Otherwise, event-x and event-y are zero. In a LeaveNotify event, if a child of the event window contains the initial position of the pointer, then the child component is set to that child. Otherwise, it is None. For an EnterNotify event, if a child of the event window contains the final pointer position, then the child component is set to that child. Otherwise, it is None. If the event window is the focus window or an inferior of the focus window, then focus is True. Otherwise, focus is False.

Normal pointer motion events have mode Normal. Pseudo-motion events when a grab activates have mode Grab, and pseudo-motion events when a grab deactivates have mode Ungrab.

All EnterNotify and LeaveNotify events caused by a hierarchy change are generated after any hierarchy event caused by that change (that is, UnmapNotify, MapNotify, ConfigureNotify, GravityNotify, CirculateNotify), but the ordering of EnterNotify and LeaveNotify events with respect to FocusOut, VisibilityNotify, and Expose events is not constrained.

Normal events are generated as follows:

When the pointer moves from window A to window B and A is an inferior of B:

When the pointer moves from window A to window B and B is an inferior of A:

When the pointer moves from window A to window B and window C is their least common ancestor:

When the pointer moves from window A to window B on different screens:

When a pointer grab activates (but after any initial warp into a confine-to window and before generating any actual ButtonPress event that activates the grab), G is the grab-window for the grab, and P is the window the pointer is in:

When a pointer grab deactivates (but after generating any actual ButtonRelease event that deactivates the grab), G is the grab-window for the grab, and P is the window the pointer is in:

FocusIn
FocusOut

event: WINDOW
mode: {Normal, WhileGrabbed, Grab, Ungrab}
detail: {Ancestor, Virtual, Inferior, Nonlinear, Nonlin-
earVirtual, Pointer,            
PointerRoot, None}│__

These events are generated when the input focus changes and are reported to clients selecting FocusChange on the window. Events generated by SetInputFocus when the keyboard is not grabbed have mode Normal. Events generated by SetInputFocus when the keyboard is grabbed have mode WhileGrabbed. Events generated when a keyboard grab activates have mode Grab, and events generated when a keyboard grab deactivates have mode Ungrab.

All FocusOut events caused by a window unmap are generated after any UnmapNotify event, but the ordering of FocusOut with respect to generated EnterNotify, LeaveNotify, VisibilityNotify, and Expose events is not constrained.

Normal and WhileGrabbed events are generated as follows:

When the focus moves from window A to window B, A is an inferior of B, and the pointer is in window P:

When the focus moves from window A to window B, B is an inferior of A, and the pointer is in window P:

When the focus moves from window A to window B, window C is their least common ancestor, and the pointer is in window P:

When the focus moves from window A to window B on different screens and the pointer is in window P:

When the focus moves from window A to PointerRoot (or None) and the pointer is in window P:

When the focus moves from PointerRoot (or None) to window A and the pointer is in window P:

When the focus moves from PointerRoot to None (or vice versa) and the pointer is in window P:

When a keyboard grab activates (but before generating any actual KeyPress event that activates the grab), G is the grab-window for the grab, and F is the current focus:

When a keyboard grab deactivates (but after generating any actual KeyRelease event that deactivates the grab), G is the grab-window for the grab, and F is the current focus:

KeymapNotify

keys: LISTofCARD8│__

The value is a bit vector as described in QueryKeymap. This event is reported to clients selecting KeymapState on a window and is generated immediately after every EnterNotify and FocusIn. __ │
Expose

window: WINDOW
x, y, width, height: CARD16
count: CARD16│__

This event is reported to clients selecting Exposure on the window. It is generated when no valid contents are available for regions of a window, and either the regions are visible, the regions are viewable and the server is (perhaps newly) maintaining backing store on the window, or the window is not viewable but the server is (perhaps newly) honoring window’s backing-store attribute of Always or WhenMapped. The regions are decomposed into an arbitrary set of rectangles, and an Expose event is generated for each rectangle.

For a given action causing exposure events, the set of events for a given window are guaranteed to be reported contiguously. If count is zero, then no more Expose events for this window follow. If count is nonzero, then at least that many more Expose events for this window follow (and possibly more).

The x and y coordinates are relative to window’s origin and specify the upper-left corner of a rectangle. The width and height specify the extent of the rectangle.

Expose events are never generated on InputOnly windows.

All Expose events caused by a hierarchy change are generated after any hierarchy event caused by that change (for example, UnmapNotify, MapNotify, ConfigureNotify, GravityNotify, CirculateNotify). All Expose events on a given window are generated after any VisibilityNotify event on that window, but it is not required that all Expose events on all windows be generated after all Visibilitity events on all windows. The ordering of Expose events with respect to FocusOut, EnterNotify, and LeaveNotify events is not constrained. __ │
GraphicsExposure

drawable: DRAWABLE
x, y, width, height: CARD16
count: CARD16
major-opcode: CARD8
minor-opcode: CARD16│__

This event is reported to a client using a graphics context with graphics-exposures selected and is generated when a destination region could not be computed due to an obscured or out-of-bounds source region. All of the regions exposed by a given graphics request are guaranteed to be reported contiguously. If count is zero then no more GraphicsExposure events for this window follow. If count is nonzero, then at least that many more GraphicsExposure events for this window follow (and possibly more).

The x and y coordinates are relative to drawable’s origin and specify the upper-left corner of a rectangle. The width and height specify the extent of the rectangle.

The major and minor opcodes identify the graphics request used. For the core protocol, major-opcode is always CopyArea or CopyPlane, and minor-opcode is always zero. __ │
NoExposure

drawable: DRAWABLE
major-opcode: CARD8
minor-opcode: CARD16│__

This event is reported to a client using a graphics context with graphics-exposures selected and is generated when a graphics request that might produce GraphicsExposure events does not produce any. The drawable specifies the destination used for the graphics request.

The major and minor opcodes identify the graphics request used. For the core protocol, major-opcode is always CopyArea or CopyPlane, and the minor-opcode is always zero. __ │
VisibilityNotify

window: WINDOW
state: {Unobscured, PartiallyObscured, FullyObscured}│__

This event is reported to clients selecting VisibilityChange on the window. In the following, the state of the window is calculated ignoring all of the window’s subwindows. When a window changes state from partially or fully obscured or not viewable to viewable and completely unobscured, an event with Unobscured is generated. When a window changes state from viewable and completely unobscured, from viewable and completely obscured, or from not viewable, to viewable and partially obscured, an event with PartiallyObscured is generated. When a window changes state from viewable and completely unobscured, from viewable and partially obscured, or from not viewable to viewable and fully obscured, an event with FullyObscured is generated.

VisibilityNotify events are never generated on InputOnly windows.

All VisibilityNotify events caused by a hierarchy change are generated after any hierarchy event caused by that change (for example, UnmapNotify, MapNotify, ConfigureNotify, GravityNotify, CirculateNotify). Any VisibilityNotify event on a given window is generated before any Expose events on that window, but it is not required that all VisibilityNotify events on all windows be generated before all Expose events on all windows. The ordering of VisibilityNotify events with respect to FocusOut, EnterNotify, and LeaveNotify events is not constrained. __ │
CreateNotify

parent, window: WINDOW
x, y: INT16
width, height, border-width: CARD16
override-redirect: BOOL│__

This event is reported to clients selecting SubstructureNotify on the parent and is generated when the window is created. The arguments are as in the CreateWindow request. __ │
DestroyNotify

event, window: WINDOW│__

This event is reported to clients selecting StructureNotify on the window and to clients selecting SubstructureNotify on the parent. It is generated when the window is destroyed. The event is the window on which the event was generated, and the window is the window that is destroyed.

The ordering of the DestroyNotify events is such that for any given window, DestroyNotify is generated on all inferiors of the window before being generated on the window itself. The ordering among siblings and across subhierarchies is not otherwise constrained. __ │
UnmapNotify

event, window: WINDOW
from-configure: BOOL│__

This event is reported to clients selecting StructureNotify on the window and to clients selecting SubstructureNotify on the parent. It is generated when the window changes state from mapped to unmapped. The event is the window on which the event was generated, and the window is the window that is unmapped. The from-configure flag is True if the event was generated as a result of the window’s parent being resized when the window itself had a win-gravity of Unmap. __ │
MapNotify

event, window: WINDOW
override-redirect: BOOL│__

This event is reported to clients selecting StructureNotify on the window and to clients selecting SubstructureNotify on the parent. It is generated when the window changes state from unmapped to mapped. The event is the window on which the event was generated, and the window is the window that is mapped. The override-redirect flag is from the window’s attribute. __ │
MapRequest

parent, window: WINDOW│__

This event is reported to the client selecting SubstructureRedirect on the parent and is generated when a MapWindow request is issued on an unmapped window with an override-redirect attribute of False. __ │
ReparentNotify

event, window, parent: WINDOW
x, y: INT16
override-redirect: BOOL│__

This event is reported to clients selecting SubstructureNotify on either the old or the new parent and to clients selecting StructureNotify on the window. It is generated when the window is reparented. The event is the window on which the event was generated. The window is the window that has been rerooted. The parent specifies the new parent. The x and y coordinates are relative to the new parent’s origin and specify the position of the upper-left outer corner of the window. The override-redirect flag is from the window’s attribute. __ │
ConfigureNotify

event, window: WINDOW
x, y: INT16
width, height, border-width: CARD16
above-sibling: WINDOW or None
override-redirect: BOOL│__

This event is reported to clients selecting StructureNotify on the window and to clients selecting SubstructureNotify on the parent. It is generated when a ConfigureWindow request actually changes the state of the window. The event is the window on which the event was generated, and the window is the window that is changed. The x and y coordinates are relative to the new parent’s origin and specify the position of the upper-left outer corner of the window. The width and height specify the inside size, not including the border. If above-sibling is None, then the window is on the bottom of the stack with respect to siblings. Otherwise, the window is immediately on top of the specified sibling. The override-redirect flag is from the window’s attribute. __ │
GravityNotify

event, window: WINDOW
x, y: INT16│__

This event is reported to clients selecting SubstructureNotify on the parent and to clients selecting StructureNotify on the window. It is generated when a window is moved because of a change in size of the parent. The event is the window on which the event was generated, and the window is the window that is moved. The x and y coordinates are relative to the new parent’s origin and specify the position of the upper-left outer corner of the window. __ │
ResizeRequest

window: WINDOW
width, height: CARD16│__

This event is reported to the client selecting ResizeRedirect on the window and is generated when a ConfigureWindow request by some other client on the window attempts to change the size of the window. The width and height are the requested inside size, not including the border. __ │
ConfigureRequest

parent, window: WINDOW
x, y: INT16
width, height, border-width: CARD16
sibling: WINDOW or None
stack-mode: {Above, Below, TopIf, BottomIf, Opposite}
value-mask: BITMASK│__

This event is reported to the client selecting SubstructureRedirect on the parent and is generated when a ConfigureWindow request is issued on the window by some other client. The value-mask indicates which components were specified in the request. The value-mask and the corresponding values are reported as given in the request. The remaining values are filled in from the current geometry of the window, except in the case of sibling and stack-mode, which are reported as None and Above (respectively) if not given in the request. __ │
CirculateNotify

event, window: WINDOW
place: {Top, Bottom}│__

This event is reported to clients selecting StructureNotify on the window and to clients selecting SubstructureNotify on the parent. It is generated when the window is actually restacked from a CirculateWindow request. The event is the window on which the event was generated, and the window is the window that is restacked. If place is Top, the window is now on top of all siblings. Otherwise, it is below all siblings. __ │
CirculateRequest

parent, window: WINDOW
place: {Top, Bottom}│__

This event is reported to the client selecting SubstructureRedirect on the parent and is generated when a CirculateWindow request is issued on the parent and a window actually needs to be restacked. The window specifies the window to be restacked, and the place specifies what the new position in the stacking order should be. __ │
PropertyNotify

window: WINDOW
atom: ATOM
state: {NewValue, Deleted}
time: TIMESTAMP│__

This event is reported to clients selecting PropertyChange on the window and is generated with state NewValue when a property of the window is changed using ChangeProperty or RotateProperties, even when adding zero-length data using ChangeProperty and when replacing all or part of a property with identical data using ChangeProperty or RotateProperties. It is generated with state Deleted when a property of the window is deleted using request DeleteProperty or GetProperty. The timestamp indicates the server time when the property was changed. __ │
SelectionClear

owner: WINDOW
selection: ATOM
time: TIMESTAMP│__

This event is reported to the current owner of a selection and is generated when a new owner is being defined by means of SetSelectionOwner. The timestamp is the last-change time recorded for the selection. The owner argument is the window that was specified by the current owner in its SetSelectionOwner request. __ │
SelectionRequest

owner: WINDOW
selection: ATOM
target: ATOM
property: ATOM or None
requestor: WINDOW
time: TIMESTAMP or CurrentTime│__

This event is reported to the owner of a selection and is generated when a client issues a ConvertSelection request. The owner argument is the window that was specified in the SetSelectionOwner request. The remaining arguments are as in the ConvertSelection request.

The owner should convert the selection based on the specified target type and send a SelectionNotify back to the requestor. A complete specification for using selections is given in the X.Org standard Inter-Client Communication Conventions Manual. __ │
SelectionNotify

requestor: WINDOW
selection, target: ATOM
property: ATOM or None
time: TIMESTAMP or CurrentTime│__

This event is generated by the server in response to a ConvertSelection request when there is no owner for the selection. When there is an owner, it should be generated by the owner using SendEvent. The owner of a selection should send this event to a requestor either when a selection has been converted and stored as a property or when a selection conversion could not be performed (indicated with property None). __ │
ColormapNotify

window: WINDOW
colormap: COLORMAP or None
new: BOOL
state: {Installed, Uninstalled}│__

This event is reported to clients selecting ColormapChange on the window. It is generated with value True for new when the colormap attribute of the window is changed and is generated with value False for new when the colormap of a window is installed or uninstalled. In either case, the state indicates whether the colormap is currently installed. __ │
MappingNotify

request: {Modifier, Keyboard, Pointer}
first-keycode, count: CARD8│__

This event is sent to all clients. There is no mechanism to express disinterest in this event. The detail indicates the kind of change that occurred: Modifiers for a successful SetModifierMapping, Keyboard for a successful ChangeKeyboardMapping, and Pointer for a successful SetPointerMapping. If the detail is Keyboard, then first-keycode and count indicate the range of altered keycodes. __ │
ClientMessage

window: WINDOW
type: ATOM
format: {8, 16, 32}
data: LISTofINT8 or LISTofINT16 or LISTofINT32│__

This event is only generated by clients using SendEvent. The type specifies how the data is to be interpreted by the receiving client; the server places no interpretation on the type or the data. The format specifies whether the data should be viewed as a list of 8-bit, 16-bit, or 32-bit quantities, so that the server can correctly byte-swap, as necessary. The data always consists of either 20 8-bit values or 10 16-bit values or 5 32-bit values, although particular message types might not make use of all of these values.

12. Flow Control and Concurrency

Whenever the server is writing to a given connection, it is permissible for the server to stop reading from that connection (but if the writing would block, it must continue to service other connections). The server is not required to buffer more than a single request per connection at one time. For a given connection to the server, a client can block while reading from the connection but should undertake to read (events and errors) when writing would block. Failure on the part of a client to obey this rule could result in a deadlocked connection, although deadlock is probably unlikely unless either the transport layer has very little buffering or the client attempts to send large numbers of requests without ever reading replies or checking for errors and events.

Whether or not a server is implemented with internal concurrency, the overall effect must be as if individual requests are executed to completion in some serial order, and requests from a given connection must be executed in delivery order (that is, the total execution order is a shuffle of the individual streams). The execution of a request includes validating all arguments, collecting all data for any reply, and generating and queueing all required events. However, it does not include the actual transmission of the reply and the events. In addition, the effect of any other cause that can generate multiple events (for example, activation of a grab or pointer motion) must effectively generate and queue all required events indivisibly with respect to all other causes and requests. For a request from a given client, any events destined for that client that are caused by executing the request must be sent to the client before any reply or error is sent.

1

X Protocol X11, Release 6.8

Appendix A

KEYSYM Encoding

KEYSYM values are 32-bit integers that encode the symbols on the keycaps of a keyboard. The three most significant bits are always zero, which leaves a 29-bit number space. For convenience, KEYSYM values can be viewed as split into four bytes:

There are six categories of KEYSYM values.

A.1 Special KEYSYMs

There are two special values: NoSymbol and VoidSymbol. They are used to indicate the absence of symbols (see section 5).
Byte 1 Byte 2 Byte 3 Byte 4 Hex. value Name
0 0 0 0 #x00000000
NoSymbol
0 255 255 255 #x00FFFFFF
VoidSymbol

A.2 Latin-1 KEYSYMs

The Latin-1 KEYSYMs occupy the range #x0020 to #x007E and #x00A0 to #00FF and represent the ISO 10646 / Unicode characters U+0020 to U+007E and U+00A0 to U+00FF, respectively.

A.3 Unicode KEYSYMs

These occupy the range #x01000100 to #x0110FFFF and represent the ISO 10646 / Unicode characters U+0100 to U+10FFFF, respectively. The numeric value of a Unicode KEYSYM is the Unicode position of the corresponding character plus #x01000000. In the interest of backwards compatibility, clients should be able to process both the Unicode KEYSYM and the Legacy KEYSYM for those characters where both exist.

Dead keys, which place an accent on the next character entered, shall be encoded as Function KEYSYMs, and not as the Unicode KEYSYM corresponding to an equivalent combining character. Where a keycap indicates a specific function with a graphical symbol that is also available in Unicode (e.g., an upwards arrow for the cursor up function), the appropriate Function KEYSYM should be used, and not the Unicode KEYSYM corresponding to the depicted symbol.

A.4 Function KEYSYMs

These represent keycap symbols that do not directly represent elements of a coded character set. Instead, they typically identify a software function, mode, or operation (e.g., cursor up, caps lock, insert) that can be activated using a dedicated key. Function KEYSYMs have zero values for bytes 1 and 2. Byte 3 distinguishes between several 8-bit sets within which byte 4 identifies the individual function key.
Byte 3 Byte 4
255 Keyboard
254 Keyboard (XKB) Extension
253 3270

Within a national market, keyboards tend to be comparatively standard with respect to the character keys, but they can differ significantly on the miscellaneous function keys. Some have function keys left over from early timesharing days, others were designed for a specific application, such as text processing, web browsing, or accessing audiovisual data. The symbols on the keycaps can differ significantly between manufacturers and national markets, even where they denote the same software function (e.g., Ctrl in the U.S. versus Strg in Germany)

There are two ways of thinking about how to define KEYSYMs for such a world:

The Engraving approach is to create a KEYSYM for every unique key engraving. This is effectively taking the union of all key engravings on all keyboards. For example, some keyboards label function keys across the top as F1 through Fn, and others label them as PF1 through PFn. These would be different keys under the Engraving approach. Likewise, Lock would differ from Shift Lock, which is different from the up-arrow symbol that has the effect of changing lowercase to uppercase. There are lots of other aliases such as Del, DEL, Delete, Remove, and so forth. The Engraving approach makes it easy to decide if a new entry should be added to the KEYSYM set: if it does not exactly match an existing one, then a new one is created.

The Common approach tries to capture all of the keys present on an interesting number of keyboards, folding likely aliases into the same KEYSYM. For example, Del, DEL, and Delete are all merged into a single KEYSYM. Vendors can augment the KEYSYM set (using the vendor-specific encoding space) to include all of their unique keys that were not included in the standard set. Each vendor decides which of its keys map into the standard KEYSYMs, which presumably can be overridden by a user. It is more difficult to implement this approach, because judgment is required about when a sufficient set of keyboards implements an engraving to justify making it a KEYSYM in the standard set and about which engravings should be merged into a single KEYSYM.

Although neither scheme is perfect or elegant, the Common approach has been selected because it makes it easier to write a portable application. Having the Delete functionality merged into a single KEYSYM allows an application to implement a deletion function and expect reasonable bindings on a wide set of workstations. Under the Common approach, application writers are still free to look for and interpret vendor-specific KEYSYMs, but because they are in the extended set, the application developer is more conscious that they are writing the application in a nonportable fashion.

The Keyboard set is a miscellaneous collection of commonly occurring keys on keyboards. Within this set, the numeric keypad symbols are generally duplicates of symbols found on keys on the main part of the keyboard, but they are distinguished here because they often have a distinguishable semantics associated with them.
KEYSYM Name Set
value
#xFF08 BACKSPACE, BACK SPACE, BACK CHAR Keyboard
#xFF09 TAB Keyboard
#xFF0A LINEFEED, LF Keyboard
#xFF0B CLEAR Keyboard
#xFF0D RETURN, ENTER Keyboard
#xFF13 PAUSE, HOLD Keyboard
#xFF14 SCROLL LOCK Keyboard
#xFF15 SYS REQ, SYSTEM REQUEST Keyboard
#xFF1B ESCAPE Keyboard
#xFF20 MULTI-KEY CHARACTER PREFACE Keyboard
#xFF21 KANJI, KANJI CONVERT Keyboard
#xFF22 MUHENKAN Keyboard
#xFF23 HENKAN MODE Keyboard
#xFF24 ROMAJI Keyboard
#xFF25 HIRAGANA Keyboard
#xFF26 KATAKANA Keyboard
#xFF27 HIRAGANA/KATAKANA TOGGLE Keyboard
#xFF28 ZENKAKU Keyboard
#xFF29 HANKAKU Keyboard
#xFF2A ZENKAKU/HANKAKU TOGGLE Keyboard
#xFF2B TOUROKU Keyboard
#xFF2C MASSYO Keyboard
#xFF2D KANA LOCK Keyboard
#xFF2E KANA SHIFT Keyboard
#xFF2F EISU SHIFT Keyboard
#xFF30 EISU TOGGLE Keyboard
#xFF31 HANGUL START/STOP (TOGGLE) Keyboard
#xFF32 HANGUL START Keyboard
#xFF33 HANGUL END, ENGLISH START Keyboard
#xFF34 START HANGUL/HANJA CONVERSION Keyboard
#xFF35 HANGUL JAMO MODE Keyboard
#xFF36 HANGUL ROMAJA MODE Keyboard
#xFF37 HANGUL CODE INPUT Keyboard
#xFF38 HANGUL JEONJA MODE Keyboard
#xFF39 HANGUL BANJA MODE Keyboard
#xFF3A HANGUL PREHANJA CONVERSION Keyboard
#xFF3B HANGUL POSTHANJA CONVERSION Keyboard
#xFF3C HANGUL SINGLE CANDIDATE Keyboard
#xFF3D HANGUL MULTIPLE CANDIDATE Keyboard
#xFF3E HANGUL PREVIOUS CANDIDATE Keyboard
#xFF3F HANGUL SPECIAL SYMBOLS Keyboard
#xFF50 HOME Keyboard
#xFF51 LEFT, MOVE LEFT, LEFT ARROW Keyboard
#xFF52 UP, MOVE UP, UP ARROW Keyboard
#xFF53 RIGHT, MOVE RIGHT, RIGHT ARROW Keyboard
#xFF54 DOWN, MOVE DOWN, DOWN ARROW Keyboard
#xFF55 PRIOR, PREVIOUS, PAGE UP Keyboard
#xFF56 NEXT, PAGE DOWN Keyboard
#xFF57 END, EOL Keyboard
#xFF58 BEGIN, BOL Keyboard
#xFF60 SELECT, MARK Keyboard
#xFF61 PRINT Keyboard
#xFF62 EXECUTE, RUN, DO Keyboard
#xFF63 INSERT, INSERT HERE Keyboard
#xFF65 UNDO, OOPS Keyboard
#xFF66 REDO, AGAIN Keyboard
#xFF67 MENU Keyboard
#xFF68 FIND, SEARCH Keyboard
#xFF69 CANCEL, STOP, ABORT, EXIT Keyboard
#xFF6A HELP Keyboard
#xFF6B BREAK Keyboard
#xFF7E MODE SWITCH, SCRIPT SWITCH, CHARACTER SET SWITCH Keyboard
#xFF7F NUM LOCK Keyboard
#xFF80 KEYPAD SPACE Keyboard
#xFF89 KEYPAD TAB Keyboard
#xFF8D KEYPAD ENTER Keyboard
#xFF91 KEYPAD F1, PF1, A Keyboard
#xFF92 KEYPAD F2, PF2, B Keyboard
#xFF93 KEYPAD F3, PF3, C Keyboard
#xFF94 KEYPAD F4, PF4, D Keyboard
#xFF95 KEYPAD HOME Keyboard
#xFF96 KEYPAD LEFT Keyboard
#xFF97 KEYPAD UP Keyboard
#xFF98 KEYPAD RIGHT Keyboard
#xFF99 KEYPAD DOWN Keyboard
#xFF9A KEYPAD PRIOR, PAGE UP Keyboard
#xFF9B KEYPAD NEXT, PAGE DOWN Keyboard
#xFF9C KEYPAD END Keyboard
#xFF9D KEYPAD BEGIN Keyboard
#xFF9E KEYPAD INSERT Keyboard
#xFF9F KEYPAD DELETE Keyboard
#xFFAA KEYPAD MULTIPLICATION SIGN, ASTERISK Keyboard
#xFFAB KEYPAD PLUS SIGN Keyboard
#xFFAC KEYPAD SEPARATOR, COMMA Keyboard
#xFFAD KEYPAD MINUS SIGN, HYPHEN Keyboard
#xFFAE KEYPAD DECIMAL POINT, FULL STOP Keyboard
#xFFAF KEYPAD DIVISION SIGN, SOLIDUS Keyboard
#xFFB0 KEYPAD DIGIT ZERO Keyboard
#xFFB1 KEYPAD DIGIT ONE Keyboard
#xFFB2 KEYPAD DIGIT TWO Keyboard
#xFFB3 KEYPAD DIGIT THREE Keyboard
#xFFB4 KEYPAD DIGIT FOUR Keyboard
#xFFB5 KEYPAD DIGIT FIVE Keyboard
#xFFB6 KEYPAD DIGIT SIX Keyboard
#xFFB7 KEYPAD DIGIT SEVEN Keyboard
#xFFB8 KEYPAD DIGIT EIGHT Keyboard
#xFFB9 KEYPAD DIGIT NINE Keyboard
#xFFBD KEYPAD EQUALS SIGN Keyboard
#xFFBE F1 Keyboard
#xFFBF F2 Keyboard
#xFFC0 F3 Keyboard
#xFFC1 F4 Keyboard
#xFFC2 F5 Keyboard
#xFFC3 F6 Keyboard
#xFFC4 F7 Keyboard
#xFFC5 F8 Keyboard
#xFFC6 F9 Keyboard
#xFFC7 F10 Keyboard
#xFFC8 F11, L1 Keyboard
#xFFC9 F12, L2 Keyboard
#xFFCA F13, L3 Keyboard
#xFFCB F14, L4 Keyboard
#xFFCC F15, L5 Keyboard
#xFFCD F16, L6 Keyboard
#xFFCE F17, L7 Keyboard
#xFFCF F18, L8 Keyboard
#xFFD0 F19, L9 Keyboard
#xFFD1 F20, L10 Keyboard
#xFFD2 F21, R1 Keyboard
#xFFD3 F22, R2 Keyboard
#xFFD4 F23, R3 Keyboard
#xFFD5 F24, R4 Keyboard
#xFFD6 F25, R5 Keyboard
#xFFD7 F26, R6 Keyboard
#xFFD8 F27, R7 Keyboard
#xFFD9 F28, R8 Keyboard
#xFFDA F29, R9 Keyboard
#xFFDB F30, R10 Keyboard
#xFFDC F31, R11 Keyboard
#xFFDD F32, R12 Keyboard
#xFFDE F33, R13 Keyboard
#xFFDF F34, R14 Keyboard
#xFFE0 F35, R15 Keyboard
#xFFE1 LEFT SHIFT Keyboard
#xFFE2 RIGHT SHIFT Keyboard
#xFFE3 LEFT CONTROL Keyboard
#xFFE4 RIGHT CONTROL Keyboard
#xFFE5 CAPS LOCK Keyboard
#xFFE6 SHIFT LOCK Keyboard
#xFFE7 LEFT META Keyboard
#xFFE8 RIGHT META Keyboard
#xFFE9 LEFT ALT Keyboard
#xFFEA RIGHT ALT Keyboard
#xFFEB LEFT SUPER Keyboard
#xFFEC RIGHT SUPER Keyboard
#xFFED LEFT HYPER Keyboard
#xFFEE RIGHT HYPER Keyboard
#xFFFF DELETE, RUBOUT Keyboard

The Keyboard (XKB) Extension set, which provides among other things a range of dead keys, is defined in ‘‘The X Keyboard Extension: Protocol Specification’’, Appendix C.

The 3270 set defines additional keys that are specific to IBM 3270 terminals.
KEYSYM Name Set
value
#xFD01 3270 DUPLICATE 3270
#xFD02 3270 FIELDMARK 3270
#xFD03 3270 RIGHT2 3270
#xFD04 3270 LEFT2 3270
#xFD05 3270 BACKTAB 3270
#xFD06 3270 ERASEEOF 3270
#xFD07 3270 ERASEINPUT 3270
#xFD08 3270 RESET 3270
#xFD09 3270 QUIT 3270
#xFD0A 3270 PA1 3270
#xFD0B 3270 PA2 3270
#xFD0C 3270 PA3 3270
#xFD0D 3270 TEST 3270
#xFD0E 3270 ATTN 3270
#xFD0F 3270 CURSORBLINK 3270
#xFD10 3270 ALTCURSOR 3270
#xFD11 3270 KEYCLICK 3270
#xFD12 3270 JUMP 3270
#xFD13 3270 IDENT 3270
#xFD14 3270 RULE 3270
#xFD15 3270 COPY 3270
#xFD16 3270 PLAY 3270
#xFD17 3270 SETUP 3270
#xFD18 3270 RECORD 3270
#xFD19 3270 CHANGESCREEN 3270
#xFD1A 3270 DELETEWORD 3270
#xFD1B 3270 EXSELECT 3270
#xFD1C 3270 CURSORSELECT 3270
#xFD1D 3270 PRINTSCREEN 3270
#xFD1E 3270 ENTER 3270

A.5 Vendor KEYSYMs

The KEYSYM number range #x10000000 to #x1FFFFFFF is available for vendor-specific extentions. Among these, the range #x11000000 to #x1100FFFF is designated for keypad KEYSYMs.

A.6 Legacy KEYSYMs

These date from the time before ISO 10646 / Unicode was available. They represent characters from a number of different older 8-bit coded character sets and have zero values for bytes 1 and 2. Byte 3 indicates a coded character set and byte 4 is the 8-bit value of the particular character within that set.
Byte 3 Byte 4 Byte 3 Byte 4
1 Latin-2 11 APL
2 Latin-3 12 Hebrew
3 Latin-4 13 Thai
4 Kana 14 Korean
5 Arabic 15 Latin-5
6 Cyrillic 16 Latin-6
7 Greek 17 Latin-7
8 Technical 18 Latin-8
9 Special 19 Latin-9
10 Publishing 32 Currency

Each character set contains gaps where codes have been removed that were duplicates with codes in previous character sets (that is, character sets with lesser byte 3 value).

The Latin, Arabic, Cyrillic, Greek, Hebrew, and Thai sets were taken from the early drafts of the relevant ISO 8859 parts available at the time. However, in the case of the Cyrillic and Greek sets, these turned out differently in the final versions of the ISO standard. The Technical, Special, and Publishing sets are based on Digital Equipment Corporation standards, as no equivalent international standards were available at the time.

The table below lists all standardized Legacy KEYSYMs, along with the name used in the source document. Where there exists an unambiguous equivalent in Unicode, as it is the case with all ISO 8859 characters, it is given in the second column as a cross reference. Where there is no Unicode number provided, the exact semantics of the KEYSYM may have been lost and a Unicode KEYSYM should be used instead, if available.

As support of Unicode KEYSYMs increases, some or all of the Legacy KEYSYMs may be phased out and withdrawn in future versions of this standard. Most KEYSYMs in the sets Technical, Special, Publishing, APL and Currency (with the exception of #x20AC) were probably never used in practice, and were not supported by pre-Unicode fonts. In particular, the Currency set, which was copied from Unicode, has already been deprecated by the introduction of the Unicode KEYSYMs.
KEYSYM Unicode Name Set
value value
#x01A1 U+0104 LATIN CAPITAL LETTER A WITH OGONEK Latin-2
#x01A2 U+02D8 BREVE Latin-2
#x01A3 U+0141 LATIN CAPITAL LETTER L WITH STROKE Latin-2
#x01A5 U+013D LATIN CAPITAL LETTER L WITH CARON Latin-2
#x01A6 U+015A LATIN CAPITAL LETTER S WITH ACUTE Latin-2
#x01A9 U+0160 LATIN CAPITAL LETTER S WITH CARON Latin-2
#x01AA U+015E LATIN CAPITAL LETTER S WITH CEDILLA Latin-2
#x01AB U+0164 LATIN CAPITAL LETTER T WITH CARON Latin-2
#x01AC U+0179 LATIN CAPITAL LETTER Z WITH ACUTE Latin-2
#x01AE U+017D LATIN CAPITAL LETTER Z WITH CARON Latin-2
#x01AF U+017B LATIN CAPITAL LETTER Z WITH DOT ABOVE Latin-2
#x01B1 U+0105 LATIN SMALL LETTER A WITH OGONEK Latin-2
#x01B2 U+02DB OGONEK Latin-2
#x01B3 U+0142 LATIN SMALL LETTER L WITH STROKE Latin-2
#x01B5 U+013E LATIN SMALL LETTER L WITH CARON Latin-2
#x01B6 U+015B LATIN SMALL LETTER S WITH ACUTE Latin-2
#x01B7 U+02C7 CARON Latin-2
#x01B9 U+0161 LATIN SMALL LETTER S WITH CARON Latin-2
#x01BA U+015F LATIN SMALL LETTER S WITH CEDILLA Latin-2
#x01BB U+0165 LATIN SMALL LETTER T WITH CARON Latin-2
#x01BC U+017A LATIN SMALL LETTER Z WITH ACUTE Latin-2
#x01BD U+02DD DOUBLE ACUTE ACCENT Latin-2
#x01BE U+017E LATIN SMALL LETTER Z WITH CARON Latin-2
#x01BF U+017C LATIN SMALL LETTER Z WITH DOT ABOVE Latin-2
#x01C0 U+0154 LATIN CAPITAL LETTER R WITH ACUTE Latin-2
#x01C3 U+0102 LATIN CAPITAL LETTER A WITH BREVE Latin-2
#x01C5 U+0139 LATIN CAPITAL LETTER L WITH ACUTE Latin-2
#x01C6 U+0106 LATIN CAPITAL LETTER C WITH ACUTE Latin-2
#x01C8 U+010C LATIN CAPITAL LETTER C WITH CARON Latin-2
#x01CA U+0118 LATIN CAPITAL LETTER E WITH OGONEK Latin-2
#x01CC U+011A LATIN CAPITAL LETTER E WITH CARON Latin-2
#x01CF U+010E LATIN CAPITAL LETTER D WITH CARON Latin-2
#x01D0 U+0110 LATIN CAPITAL LETTER D WITH STROKE Latin-2
#x01D1 U+0143 LATIN CAPITAL LETTER N WITH ACUTE Latin-2
#x01D2 U+0147 LATIN CAPITAL LETTER N WITH CARON Latin-2
#x01D5 U+0150 LATIN CAPITAL LETTER O WITH DOUBLE ACUTE Latin-2
#x01D8 U+0158 LATIN CAPITAL LETTER R WITH CARON Latin-2
#x01D9 U+016E LATIN CAPITAL LETTER U WITH RING ABOVE Latin-2
#x01DB U+0170 LATIN CAPITAL LETTER U WITH DOUBLE ACUTE Latin-2
#x01DE U+0162 LATIN CAPITAL LETTER T WITH CEDILLA Latin-2
#x01E0 U+0155 LATIN SMALL LETTER R WITH ACUTE Latin-2
#x01E3 U+0103 LATIN SMALL LETTER A WITH BREVE Latin-2
#x01E5 U+013A LATIN SMALL LETTER L WITH ACUTE Latin-2
#x01E6 U+0107 LATIN SMALL LETTER C WITH ACUTE Latin-2
#x01E8 U+010D LATIN SMALL LETTER C WITH CARON Latin-2
#x01EA U+0119 LATIN SMALL LETTER E WITH OGONEK Latin-2
#x01EC U+011B LATIN SMALL LETTER E WITH CARON Latin-2
#x01EF U+010F LATIN SMALL LETTER D WITH CARON Latin-2
#x01F0 U+0111 LATIN SMALL LETTER D WITH STROKE Latin-2
#x01F1 U+0144 LATIN SMALL LETTER N WITH ACUTE Latin-2
#x01F2 U+0148 LATIN SMALL LETTER N WITH CARON Latin-2
#x01F5 U+0151 LATIN SMALL LETTER O WITH DOUBLE ACUTE Latin-2
#x01F8 U+0159 LATIN SMALL LETTER R WITH CARON Latin-2
#x01F9 U+016F LATIN SMALL LETTER U WITH RING ABOVE Latin-2
#x01FB U+0171 LATIN SMALL LETTER U WITH DOUBLE ACUTE Latin-2
#x01FE U+0163 LATIN SMALL LETTER T WITH CEDILLA Latin-2
#x01FF U+02D9 DOT ABOVE Latin-2

#x02A1 U+0126 LATIN CAPITAL LETTER H WITH STROKE Latin-3
#x02A6 U+0124 LATIN CAPITAL LETTER H WITH CIRCUMFLEX Latin-3
#x02A9 U+0130 LATIN CAPITAL LETTER I WITH DOT ABOVE Latin-3
#x02AB U+011E LATIN CAPITAL LETTER G WITH BREVE Latin-3
#x02AC U+0134 LATIN CAPITAL LETTER J WITH CIRCUMFLEX Latin-3
#x02B1 U+0127 LATIN SMALL LETTER H WITH STROKE Latin-3
#x02B6 U+0125 LATIN SMALL LETTER H WITH CIRCUMFLEX Latin-3
#x02B9 U+0131 LATIN SMALL LETTER DOTLESS I Latin-3
#x02BB U+011F LATIN SMALL LETTER G WITH BREVE Latin-3
#x02BC U+0135 LATIN SMALL LETTER J WITH CIRCUMFLEX Latin-3
#x02C5 U+010A LATIN CAPITAL LETTER C WITH DOT ABOVE Latin-3
#x02C6 U+0108 LATIN CAPITAL LETTER C WITH CIRCUMFLEX Latin-3
#x02D5 U+0120 LATIN CAPITAL LETTER G WITH DOT ABOVE Latin-3
#x02D8 U+011C LATIN CAPITAL LETTER G WITH CIRCUMFLEX Latin-3
#x02DD U+016C LATIN CAPITAL LETTER U WITH BREVE Latin-3
#x02DE U+015C LATIN CAPITAL LETTER S WITH CIRCUMFLEX Latin-3
#x02E5 U+010B LATIN SMALL LETTER C WITH DOT ABOVE Latin-3
#x02E6 U+0109 LATIN SMALL LETTER C WITH CIRCUMFLEX Latin-3
#x02F5 U+0121 LATIN SMALL LETTER G WITH DOT ABOVE Latin-3
#x02F8 U+011D LATIN SMALL LETTER G WITH CIRCUMFLEX Latin-3
#x02FD U+016D LATIN SMALL LETTER U WITH BREVE Latin-3
#x02FE U+015D LATIN SMALL LETTER S WITH CIRCUMFLEX Latin-3

#x03A2 U+0138 LATIN SMALL LETTER KRA Latin-4
#x03A3 U+0156 LATIN CAPITAL LETTER R WITH CEDILLA Latin-4
#x03A5 U+0128 LATIN CAPITAL LETTER I WITH TILDE Latin-4
#x03A6 U+013B LATIN CAPITAL LETTER L WITH CEDILLA Latin-4
#x03AA U+0112 LATIN CAPITAL LETTER E WITH MACRON Latin-4
#x03AB U+0122 LATIN CAPITAL LETTER G WITH CEDILLA Latin-4
#x03AC U+0166 LATIN CAPITAL LETTER T WITH STROKE Latin-4
#x03B3 U+0157 LATIN SMALL LETTER R WITH CEDILLA Latin-4
#x03B5 U+0129 LATIN SMALL LETTER I WITH TILDE Latin-4
#x03B6 U+013C LATIN SMALL LETTER L WITH CEDILLA Latin-4
#x03BA U+0113 LATIN SMALL LETTER E WITH MACRON Latin-4
#x03BB U+0123 LATIN SMALL LETTER G WITH CEDILLA Latin-4
#x03BC U+0167 LATIN SMALL LETTER T WITH STROKE Latin-4
#x03BD U+014A LATIN CAPITAL LETTER ENG Latin-4
#x03BF U+014B LATIN SMALL LETTER ENG Latin-4
#x03C0 U+0100 LATIN CAPITAL LETTER A WITH MACRON Latin-4
#x03C7 U+012E LATIN CAPITAL LETTER I WITH OGONEK Latin-4
#x03CC U+0116 LATIN CAPITAL LETTER E WITH DOT ABOVE Latin-4
#x03CF U+012A LATIN CAPITAL LETTER I WITH MACRON Latin-4
#x03D1 U+0145 LATIN CAPITAL LETTER N WITH CEDILLA Latin-4
#x03D2 U+014C LATIN CAPITAL LETTER O WITH MACRON Latin-4
#x03D3 U+0136 LATIN CAPITAL LETTER K WITH CEDILLA Latin-4
#x03D9 U+0172 LATIN CAPITAL LETTER U WITH OGONEK Latin-4
#x03DD U+0168 LATIN CAPITAL LETTER U WITH TILDE Latin-4
#x03DE U+016A LATIN CAPITAL LETTER U WITH MACRON Latin-4
#x03E0 U+0101 LATIN SMALL LETTER A WITH MACRON Latin-4
#x03E7 U+012F LATIN SMALL LETTER I WITH OGONEK Latin-4
#x03EC U+0117 LATIN SMALL LETTER E WITH DOT ABOVE Latin-4
#x03EF U+012B LATIN SMALL LETTER I WITH MACRON Latin-4
#x03F1 U+0146 LATIN SMALL LETTER N WITH CEDILLA Latin-4
#x03F2 U+014D LATIN SMALL LETTER O WITH MACRON Latin-4
#x03F3 U+0137 LATIN SMALL LETTER K WITH CEDILLA Latin-4
#x03F9 U+0173 LATIN SMALL LETTER U WITH OGONEK Latin-4
#x03FD U+0169 LATIN SMALL LETTER U WITH TILDE Latin-4
#x03FE U+016B LATIN SMALL LETTER U WITH MACRON Latin-4

#x047E U+203E OVERLINE Kana
#x04A1 U+3002 KANA FULL STOP Kana
#x04A2 U+300C KANA OPENING BRACKET Kana
#x04A3 U+300D KANA CLOSING BRACKET Kana
#x04A4 U+3001 KANA COMMA Kana
#x04A5 U+30FB KANA CONJUNCTIVE Kana
#x04A6 U+30F2 KANA LETTER WO Kana
#x04A7 U+30A1 KANA LETTER SMALL A Kana
#x04A8 U+30A3 KANA LETTER SMALL I Kana
#x04A9 U+30A5 KANA LETTER SMALL U Kana
#x04AA U+30A7 KANA LETTER SMALL E Kana
#x04AB U+30A9 KANA LETTER SMALL O Kana
#x04AC U+30E3 KANA LETTER SMALL YA Kana
#x04AD U+30E5 KANA LETTER SMALL YU Kana
#x04AE U+30E7 KANA LETTER SMALL YO Kana
#x04AF U+30C3 KANA LETTER SMALL TSU Kana
#x04B0 U+30FC PROLONGED SOUND SYMBOL Kana
#x04B1 U+30A2 KANA LETTER A Kana
#x04B2 U+30A4 KANA LETTER I Kana
#x04B3 U+30A6 KANA LETTER U Kana
#x04B4 U+30A8 KANA LETTER E Kana
#x04B5 U+30AA KANA LETTER O Kana
#x04B6 U+30AB KANA LETTER KA Kana
#x04B7 U+30AD KANA LETTER KI Kana
#x04B8 U+30AF KANA LETTER KU Kana
#x04B9 U+30B1 KANA LETTER KE Kana
#x04BA U+30B3 KANA LETTER KO Kana
#x04BB U+30B5 KANA LETTER SA Kana
#x04BC U+30B7 KANA LETTER SHI Kana
#x04BD U+30B9 KANA LETTER SU Kana
#x04BE U+30BB KANA LETTER SE Kana
#x04BF U+30BD KANA LETTER SO Kana
#x04C0 U+30BF KANA LETTER TA Kana
#x04C1 U+30C1 KANA LETTER CHI Kana
#x04C2 U+30C4 KANA LETTER TSU Kana
#x04C3 U+30C6 KANA LETTER TE Kana
#x04C4 U+30C8 KANA LETTER TO Kana
#x04C5 U+30CA KANA LETTER NA Kana
#x04C6 U+30CB KANA LETTER NI Kana
#x04C7 U+30CC KANA LETTER NU Kana
#x04C8 U+30CD KANA LETTER NE Kana
#x04C9 U+30CE KANA LETTER NO Kana
#x04CA U+30CF KANA LETTER HA Kana
#x04CB U+30D2 KANA LETTER HI Kana
#x04CC U+30D5 KANA LETTER FU Kana
#x04CD U+30D8 KANA LETTER HE Kana
#x04CE U+30DB KANA LETTER HO Kana
#x04CF U+30DE KANA LETTER MA Kana
#x04D0 U+30DF KANA LETTER MI Kana
#x04D1 U+30E0 KANA LETTER MU Kana
#x04D2 U+30E1 KANA LETTER ME Kana
#x04D3 U+30E2 KANA LETTER MO Kana
#x04D4 U+30E4 KANA LETTER YA Kana
#x04D5 U+30E6 KANA LETTER YU Kana
#x04D6 U+30E8 KANA LETTER YO Kana
#x04D7 U+30E9 KANA LETTER RA Kana
#x04D8 U+30EA KANA LETTER RI Kana
#x04D9 U+30EB KANA LETTER RU Kana
#x04DA U+30EC KANA LETTER RE Kana
#x04DB U+30ED KANA LETTER RO Kana
#x04DC U+30EF KANA LETTER WA Kana
#x04DD U+30F3 KANA LETTER N Kana
#x04DE U+309B VOICED SOUND SYMBOL Kana
#x04DF U+309C SEMIVOICED SOUND SYMBOL Kana

#x05AC U+060C ARABIC COMMA Arabic
#x05BB U+061B ARABIC SEMICOLON Arabic
#x05BF U+061F ARABIC QUESTION MARK Arabic
#x05C1 U+0621 ARABIC LETTER HAMZA Arabic
#x05C2 U+0622 ARABIC LETTER ALEF WITH MADDA ABOVE Arabic
#x05C3 U+0623 ARABIC LETTER ALEF WITH HAMZA ABOVE Arabic
#x05C4 U+0624 ARABIC LETTER WAW WITH HAMZA ABOVE Arabic
#x05C5 U+0625 ARABIC LETTER ALEF WITH HAMZA BELOW Arabic
#x05C6 U+0626 ARABIC LETTER YEH WITH HAMZA ABOVE Arabic
#x05C7 U+0627 ARABIC LETTER ALEF Arabic
#x05C8 U+0628 ARABIC LETTER BEH Arabic
#x05C9 U+0629 ARABIC LETTER TEH MARBUTA Arabic
#x05CA U+062A ARABIC LETTER TEH Arabic
#x05CB U+062B ARABIC LETTER THEH Arabic
#x05CC U+062C ARABIC LETTER JEEM Arabic
#x05CD U+062D ARABIC LETTER HAH Arabic
#x05CE U+062E ARABIC LETTER KHAH Arabic
#x05CF U+062F ARABIC LETTER DAL Arabic
#x05D0 U+0630 ARABIC LETTER THAL Arabic
#x05D1 U+0631 ARABIC LETTER REH Arabic
#x05D2 U+0632 ARABIC LETTER ZAIN Arabic
#x05D3 U+0633 ARABIC LETTER SEEN Arabic
#x05D4 U+0634 ARABIC LETTER SHEEN Arabic
#x05D5 U+0635 ARABIC LETTER SAD Arabic
#x05D6 U+0636 ARABIC LETTER DAD Arabic
#x05D7 U+0637 ARABIC LETTER TAH Arabic
#x05D8 U+0638 ARABIC LETTER ZAH Arabic
#x05D9 U+0639 ARABIC LETTER AIN Arabic
#x05DA U+063A ARABIC LETTER GHAIN Arabic
#x05E0 U+0640 ARABIC TATWEEL Arabic
#x05E1 U+0641 ARABIC LETTER FEH Arabic
#x05E2 U+0642 ARABIC LETTER QAF Arabic
#x05E3 U+0643 ARABIC LETTER KAF Arabic
#x05E4 U+0644 ARABIC LETTER LAM Arabic
#x05E5 U+0645 ARABIC LETTER MEEM Arabic
#x05E6 U+0646 ARABIC LETTER NOON Arabic
#x05E7 U+0647 ARABIC LETTER HEH Arabic
#x05E8 U+0648 ARABIC LETTER WAW Arabic
#x05E9 U+0649 ARABIC LETTER ALEF MAKSURA Arabic
#x05EA U+064A ARABIC LETTER YEH Arabic
#x05EB U+064B ARABIC FATHATAN Arabic
#x05EC U+064C ARABIC DAMMATAN Arabic
#x05ED U+064D ARABIC KASRATAN Arabic
#x05EE U+064E ARABIC FATHA Arabic
#x05EF U+064F ARABIC DAMMA Arabic
#x05F0 U+0650 ARABIC KASRA Arabic
#x05F1 U+0651 ARABIC SHADDA Arabic
#x05F2 U+0652 ARABIC SUKUN Arabic

#x06A1 U+0452 CYRILLIC SMALL LETTER DJE Cyrillic
#x06A2 U+0453 CYRILLIC SMALL LETTER GJE Cyrillic
#x06A3 U+0451 CYRILLIC SMALL LETTER IO Cyrillic
#x06A4 U+0454 CYRILLIC SMALL LETTER UKRAINIAN IE Cyrillic
#x06A5 U+0455 CYRILLIC SMALL LETTER DZE Cyrillic
#x06A6 U+0456 CYRILLIC SMALL LETTER BYELORUSSIAN-UKRAINIAN I Cyrillic
#x06A7 U+0457 CYRILLIC SMALL LETTER YI Cyrillic
#x06A8 U+0458 CYRILLIC SMALL LETTER JE Cyrillic
#x06A9 U+0459 CYRILLIC SMALL LETTER LJE Cyrillic
#x06AA U+045A CYRILLIC SMALL LETTER NJE Cyrillic
#x06AB U+045B CYRILLIC SMALL LETTER TSHE Cyrillic
#x06AC U+045C CYRILLIC SMALL LETTER KJE Cyrillic
#x06AD U+0491 CYRILLIC SMALL LETTER GHE WITH UPTURN Cyrillic
#x06AE U+045E CYRILLIC SMALL LETTER SHORT U Cyrillic
#x06AF U+045F CYRILLIC SMALL LETTER DZHE Cyrillic
#x06B0 U+2116 NUMERO SIGN Cyrillic
#x06B1 U+0402 CYRILLIC CAPITAL LETTER DJE Cyrillic
#x06B2 U+0403 CYRILLIC CAPITAL LETTER GJE Cyrillic
#x06B3 U+0401 CYRILLIC CAPITAL LETTER IO Cyrillic
#x06B4 U+0404 CYRILLIC CAPITAL LETTER UKRAINIAN IE Cyrillic
#x06B5 U+0405 CYRILLIC CAPITAL LETTER DZE Cyrillic
#x06B6 U+0406 CYRILLIC CAPITAL LETTER BYELORUSSIAN-UKRAINIAN I Cyrillic
#x06B7 U+0407 CYRILLIC CAPITAL LETTER YI Cyrillic
#x06B8 U+0408 CYRILLIC CAPITAL LETTER JE Cyrillic
#x06B9 U+0409 CYRILLIC CAPITAL LETTER LJE Cyrillic
#x06BA U+040A CYRILLIC CAPITAL LETTER NJE Cyrillic
#x06BB U+040B CYRILLIC CAPITAL LETTER TSHE Cyrillic
#x06BC U+040C CYRILLIC CAPITAL LETTER KJE Cyrillic
#x06BD U+0490 CYRILLIC CAPITAL LETTER GHE WITH UPTURN Cyrillic
#x06BE U+040E CYRILLIC CAPITAL LETTER SHORT U Cyrillic
#x06BF U+040F CYRILLIC CAPITAL LETTER DZHE Cyrillic
#x06C0 U+044E CYRILLIC SMALL LETTER YU Cyrillic
#x06C1 U+0430 CYRILLIC SMALL LETTER A Cyrillic
#x06C2 U+0431 CYRILLIC SMALL LETTER BE Cyrillic
#x06C3 U+0446 CYRILLIC SMALL LETTER TSE Cyrillic
#x06C4 U+0434 CYRILLIC SMALL LETTER DE Cyrillic
#x06C5 U+0435 CYRILLIC SMALL LETTER IE Cyrillic
#x06C6 U+0444 CYRILLIC SMALL LETTER EF Cyrillic
#x06C7 U+0433 CYRILLIC SMALL LETTER GHE Cyrillic
#x06C8 U+0445 CYRILLIC SMALL LETTER HA Cyrillic
#x06C9 U+0438 CYRILLIC SMALL LETTER I Cyrillic
#x06CA U+0439 CYRILLIC SMALL LETTER SHORT I Cyrillic
#x06CB U+043A CYRILLIC SMALL LETTER KA Cyrillic
#x06CC U+043B CYRILLIC SMALL LETTER EL Cyrillic
#x06CD U+043C CYRILLIC SMALL LETTER EM Cyrillic
#x06CE U+043D CYRILLIC SMALL LETTER EN Cyrillic
#x06CF U+043E CYRILLIC SMALL LETTER O Cyrillic
#x06D0 U+043F CYRILLIC SMALL LETTER PE Cyrillic
#x06D1 U+044F CYRILLIC SMALL LETTER YA Cyrillic
#x06D2 U+0440 CYRILLIC SMALL LETTER ER Cyrillic
#x06D3 U+0441 CYRILLIC SMALL LETTER ES Cyrillic
#x06D4 U+0442 CYRILLIC SMALL LETTER TE Cyrillic
#x06D5 U+0443 CYRILLIC SMALL LETTER U Cyrillic
#x06D6 U+0436 CYRILLIC SMALL LETTER ZHE Cyrillic
#x06D7 U+0432 CYRILLIC SMALL LETTER VE Cyrillic
#x06D8 U+044C CYRILLIC SMALL LETTER SOFT SIGN Cyrillic
#x06D9 U+044B CYRILLIC SMALL LETTER YERU Cyrillic
#x06DA U+0437 CYRILLIC SMALL LETTER ZE Cyrillic
#x06DB U+0448 CYRILLIC SMALL LETTER SHA Cyrillic
#x06DC U+044D CYRILLIC SMALL LETTER E Cyrillic
#x06DD U+0449 CYRILLIC SMALL LETTER SHCHA Cyrillic
#x06DE U+0447 CYRILLIC SMALL LETTER CHE Cyrillic
#x06DF U+044A CYRILLIC SMALL LETTER HARD SIGN Cyrillic
#x06E0 U+042E CYRILLIC CAPITAL LETTER YU Cyrillic
#x06E1 U+0410 CYRILLIC CAPITAL LETTER A Cyrillic
#x06E2 U+0411 CYRILLIC CAPITAL LETTER BE Cyrillic
#x06E3 U+0426 CYRILLIC CAPITAL LETTER TSE Cyrillic
#x06E4 U+0414 CYRILLIC CAPITAL LETTER DE Cyrillic
#x06E5 U+0415 CYRILLIC CAPITAL LETTER IE Cyrillic
#x06E6 U+0424 CYRILLIC CAPITAL LETTER EF Cyrillic
#x06E7 U+0413 CYRILLIC CAPITAL LETTER GHE Cyrillic
#x06E8 U+0425 CYRILLIC CAPITAL LETTER HA Cyrillic
#x06E9 U+0418 CYRILLIC CAPITAL LETTER I Cyrillic
#x06EA U+0419 CYRILLIC CAPITAL LETTER SHORT I Cyrillic
#x06EB U+041A CYRILLIC CAPITAL LETTER KA Cyrillic
#x06EC U+041B CYRILLIC CAPITAL LETTER EL Cyrillic
#x06ED U+041C CYRILLIC CAPITAL LETTER EM Cyrillic
#x06EE U+041D CYRILLIC CAPITAL LETTER EN Cyrillic
#x06EF U+041E CYRILLIC CAPITAL LETTER O Cyrillic
#x06F0 U+041F CYRILLIC CAPITAL LETTER PE Cyrillic
#x06F1 U+042F CYRILLIC CAPITAL LETTER YA Cyrillic
#x06F2 U+0420 CYRILLIC CAPITAL LETTER ER Cyrillic
#x06F3 U+0421 CYRILLIC CAPITAL LETTER ES Cyrillic
#x06F4 U+0422 CYRILLIC CAPITAL LETTER TE Cyrillic
#x06F5 U+0423 CYRILLIC CAPITAL LETTER U Cyrillic
#x06F6 U+0416 CYRILLIC CAPITAL LETTER ZHE Cyrillic
#x06F7 U+0412 CYRILLIC CAPITAL LETTER VE Cyrillic
#x06F8 U+042C CYRILLIC CAPITAL LETTER SOFT SIGN Cyrillic
#x06F9 U+042B CYRILLIC CAPITAL LETTER YERU Cyrillic
#x06FA U+0417 CYRILLIC CAPITAL LETTER ZE Cyrillic
#x06FB U+0428 CYRILLIC CAPITAL LETTER SHA Cyrillic
#x06FC U+042D CYRILLIC CAPITAL LETTER E Cyrillic
#x06FD U+0429 CYRILLIC CAPITAL LETTER SHCHA Cyrillic
#x06FE U+0427 CYRILLIC CAPITAL LETTER CHE Cyrillic
#x06FF U+042A CYRILLIC CAPITAL LETTER HARD SIGN Cyrillic

#x07A1 U+0386 GREEK CAPITAL LETTER ALPHA WITH TONOS Greek
#x07A2 U+0388 GREEK CAPITAL LETTER EPSILON WITH TONOS Greek
#x07A3 U+0389 GREEK CAPITAL LETTER ETA WITH TONOS Greek
#x07A4 U+038A GREEK CAPITAL LETTER IOTA WITH TONOS Greek
#x07A5 U+03AA GREEK CAPITAL LETTER IOTA WITH DIALYTIKA Greek
#x07A7 U+038C GREEK CAPITAL LETTER OMICRON WITH TONOS Greek
#x07A8 U+038E GREEK CAPITAL LETTER UPSILON WITH TONOS Greek
#x07A9 U+03AB GREEK CAPITAL LETTER UPSILON WITH DIALYTIKA Greek
#x07AB U+038F GREEK CAPITAL LETTER OMEGA WITH TONOS Greek
#x07AE U+0385 GREEK DIALYTIKA TONOS Greek
#x07AF U+2015 HORIZONTAL BAR Greek
#x07B1 U+03AC GREEK SMALL LETTER ALPHA WITH TONOS Greek
#x07B2 U+03AD GREEK SMALL LETTER EPSILON WITH TONOS Greek
#x07B3 U+03AE GREEK SMALL LETTER ETA WITH TONOS Greek
#x07B4 U+03AF GREEK SMALL LETTER IOTA WITH TONOS Greek
#x07B5 U+03CA GREEK SMALL LETTER IOTA WITH DIALYTIKA Greek
#x07B6 U+0390 GREEK SMALL LETTER IOTA WITH DIALYTIKA AND TONOS Greek
#x07B7 U+03CC GREEK SMALL LETTER OMICRON WITH TONOS Greek
#x07B8 U+03CD GREEK SMALL LETTER UPSILON WITH TONOS Greek
#x07B9 U+03CB GREEK SMALL LETTER UPSILON WITH DIALYTIKA Greek
#x07BA U+03B0 GREEK SMALL LETTER UPSILON WITH DIALYTIKA AND TONOS Greek
#x07BB U+03CE GREEK SMALL LETTER OMEGA WITH TONOS Greek
#x07C1 U+0391 GREEK CAPITAL LETTER ALPHA Greek
#x07C2 U+0392 GREEK CAPITAL LETTER BETA Greek
#x07C3 U+0393 GREEK CAPITAL LETTER GAMMA Greek
#x07C4 U+0394 GREEK CAPITAL LETTER DELTA Greek
#x07C5 U+0395 GREEK CAPITAL LETTER EPSILON Greek
#x07C6 U+0396 GREEK CAPITAL LETTER ZETA Greek
#x07C7 U+0397 GREEK CAPITAL LETTER ETA Greek
#x07C8 U+0398 GREEK CAPITAL LETTER THETA Greek
#x07C9 U+0399 GREEK CAPITAL LETTER IOTA Greek
#x07CA U+039A GREEK CAPITAL LETTER KAPPA Greek
#x07CB U+039B GREEK CAPITAL LETTER LAMDA Greek
#x07CC U+039C GREEK CAPITAL LETTER MU Greek
#x07CD U+039D GREEK CAPITAL LETTER NU Greek
#x07CE U+039E GREEK CAPITAL LETTER XI Greek
#x07CF U+039F GREEK CAPITAL LETTER OMICRON Greek
#x07D0 U+03A0 GREEK CAPITAL LETTER PI Greek
#x07D1 U+03A1 GREEK CAPITAL LETTER RHO Greek
#x07D2 U+03A3 GREEK CAPITAL LETTER SIGMA Greek
#x07D4 U+03A4 GREEK CAPITAL LETTER TAU Greek
#x07D5 U+03A5 GREEK CAPITAL LETTER UPSILON Greek
#x07D6 U+03A6 GREEK CAPITAL LETTER PHI Greek
#x07D7 U+03A7 GREEK CAPITAL LETTER CHI Greek
#x07D8 U+03A8 GREEK CAPITAL LETTER PSI Greek
#x07D9 U+03A9 GREEK CAPITAL LETTER OMEGA Greek
#x07E1 U+03B1 GREEK SMALL LETTER ALPHA Greek
#x07E2 U+03B2 GREEK SMALL LETTER BETA Greek
#x07E3 U+03B3 GREEK SMALL LETTER GAMMA Greek
#x07E4 U+03B4 GREEK SMALL LETTER DELTA Greek
#x07E5 U+03B5 GREEK SMALL LETTER EPSILON Greek
#x07E6 U+03B6 GREEK SMALL LETTER ZETA Greek
#x07E7 U+03B7 GREEK SMALL LETTER ETA Greek
#x07E8 U+03B8 GREEK SMALL LETTER THETA Greek
#x07E9 U+03B9 GREEK SMALL LETTER IOTA Greek
#x07EA U+03BA GREEK SMALL LETTER KAPPA Greek
#x07EB U+03BB GREEK SMALL LETTER LAMDA Greek
#x07EC U+03BC GREEK SMALL LETTER MU Greek
#x07ED U+03BD GREEK SMALL LETTER NU Greek
#x07EE U+03BE GREEK SMALL LETTER XI Greek
#x07EF U+03BF GREEK SMALL LETTER OMICRON Greek
#x07F0 U+03C0 GREEK SMALL LETTER PI Greek
#x07F1 U+03C1 GREEK SMALL LETTER RHO Greek
#x07F2 U+03C3 GREEK SMALL LETTER SIGMA Greek
#x07F3 U+03C2 GREEK SMALL LETTER FINAL SIGMA Greek
#x07F4 U+03C4 GREEK SMALL LETTER TAU Greek
#x07F5 U+03C5 GREEK SMALL LETTER UPSILON Greek
#x07F6 U+03C6 GREEK SMALL LETTER PHI Greek
#x07F7 U+03C7 GREEK SMALL LETTER CHI Greek
#x07F8 U+03C8 GREEK SMALL LETTER PSI Greek
#x07F9 U+03C9 GREEK SMALL LETTER OMEGA Greek

#x08A1 U+23B7 LEFT RADICAL Technical
#x08A2 − TOP LEFT RADICAL Technical
#x08A3 − HORIZONTAL CONNECTOR Technical
#x08A4 U+2320 TOP INTEGRAL Technical
#x08A5 U+2321 BOTTOM INTEGRAL Technical
#x08A6 − VERTICAL CONNECTOR Technical
#x08A7 U+23A1 TOP LEFT SQUARE BRACKET Technical
#x08A8 U+23A3 BOTTOM LEFT SQUARE BRACKET Technical
#x08A9 U+23A4 TOP RIGHT SQUARE BRACKET Technical
#x08AA U+23A6 BOTTOM RIGHT SQUARE BRACKET Technical
#x08AB U+239B TOP LEFT PARENTHESIS Technical
#x08AC U+239D BOTTOM LEFT PARENTHESIS Technical
#x08AD U+239E TOP RIGHT PARENTHESIS Technical
#x08AE U+23A0 BOTTOM RIGHT PARENTHESIS Technical
#x08AF U+23A8 LEFT MIDDLE CURLY BRACE Technical
#x08B0 U+23AC RIGHT MIDDLE CURLY BRACE Technical
#x08B1 − TOP LEFT SUMMATION Technical
#x08B2 − BOTTOM LEFT SUMMATION Technical
#x08B3 − TOP VERTICAL SUMMATION CONNECTOR Technical
#x08B4 − BOTTOM VERTICAL SUMMATION CONNECTOR Technical
#x08B5 − TOP RIGHT SUMMATION Technical
#x08B6 − BOTTOM RIGHT SUMMATION Technical
#x08B7 − RIGHT MIDDLE SUMMATION Technical
#x08BC U+2264 LESS THAN OR EQUAL SIGN Technical
#x08BD U+2260 NOT EQUAL SIGN Technical
#x08BE U+2265 GREATER THAN OR EQUAL SIGN Technical
#x08BF U+222B INTEGRAL Technical
#x08C0 U+2234 THEREFORE Technical
#x08C1 U+221D VARIATION, PROPORTIONAL TO Technical
#x08C2 U+221E INFINITY Technical
#x08C5 U+2207 NABLA, DEL Technical
#x08C8 U+223C IS APPROXIMATE TO Technical
#x08C9 U+2243 SIMILAR OR EQUAL TO Technical
#x08CD U+21D4 IF AND ONLY IF Technical
#x08CE U+21D2 IMPLIES Technical
#x08CF U+2261 IDENTICAL TO Technical
#x08D6 U+221A RADICAL Technical
#x08DA U+2282 IS INCLUDED IN Technical
#x08DB U+2283 INCLUDES Technical
#x08DC U+2229 INTERSECTION Technical
#x08DD U+222A UNION Technical
#x08DE U+2227 LOGICAL AND Technical
#x08DF U+2228 LOGICAL OR Technical
#x08EF U+2202 PARTIAL DERIVATIVE Technical
#x08F6 U+0192 FUNCTION Technical
#x08FB U+2190 LEFT ARROW Technical
#x08FC U+2191 UPWARD ARROW Technical
#x08FD U+2192 RIGHT ARROW Technical
#x08FE U+2193 DOWNWARD ARROW Technical

#x09DF − BLANK Special
#x09E0 U+25C6 SOLID DIAMOND Special
#x09E1 U+2592 CHECKERBOARD Special
#x09E2 U+2409 ‘‘HT’’ Special
#x09E3 U+240C ‘‘FF’’ Special
#x09E4 U+240D ‘‘CR’’ Special
#x09E5 U+240A ‘‘LF’’ Special
#x09E8 U+2424 ‘‘NL’’ Special
#x09E9 U+240B ‘‘VT’’ Special
#x09EA U+2518 LOWER-RIGHT CORNER Special
#x09EB U+2510 UPPER-RIGHT CORNER Special
#x09EC U+250C UPPER-LEFT CORNER Special
#x09ED U+2514 LOWER-LEFT CORNER Special
#x09EE U+253C CROSSING-LINES Special
#x09EF U+23BA HORIZONTAL LINE, SCAN 1 Special
#x09F0 U+23BB HORIZONTAL LINE, SCAN 3 Special
#x09F1 U+2500 HORIZONTAL LINE, SCAN 5 Special
#x09F2 U+23BC HORIZONTAL LINE, SCAN 7 Special
#x09F3 U+23BD HORIZONTAL LINE, SCAN 9 Special
#x09F4 U+251C LEFT ‘‘T’’ Special
#x09F5 U+2524 RIGHT ‘‘T’’ Special
#x09F6 U+2534 BOTTOM ‘‘T’’ Special
#x09F7 U+252C TOP ‘‘T’’ Special
#x09F8 U+2502 VERTICAL BAR Special

#x0AA1 U+2003 EM SPACE Publish
#x0AA2 U+2002 EN SPACE Publish
#x0AA3 U+2004 3/EM SPACE Publish
#x0AA4 U+2005 4/EM SPACE Publish
#x0AA5 U+2007 DIGIT SPACE Publish
#x0AA6 U+2008 PUNCTUATION SPACE Publish
#x0AA7 U+2009 THIN SPACE Publish
#x0AA8 U+200A HAIR SPACE Publish
#x0AA9 U+2014 EM DASH Publish
#x0AAA U+2013 EN DASH Publish
#x0AAC − SIGNIFICANT BLANK SYMBOL Publish
#x0AAE U+2026 ELLIPSIS Publish
#x0AAF U+2025 DOUBLE BASELINE DOT Publish
#x0AB0 U+2153 VULGAR FRACTION ONE THIRD Publish
#x0AB1 U+2154 VULGAR FRACTION TWO THIRDS Publish
#x0AB2 U+2155 VULGAR FRACTION ONE FIFTH Publish
#x0AB3 U+2156 VULGAR FRACTION TWO FIFTHS Publish
#x0AB4 U+2157 VULGAR FRACTION THREE FIFTHS Publish
#x0AB5 U+2158 VULGAR FRACTION FOUR FIFTHS Publish
#x0AB6 U+2159 VULGAR FRACTION ONE SIXTH Publish
#x0AB7 U+215A VULGAR FRACTION FIVE SIXTHS Publish
#x0AB8 U+2105 CARE OF Publish
#x0ABB U+2012 FIGURE DASH Publish
#x0ABC − LEFT ANGLE BRACKET Publish
#x0ABD − DECIMAL POINT Publish
#x0ABE − RIGHT ANGLE BRACKET Publish
#x0ABF − MARKER Publish
#x0AC3 U+215B VULGAR FRACTION ONE EIGHTH Publish
#x0AC4 U+215C VULGAR FRACTION THREE EIGHTHS Publish
#x0AC5 U+215D VULGAR FRACTION FIVE EIGHTHS Publish
#x0AC6 U+215E VULGAR FRACTION SEVEN EIGHTHS Publish
#x0AC9 U+2122 TRADEMARK SIGN Publish
#x0ACA − SIGNATURE MARK Publish
#x0ACB − TRADEMARK SIGN IN CIRCLE Publish
#x0ACC − LEFT OPEN TRIANGLE Publish
#x0ACD − RIGHT OPEN TRIANGLE Publish
#x0ACE − EM OPEN CIRCLE Publish
#x0ACF − EM OPEN RECTANGLE Publish
#x0AD0 U+2018 LEFT SINGLE QUOTATION MARK Publish
#x0AD1 U+2019 RIGHT SINGLE QUOTATION MARK Publish
#x0AD2 U+201C LEFT DOUBLE QUOTATION MARK Publish
#x0AD3 U+201D RIGHT DOUBLE QUOTATION MARK Publish
#x0AD4 U+211E PRESCRIPTION, TAKE, RECIPE Publish
#x0AD6 U+2032 MINUTES Publish
#x0AD7 U+2033 SECONDS Publish
#x0AD9 U+271D LATIN CROSS Publish
#x0ADA − HEXAGRAM Publish
#x0ADB − FILLED RECTANGLE BULLET Publish
#x0ADC − FILLED LEFT TRIANGLE BULLET Publish
#x0ADD − FILLED RIGHT TRIANGLE BULLET Publish
#x0ADE − EM FILLED CIRCLE Publish
#x0ADF − EM FILLED RECTANGLE Publish
#x0AE0 − EN OPEN CIRCLE BULLET Publish
#x0AE1 − EN OPEN SQUARE BULLET Publish
#x0AE2 − OPEN RECTANGULAR BULLET Publish
#x0AE3 − OPEN TRIANGULAR BULLET UP Publish
#x0AE4 − OPEN TRIANGULAR BULLET DOWN Publish
#x0AE5 − OPEN STAR Publish
#x0AE6 − EN FILLED CIRCLE BULLET Publish
#x0AE7 − EN FILLED SQUARE BULLET Publish
#x0AE8 − FILLED TRIANGULAR BULLET UP Publish
#x0AE9 − FILLED TRIANGULAR BULLET DOWN Publish
#x0AEA − LEFT POINTER Publish
#x0AEB − RIGHT POINTER Publish
#x0AEC U+2663 CLUB Publish
#x0AED U+2666 DIAMOND Publish
#x0AEE U+2665 HEART Publish
#x0AF0 U+2720 MALTESE CROSS Publish
#x0AF1 U+2020 DAGGER Publish
#x0AF2 U+2021 DOUBLE DAGGER Publish
#x0AF3 U+2713 CHECK MARK, TICK Publish
#x0AF4 U+2717 BALLOT CROSS Publish
#x0AF5 U+266F MUSICAL SHARP Publish
#x0AF6 U+266D MUSICAL FLAT Publish
#x0AF7 U+2642 MALE SYMBOL Publish
#x0AF8 U+2640 FEMALE SYMBOL Publish
#x0AF9 U+260E TELEPHONE SYMBOL Publish
#x0AFA U+2315 TELEPHONE RECORDER SYMBOL Publish
#x0AFB U+2117 PHONOGRAPH COPYRIGHT SIGN Publish
#x0AFC U+2038 CARET Publish
#x0AFD U+201A SINGLE LOW QUOTATION MARK Publish
#x0AFE U+201E DOUBLE LOW QUOTATION MARK Publish
#x0AFF − CURSOR Publish

#x0BA3 − LEFT CARET APL
#x0BA6 − RIGHT CARET APL
#x0BA8 − DOWN CARET APL
#x0BA9 − UP CARET APL
#x0BC0 − OVERBAR APL
#x0BC2 U+22A5 DOWN TACK APL
#x0BC3 − UP SHOE (CAP) APL
#x0BC4 U+230A DOWN STILE APL
#x0BC6 − UNDERBAR APL
#x0BCA U+2218 JOT APL
#x0BCC U+2395 QUAD APL
#x0BCE U+22A4 UP TACK APL
#x0BCF U+25CB CIRCLE APL
#x0BD3 U+2308 UP STILE APL
#x0BD6 − DOWN SHOE (CUP) APL
#x0BD8 − RIGHT SHOE APL
#x0BDA − LEFT SHOE APL
#x0BDC U+22A2 LEFT TACK APL
#x0BFC U+22A3 RIGHT TACK APL

#x0CDF U+2017 DOUBLE LOW LINE Hebrew
#x0CE0 U+05D0 HEBREW LETTER ALEF Hebrew
#x0CE1 U+05D1 HEBREW LETTER BET Hebrew
#x0CE2 U+05D2 HEBREW LETTER GIMEL Hebrew
#x0CE3 U+05D3 HEBREW LETTER DALET Hebrew
#x0CE4 U+05D4 HEBREW LETTER HE Hebrew
#x0CE5 U+05D5 HEBREW LETTER VAV Hebrew
#x0CE6 U+05D6 HEBREW LETTER ZAYIN Hebrew
#x0CE7 U+05D7 HEBREW LETTER HET Hebrew
#x0CE8 U+05D8 HEBREW LETTER TET Hebrew
#x0CE9 U+05D9 HEBREW LETTER YOD Hebrew
#x0CEA U+05DA HEBREW LETTER FINAL KAF Hebrew
#x0CEB U+05DB HEBREW LETTER KAF Hebrew
#x0CEC U+05DC HEBREW LETTER LAMED Hebrew
#x0CED U+05DD HEBREW LETTER FINAL MEM Hebrew
#x0CEE U+05DE HEBREW LETTER MEM Hebrew
#x0CEF U+05DF HEBREW LETTER FINAL NUN Hebrew
#x0CF0 U+05E0 HEBREW LETTER NUN Hebrew
#x0CF1 U+05E1 HEBREW LETTER SAMEKH Hebrew
#x0CF2 U+05E2 HEBREW LETTER AYIN Hebrew
#x0CF3 U+05E3 HEBREW LETTER FINAL PE Hebrew
#x0CF4 U+05E4 HEBREW LETTER PE Hebrew
#x0CF5 U+05E5 HEBREW LETTER FINAL TSADI Hebrew
#x0CF6 U+05E6 HEBREW LETTER TSADI Hebrew
#x0CF7 U+05E7 HEBREW LETTER QOF Hebrew
#x0CF8 U+05E8 HEBREW LETTER RESH Hebrew
#x0CF9 U+05E9 HEBREW LETTER SHIN Hebrew
#x0CFA U+05EA HEBREW LETTER TAV Hebrew

#x0DA1 U+0E01 THAI CHARACTER KO KAI Thai
#x0DA2 U+0E02 THAI CHARACTER KHO KHAI Thai
#x0DA3 U+0E03 THAI CHARACTER KHO KHUAT Thai
#x0DA4 U+0E04 THAI CHARACTER KHO KHWAI Thai
#x0DA5 U+0E05 THAI CHARACTER KHO KHON Thai
#x0DA6 U+0E06 THAI CHARACTER KHO RAKHANG Thai
#x0DA7 U+0E07 THAI CHARACTER NGO NGU Thai
#x0DA8 U+0E08 THAI CHARACTER CHO CHAN Thai
#x0DA9 U+0E09 THAI CHARACTER CHO CHING Thai
#x0DAA U+0E0A THAI CHARACTER CHO CHANG Thai
#x0DAB U+0E0B THAI CHARACTER SO SO Thai
#x0DAC U+0E0C THAI CHARACTER CHO CHOE Thai
#x0DAD U+0E0D THAI CHARACTER YO YING Thai
#x0DAE U+0E0E THAI CHARACTER DO CHADA Thai
#x0DAF U+0E0F THAI CHARACTER TO PATAK Thai
#x0DB0 U+0E10 THAI CHARACTER THO THAN Thai
#x0DB1 U+0E11 THAI CHARACTER THO NANGMONTHO Thai
#x0DB2 U+0E12 THAI CHARACTER THO PHUTHAO Thai
#x0DB3 U+0E13 THAI CHARACTER NO NEN Thai
#x0DB4 U+0E14 THAI CHARACTER DO DEK Thai
#x0DB5 U+0E15 THAI CHARACTER TO TAO Thai
#x0DB6 U+0E16 THAI CHARACTER THO THUNG Thai
#x0DB7 U+0E17 THAI CHARACTER THO THAHAN Thai
#x0DB8 U+0E18 THAI CHARACTER THO THONG Thai
#x0DB9 U+0E19 THAI CHARACTER NO NU Thai
#x0DBA U+0E1A THAI CHARACTER BO BAIMAI Thai
#x0DBB U+0E1B THAI CHARACTER PO PLA Thai
#x0DBC U+0E1C THAI CHARACTER PHO PHUNG Thai
#x0DBD U+0E1D THAI CHARACTER FO FA Thai
#x0DBE U+0E1E THAI CHARACTER PHO PHAN Thai
#x0DBF U+0E1F THAI CHARACTER FO FAN Thai
#x0DC0 U+0E20 THAI CHARACTER PHO SAMPHAO Thai
#x0DC1 U+0E21 THAI CHARACTER MO MA Thai
#x0DC2 U+0E22 THAI CHARACTER YO YAK Thai
#x0DC3 U+0E23 THAI CHARACTER RO RUA Thai
#x0DC4 U+0E24 THAI CHARACTER RU Thai
#x0DC5 U+0E25 THAI CHARACTER LO LING Thai
#x0DC6 U+0E26 THAI CHARACTER LU Thai
#x0DC7 U+0E27 THAI CHARACTER WO WAEN Thai
#x0DC8 U+0E28 THAI CHARACTER SO SALA Thai
#x0DC9 U+0E29 THAI CHARACTER SO RUSI Thai
#x0DCA U+0E2A THAI CHARACTER SO SUA Thai
#x0DCB U+0E2B THAI CHARACTER HO HIP Thai
#x0DCC U+0E2C THAI CHARACTER LO CHULA Thai
#x0DCD U+0E2D THAI CHARACTER O ANG Thai
#x0DCE U+0E2E THAI CHARACTER HO NOKHUK Thai
#x0DCF U+0E2F THAI CHARACTER PAIYANNOI Thai
#x0DD0 U+0E30 THAI CHARACTER SARA A Thai
#x0DD1 U+0E31 THAI CHARACTER MAI HAN-AKAT Thai
#x0DD2 U+0E32 THAI CHARACTER SARA AA Thai
#x0DD3 U+0E33 THAI CHARACTER SARA AM Thai
#x0DD4 U+0E34 THAI CHARACTER SARA I Thai
#x0DD5 U+0E35 THAI CHARACTER SARA II Thai
#x0DD6 U+0E36 THAI CHARACTER SARA UE Thai
#x0DD7 U+0E37 THAI CHARACTER SARA UEE Thai
#x0DD8 U+0E38 THAI CHARACTER SARA U Thai
#x0DD9 U+0E39 THAI CHARACTER SARA UU Thai
#x0DDA U+0E3A THAI CHARACTER PHINTHU Thai
#x0DDF U+0E3F THAI CURRENCY SYMBOL BAHT Thai
#x0DE0 U+0E40 THAI CHARACTER SARA E Thai
#x0DE1 U+0E41 THAI CHARACTER SARA AE Thai
#x0DE2 U+0E42 THAI CHARACTER SARA O Thai
#x0DE3 U+0E43 THAI CHARACTER SARA AI MAIMUAN Thai
#x0DE4 U+0E44 THAI CHARACTER SARA AI MAIMALAI Thai
#x0DE5 U+0E45 THAI CHARACTER LAKKHANGYAO Thai
#x0DE6 U+0E46 THAI CHARACTER MAIYAMOK Thai
#x0DE7 U+0E47 THAI CHARACTER MAITAIKHU Thai
#x0DE8 U+0E48 THAI CHARACTER MAI EK Thai
#x0DE9 U+0E49 THAI CHARACTER MAI THO Thai
#x0DEA U+0E4A THAI CHARACTER MAI TRI Thai
#x0DEB U+0E4B THAI CHARACTER MAI CHATTAWA Thai
#x0DEC U+0E4C THAI CHARACTER THANTHAKHAT Thai
#x0DED U+0E4D THAI CHARACTER NIKHAHIT Thai
#x0DF0 U+0E50 THAI DIGIT ZERO Thai
#x0DF1 U+0E51 THAI DIGIT ONE Thai
#x0DF2 U+0E52 THAI DIGIT TWO Thai
#x0DF3 U+0E53 THAI DIGIT THREE Thai
#x0DF4 U+0E54 THAI DIGIT FOUR Thai
#x0DF5 U+0E55 THAI DIGIT FIVE Thai
#x0DF6 U+0E56 THAI DIGIT SIX Thai
#x0DF7 U+0E57 THAI DIGIT SEVEN Thai
#x0DF8 U+0E58 THAI DIGIT EIGHT Thai
#x0DF9 U+0E59 THAI DIGIT NINE Thai

#x0EA1 − HANGUL KIYEOG Korean
#x0EA2 − HANGUL SSANG KIYEOG Korean
#x0EA3 − HANGUL KIYEOG SIOS Korean
#x0EA4 − HANGUL NIEUN Korean
#x0EA5 − HANGUL NIEUN JIEUJ Korean
#x0EA6 − HANGUL NIEUN HIEUH Korean
#x0EA7 − HANGUL DIKEUD Korean
#x0EA8 − HANGUL SSANG DIKEUD Korean
#x0EA9 − HANGUL RIEUL Korean
#x0EAA − HANGUL RIEUL KIYEOG Korean
#x0EAB − HANGUL RIEUL MIEUM Korean
#x0EAC − HANGUL RIEUL PIEUB Korean
#x0EAD − HANGUL RIEUL SIOS Korean
#x0EAE − HANGUL RIEUL TIEUT Korean
#x0EAF − HANGUL RIEUL PHIEUF Korean
#x0EB0 − HANGUL RIEUL HIEUH Korean
#x0EB1 − HANGUL MIEUM Korean
#x0EB2 − HANGUL PIEUB Korean
#x0EB3 − HANGUL SSANG PIEUB Korean
#x0EB4 − HANGUL PIEUB SIOS Korean
#x0EB5 − HANGUL SIOS Korean
#x0EB6 − HANGUL SSANG SIOS Korean
#x0EB7 − HANGUL IEUNG Korean
#x0EB8 − HANGUL JIEUJ Korean
#x0EB9 − HANGUL SSANG JIEUJ Korean
#x0EBA − HANGUL CIEUC Korean
#x0EBB − HANGUL KHIEUQ Korean
#x0EBC − HANGUL TIEUT Korean
#x0EBD − HANGUL PHIEUF Korean
#x0EBE − HANGUL HIEUH Korean
#x0EBF − HANGUL A Korean
#x0EC0 − HANGUL AE Korean
#x0EC1 − HANGUL YA Korean
#x0EC2 − HANGUL YAE Korean
#x0EC3 − HANGUL EO Korean
#x0EC4 − HANGUL E Korean
#x0EC5 − HANGUL YEO Korean
#x0EC6 − HANGUL YE Korean
#x0EC7 − HANGUL O Korean
#x0EC8 − HANGUL WA Korean
#x0EC9 − HANGUL WAE Korean
#x0ECA − HANGUL OE Korean
#x0ECB − HANGUL YO Korean
#x0ECC − HANGUL U Korean
#x0ECD − HANGUL WEO Korean
#x0ECE − HANGUL WE Korean
#x0ECF − HANGUL WI Korean
#x0ED0 − HANGUL YU Korean
#x0ED1 − HANGUL EU Korean
#x0ED2 − HANGUL YI Korean
#x0ED3 − HANGUL I Korean
#x0ED4 − HANGUL JONG SEONG KIYEOG Korean
#x0ED5 − HANGUL JONG SEONG SSANG KIYEOG Korean
#x0ED6 − HANGUL JONG SEONG KIYEOG SIOS Korean
#x0ED7 − HANGUL JONG SEONG NIEUN Korean
#x0ED8 − HANGUL JONG SEONG NIEUN JIEUJ Korean
#x0ED9 − HANGUL JONG SEONG NIEUN HIEUH Korean
#x0EDA − HANGUL JONG SEONG DIKEUD Korean
#x0EDB − HANGUL JONG SEONG RIEUL Korean
#x0EDC − HANGUL JONG SEONG RIEUL KIYEOG Korean
#x0EDD − HANGUL JONG SEONG RIEUL MIEUM Korean
#x0EDE − HANGUL JONG SEONG RIEUL PIEUB Korean
#x0EDF − HANGUL JONG SEONG RIEUL SIOS Korean
#x0EE0 − HANGUL JONG SEONG RIEUL TIEUT Korean
#x0EE1 − HANGUL JONG SEONG RIEUL PHIEUF Korean
#x0EE2 − HANGUL JONG SEONG RIEUL HIEUH Korean
#x0EE3 − HANGUL JONG SEONG MIEUM Korean
#x0EE4 − HANGUL JONG SEONG PIEUB Korean
#x0EE5 − HANGUL JONG SEONG PIEUB SIOS Korean
#x0EE6 − HANGUL JONG SEONG SIOS Korean
#x0EE7 − HANGUL JONG SEONG SSANG SIOS Korean
#x0EE8 − HANGUL JONG SEONG IEUNG Korean
#x0EE9 − HANGUL JONG SEONG JIEUJ Korean
#x0EEA − HANGUL JONG SEONG CIEUC Korean
#x0EEB − HANGUL JONG SEONG KHIEUQ Korean
#x0EEC − HANGUL JONG SEONG TIEUT Korean
#x0EED − HANGUL JONG SEONG PHIEUF Korean
#x0EEE − HANGUL JONG SEONG HIEUH Korean
#x0EEF − HANGUL RIEUL YEORIN HIEUH Korean
#x0EF0 − HANGUL SUNKYEONGEUM MIEUM Korean
#x0EF1 − HANGUL SUNKYEONGEUM PIEUB Korean
#x0EF2 − HANGUL PAN SIOS Korean
#x0EF3 − HANGUL KKOGJI DALRIN IEUNG Korean
#x0EF4 − HANGUL SUNKYEONGEUM PHIEUF Korean
#x0EF5 − HANGUL YEORIN HIEUH Korean
#x0EF6 − HANGUL ARAE A Korean
#x0EF7 − HANGUL ARAE AE Korean
#x0EF8 − HANGUL JONG SEONG PAN SIOS Korean
#x0EF9 − HANGUL JONG SEONG KKOGJI DALRIN IEUNG Korean
#x0EFA − HANGUL JONG SEONG YEORIN HIEUH Korean
#x0EFF − KOREAN WON Korean

#x13BC U+0152 LATIN CAPITAL LIGATURE OE Latin-9
#x13BD U+0153 LATIN SMALL LIGATURE OE Latin-9
#x13BE U+0178 LATIN CAPITAL LETTER Y WITH DIAERESIS Latin-9

#x20A0 − CURRENCY ECU SIGN Currency
#x20A1 − CURRENCY COLON SIGN Currency
#x20A2 − CURRENCY CRUZEIRO SIGN Currency
#x20A3 − CURRENCY FRENCH FRANC SIGN Currency
#x20A4 − CURRENCY LIRA SIGN Currency
#x20A5 − CURRENCY MILL SIGN Currency
#x20A6 − CURRENCY NAIRA SIGN Currency
#x20A7 − CURRENCY PESETA SIGN Currency
#x20A8 − CURRENCY RUPEE SIGN Currency
#x20A9 − CURRENCY WON SIGN Currency
#x20AA − CURRENCY NEW SHEQEL SIGN Currency
#x20AB − CURRENCY DONG SIGN Currency
#x20AC U+20AC CURRENCY EURO SIGN Currency

2

X Protocol X11, Release 6.8

Appendix B

Protocol Encoding

Syntactic Conventions

All numbers are in decimal, unless prefixed with #x, in which case they are in hexadecimal (base 16).

The general syntax used to describe requests, replies, errors, events, and compound types is:

NameofThing
encode-form
...
encode-form

Each encode-form describes a single component.

For components described in the protocol as:

name: TYPE

the encode-form is:

N TYPE name

N is the number of bytes occupied in the data stream, and TYPE is the interpretation of those bytes. For example,

depth: CARD8

becomes:

1 CARD8 depth

For components with a static numeric value the encode-form is:

N value name

The value is always interpreted as an N-byte unsigned integer. For example, the first two bytes of a Window error are always zero (indicating an error in general) and three (indicating the Window error in particular):

1 0 Error

For components described in the protocol as:

name: {Name1,..., NameI}

the encode-form is:

The value is always interpreted as an N-byte unsigned integer. Note that the size of N is sometimes larger than that strictly required to encode the values. For example:

class: {InputOutput, InputOnly, CopyFromParent}

becomes:

For components described in the protocol as:

NAME: TYPE or Alternative1...or AlternativeI

the encode-form is:

The alternative values are guaranteed not to conflict with the encoding of TYPE. For example:

destination: WINDOW or PointerWindow or InputFocus

becomes:

For components described in the protocol as:

value-mask: BITMASK

the encode-form is:

The individual bits in the mask are specified and named, and N is 2 or 4. The most-significant bit in a BITMASK is reserved for use in defining chained (multiword) bitmasks, as extensions augment existing core requests. The precise interpretation of this bit is not yet defined here, although a probable mechanism is that a 1-bit indicates that another N bytes of bitmask follows, with bits within the overall mask still interpreted from least-significant to most-significant with an N-byte unit, with N-byte units interpreted in stream order, and with the overall mask being byte-swapped in individual N-byte units.

For LISTofVALUE encodings, the request is followed by a section of the form:

VALUEs
encode-form
...
encode-form

listing an encode-form for each VALUE. The NAME in each encode-form keys to the corresponding BITMASK bit. The encoding of a VALUE always occupies four bytes, but the number of bytes specified in the encoding-form indicates how many of the least-significant bytes are actually used; the remaining bytes are unused and their values do not matter.

In various cases, the number of bytes occupied by a component will be specified by a lowercase single-letter variable name instead of a specific numeric value, and often some other component will have its value specified as a simple numeric expression involving these variables. Components specified with such expressions are always interpreted as unsigned integers. The scope of such variables is always just the enclosing request, reply, error, event, or compound type structure. For example:

2 3+n request length

For unused bytes (the values of the bytes are undefined and do no matter), the encode-form is:

If the number of unused bytes is variable, the encode-form typically is:

where E is some expression, and pad(E) is the number of bytes needed to round E up to a multiple of four.

pad(E) = (4 - (E mod 4)) mod 4

Common Types

LISTofFOO

In this document the LISTof notation strictly means some number of repetitions of the FOO encoding; the actual length of the list is encoded elsewhere.

SETofFOO

A set is always represented by a bitmask, with a 1-bit indicating presence in the set.

BITMASK: CARD32

WINDOW: CARD32

PIXMAP: CARD32

CURSOR: CARD32

FONT: CARD32

GCONTEXT: CARD32

COLORMAP: CARD32

DRAWABLE: CARD32

FONTABLE: CARD32

ATOM: CARD32

VISUALID: CARD32

BYTE: 8-bit value

INT8: 8-bit signed integer

INT16: 16-bit signed integer

INT32: 32-bit signed integer

CARD8: 8-bit unsigned integer

CARD16: 16-bit unsigned integer

CARD32: 32-bit unsigned integer

TIMESTAMP: CARD32

BITGRAVITY

WINGRAVITY

BOOL

SETofEVENT

SETofPOINTEREVENT

SETofDEVICEEVENT

KEYSYM: CARD32

KEYCODE: CARD8

BUTTON: CARD8

SETofKEYBUTMASK

SETofKEYMASK

STRING8: LISTofCARD8

STRING16: LISTofCHAR2B

CHAR2B

POINT

RECTANGLE

ARC

HOST

STR

Errors

Request

Value

Window

Pixmap

Atom

Cursor

Font

Match

Drawable

Access

Alloc

Colormap

GContext

IDChoice