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This chapter describes how the runnable XEmacs executable is dumped with the preloaded Lisp libraries in it, how storage is allocated, and some internal aspects of XEmacs that may be of interest to C programmers.
A.1 Building XEmacs | How to preload Lisp libraries into XEmacs. | |
A.2 Pure Storage | A kludge to make preloaded Lisp functions sharable. | |
A.3 Garbage Collection | Reclaiming space for Lisp objects no longer used. | |
A.4 Writing XEmacs Primitives | Writing C code for XEmacs. | |
A.5 Object Internals | Data formats of buffers, windows, processes. |
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This section explains the steps involved in building the XEmacs executable. You don’t have to know this material to build and install XEmacs, since the makefiles do all these things automatically. This information is pertinent to XEmacs maintenance.
Compilation of the C source files in the ‘src’ directory produces an executable file called ‘temacs’, also called a bare impure XEmacs. It contains the Emacs Lisp interpreter and I/O routines, but not the editing commands.
The command ‘temacs -l loadup’ uses ‘temacs’ to create the real runnable XEmacs executable. These arguments direct ‘temacs’ to evaluate the Lisp files specified in the file ‘loadup.el’. These files set up the normal XEmacs editing environment, resulting in an XEmacs that is still impure but no longer bare.
It takes a substantial time to load the standard Lisp files. Luckily, you don’t have to do this each time you run XEmacs; ‘temacs’ can dump out an executable program called ‘emacs’ that has these files preloaded. ‘emacs’ starts more quickly because it does not need to load the files. This is the XEmacs executable that is normally installed.
To create ‘emacs’, use the command ‘temacs -batch -l loadup dump’. The purpose of ‘-batch’ here is to prevent ‘temacs’ from trying to initialize any of its data on the terminal; this ensures that the tables of terminal information are empty in the dumped XEmacs. The argument ‘dump’ tells ‘loadup.el’ to dump a new executable named ‘emacs’.
Some operating systems don’t support dumping. On those systems, you must start XEmacs with the ‘temacs -l loadup’ command each time you use it. This takes a substantial time, but since you need to start Emacs once a day at most—or once a week if you never log out—the extra time is not too severe a problem.
You can specify additional files to preload by writing a library named
‘site-load.el’ that loads them. You may need to increase the
value of PURESIZE
, in ‘src/puresize.h’, to make room for the
additional files. (Try adding increments of 20000 until it is big
enough.) However, the advantage of preloading additional files
decreases as machines get faster. On modern machines, it is usually not
advisable.
You can specify other Lisp expressions to execute just before dumping by putting them in a library named ‘site-init.el’. However, if they might alter the behavior that users expect from an ordinary unmodified XEmacs, it is better to put them in ‘default.el’, so that users can override them if they wish. @xref{Start-up Summary}.
Before ‘loadup.el’ dumps the new executable, it finds the
documentation strings for primitive and preloaded functions (and
variables) in the file where they are stored, by calling
Snarf-documentation
(@pxref{Accessing Documentation}). These
strings were moved out of the ‘emacs’ executable to make it
smaller. @xref{Documentation Basics}.
This function dumps the current state of XEmacs into an executable file to-file. It takes symbols from from-file (this is normally the executable file ‘temacs’).
If you use this function in an XEmacs that was already dumped, you must
set command-line-processed
to nil
first for good results.
@xref{Command Line Arguments}.
This function returns a string describing the version of XEmacs that is running. It is useful to include this string in bug reports.
(emacs-version) ⇒ "XEmacs 19.13 of Mon Aug 21 1995 on willow (usg-unix-v) [formerly Lucid Emacs]"
Called interactively, the function prints the same information in the echo area.
The value of this variable is the time at which XEmacs was built at the local site.
emacs-build-time ⇒ "Tue Jun 6 14:55:57 1995"
The value of this variable is the version of Emacs being run. It is a
string, e.g. "19.13 XEmacs Lucid"
.
The following two variables did not exist before Emacs version 19.23, which reduces their usefulness at present, but we hope they will be convenient in the future.
The major version number of Emacs, as an integer. For XEmacs version 19.13, the value is 19.
The minor version number of Emacs, as an integer. For XEmacs version 19.13, the value is 13.
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Emacs Lisp uses two kinds of storage for user-created Lisp objects: normal storage and pure storage. Normal storage is where all the new data created during an XEmacs session is kept; see the following section for information on normal storage. Pure storage is used for certain data in the preloaded standard Lisp files—data that should never change during actual use of XEmacs.
Pure storage is allocated only while ‘temacs’ is loading the
standard preloaded Lisp libraries. In the file ‘emacs’, it is
marked as read-only (on operating systems that permit this), so that
the memory space can be shared by all the XEmacs jobs running on the
machine at once. Pure storage is not expandable; a fixed amount is
allocated when XEmacs is compiled, and if that is not sufficient for the
preloaded libraries, ‘temacs’ crashes. If that happens, you must
increase the compilation parameter PURESIZE
in the file
‘src/puresize.h’. This normally won’t happen unless you try to
preload additional libraries or add features to the standard ones.
This function makes a copy of object in pure storage and returns it. It copies strings by simply making a new string with the same characters in pure storage. It recursively copies the contents of vectors and cons cells. It does not make copies of other objects such as symbols, but just returns them unchanged. It signals an error if asked to copy markers.
This function is a no-op except while XEmacs is being built and dumped; it is usually called only in the file ‘emacs/lisp/loaddefs.el’, but a few packages call it just in case you decide to preload them.
The value of this variable is the number of bytes of pure storage allocated so far. Typically, in a dumped XEmacs, this number is very close to the total amount of pure storage available—if it were not, we would preallocate less.
This variable determines whether defun
should make a copy of the
function definition in pure storage. If it is non-nil
, then the
function definition is copied into pure storage.
This flag is t
while loading all of the basic functions for
building XEmacs initially (allowing those functions to be sharable and
non-collectible). Dumping XEmacs as an executable always writes
nil
in this variable, regardless of the value it actually has
before and after dumping.
You should not change this flag in a running XEmacs.
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When a program creates a list or the user defines a new function (such as by loading a library), that data is placed in normal storage. If normal storage runs low, then XEmacs asks the operating system to allocate more memory in blocks of 1k bytes. Each block is used for one type of Lisp object, so symbols, cons cells, markers, etc., are segregated in distinct blocks in memory. (Vectors, long strings, buffers and certain other editing types, which are fairly large, are allocated in individual blocks, one per object, while small strings are packed into blocks of 8k bytes.)
It is quite common to use some storage for a while, then release it by (for example) killing a buffer or deleting the last pointer to an object. XEmacs provides a garbage collector to reclaim this abandoned storage. (This name is traditional, but “garbage recycler” might be a more intuitive metaphor for this facility.)
The garbage collector operates by finding and marking all Lisp objects that are still accessible to Lisp programs. To begin with, it assumes all the symbols, their values and associated function definitions, and any data presently on the stack, are accessible. Any objects that can be reached indirectly through other accessible objects are also accessible.
When marking is finished, all objects still unmarked are garbage. No matter what the Lisp program or the user does, it is impossible to refer to them, since there is no longer a way to reach them. Their space might as well be reused, since no one will miss them. The second (“sweep”) phase of the garbage collector arranges to reuse them.
The sweep phase puts unused cons cells onto a free list
for future allocation; likewise for symbols and markers. It compacts
the accessible strings so they occupy fewer 8k blocks; then it frees the
other 8k blocks. Vectors, buffers, windows, and other large objects are
individually allocated and freed using malloc
and free
.
Common Lisp note: unlike other Lisps, Emacs Lisp does not call the garbage collector when the free list is empty. Instead, it simply requests the operating system to allocate more storage, and processing continues until
gc-cons-threshold
bytes have been used.This means that you can make sure that the garbage collector will not run during a certain portion of a Lisp program by calling the garbage collector explicitly just before it (provided that portion of the program does not use so much space as to force a second garbage collection).
This command runs a garbage collection, and returns information on
the amount of space in use. (Garbage collection can also occur
spontaneously if you use more than gc-cons-threshold
bytes of
Lisp data since the previous garbage collection.)
garbage-collect
returns a list containing the following
information:
((used-conses . free-conses) (used-syms . free-syms)
(used-markers . free-markers) used-string-chars used-vector-slots (plist))
(garbage-collect) ⇒ ((7285 . 3680) (5462 . 0) (47 . 1074) 135506 20902 (conses-used 7285 conses-free 3680 cons-storage 88064 symbols-used 5462 symbols-free 0 symbol-storage 133120 vectors-used 1005 vectors-total-length 20902 vector-storage 95668 bytecodes-used 508 bytecodes-free 30 bytecode-storage 16192 short-strings-used 3596 long-strings-used 0 strings-free 920 short-strings-total-length 135506 short-string-storage 163840 long-strings-total-length 0 string-header-storage 55296 floats-used 0 floats-free 9 float-storage 2044 markers-used 47 markers-free 1074 marker-storage 18360 events-used 104 events-free 21 event-storage 15840 extents-used 0 extents-free 17 extent-storage 2032 extent-duplicates-used 0 extent-duplicates-free 0 extent-duplicate-storage 0 processs-used 1 process-storage 80 frames-used 1 frame-storage 188 menubar-datas-used 1 menubar-data-storage 24 pixmaps-used 10 pixmap-storage 560 faces-used 44 face-storage 1232 pixels-used 14 pixel-storage 448 fonts-used 7 font-storage 280 tooltalk-patterns-used 23 tooltalk-pattern-storage 368 cursors-used 5 cursor-storage 160 buffer-local-value-cells-used 33 buffer-local-value-cell-storage 1056 keymaps-used 128 keymap-storage 5120 hashtables-used 256 hashtable-storage 9216 buffers-used 11 buffers-freed 1 buffer-storage 2640 output-streams-used 0 output-streams-freed 1 output-stream-storage 0 windows-used 4 windows-freed 12 window-storage 576 window-configurations-used 0 window-configurations-freed 22 window-configuration-storage 0))
Here is a table explaining each element:
The number of cons cells in use.
The number of cons cells for which space has been obtained from the operating system, but that are not currently being used.
The number of symbols in use.
The number of symbols for which space has been obtained from the operating system, but that are not currently being used.
The number of markers in use.
The number of markers for which space has been obtained from the operating system, but that are not currently being used.
The total size of all strings, in characters.
The total number of elements of existing vectors.
A list of alternating keyword/value pairs providing more detailed information. (As you can see above, quite a lot of information is provided.)
The value of this variable is the number of bytes of storage that must be allocated for Lisp objects after one garbage collection in order to trigger another garbage collection. A cons cell counts as eight bytes, a string as one byte per character plus a few bytes of overhead, and so on; space allocated to the contents of buffers does not count. Note that the subsequent garbage collection does not happen immediately when the threshold is exhausted, but only the next time the Lisp evaluator is called.
The initial threshold value is 300,000. If you specify a larger value, garbage collection will happen less often. This reduces the amount of time spent garbage collecting, but increases total memory use. You may want to do this when running a program that creates lots of Lisp data.
You can make collections more frequent by specifying a smaller value,
down to 10,000. A value less than 10,000 will remain in effect only
until the subsequent garbage collection, at which time
garbage-collect
will set the threshold back to 10,000.
This function returns the address of the last byte XEmacs has allocated, divided by 1024. We divide the value by 1024 to make sure it fits in a Lisp integer.
You can use this to get a general idea of how your actions affect the memory usage.
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Lisp primitives are Lisp functions implemented in C. The details of interfacing the C function so that Lisp can call it are handled by a few C macros. The only way to really understand how to write new C code is to read the source, but we can explain some things here.
An example of a special form is the definition of or
, from
‘eval.c’. (An ordinary function would have the same general
appearance.)
DEFUN ("or", For, Sor, 0, UNEVALLED, 0, "Eval args until one of them yields non-nil, then return that value.\n\ The remaining args are not evalled at all.\n\
If all args return nil, return nil.") (args) Lisp_Object args; { register Lisp_Object val; Lisp_Object args_left; struct gcpro gcpro1;
if (NULL (args)) return Qnil; args_left = args; GCPRO1 (args_left);
do { val = Feval (Fcar (args_left)); if (!NULL (val)) break; args_left = Fcdr (args_left); } while (!NULL (args_left));
UNGCPRO; return val; }
Let’s start with a precise explanation of the arguments to the
DEFUN
macro. Here is a template for them:
DEFUN (lname, fname, sname, min, max, interactive, doc)
This is the name of the Lisp symbol to define as the function name; in
the example above, it is or
.
This is the C function name for this function. This is
the name that is used in C code for calling the function. The name is,
by convention, ‘F’ prepended to the Lisp name, with all dashes
(‘-’) in the Lisp name changed to underscores. Thus, to call this
function from C code, call For
. Remember that the arguments must
be of type Lisp_Object
; various macros and functions for creating
values of type Lisp_Object
are declared in the file
‘lisp.h’.
This is a C variable name to use for a structure that holds the data for the subr object that represents the function in Lisp. This structure conveys the Lisp symbol name to the initialization routine that will create the symbol and store the subr object as its definition. By convention, this name is always fname with ‘F’ replaced with ‘S’.
This is the minimum number of arguments that the function requires. The
function or
allows a minimum of zero arguments.
This is the maximum number of arguments that the function accepts, if
there is a fixed maximum. Alternatively, it can be UNEVALLED
,
indicating a special form that receives unevaluated arguments, or
MANY
, indicating an unlimited number of evaluated arguments (the
equivalent of &rest
). Both UNEVALLED
and MANY
are
macros. If max is a number, it may not be less than min and
it may not be greater than seven.
This is an interactive specification, a string such as might be used as
the argument of interactive
in a Lisp function. In the case of
or
, it is 0 (a null pointer), indicating that or
cannot be
called interactively. A value of ""
indicates a function that
should receive no arguments when called interactively.
This is the documentation string. It is written just like a documentation string for a function defined in Lisp, except you must write ‘\n\’ at the end of each line. In particular, the first line should be a single sentence.
After the call to the DEFUN
macro, you must write the argument
name list that every C function must have, followed by ordinary C
declarations for the arguments. For a function with a fixed maximum
number of arguments, declare a C argument for each Lisp argument, and
give them all type Lisp_Object
. When a Lisp function has no
upper limit on the number of arguments, its implementation in C actually
receives exactly two arguments: the first is the number of Lisp
arguments, and the second is the address of a block containing their
values. They have types int
and Lisp_Object *
.
Within the function For
itself, note the use of the macros
GCPRO1
and UNGCPRO
. GCPRO1
is used to “protect”
a variable from garbage collection—to inform the garbage collector that
it must look in that variable and regard its contents as an accessible
object. This is necessary whenever you call Feval
or anything
that can directly or indirectly call Feval
. At such a time, any
Lisp object that you intend to refer to again must be protected somehow.
UNGCPRO
cancels the protection of the variables that are
protected in the current function. It is necessary to do this explicitly.
For most data types, it suffices to protect at least one pointer to the object; as long as the object is not recycled, all pointers to it remain valid. This is not so for strings, because the garbage collector can move them. When the garbage collector moves a string, it relocates all the pointers it knows about; any other pointers become invalid. Therefore, you must protect all pointers to strings across any point where garbage collection may be possible.
The macro GCPRO1
protects just one local variable. If you want
to protect two, use GCPRO2
instead; repeating GCPRO1
will
not work. Macros GCPRO3
and GCPRO4
also exist.
These macros implicitly use local variables such as gcpro1
; you
must declare these explicitly, with type struct gcpro
. Thus, if
you use GCPRO2
, you must declare gcpro1
and gcpro2
.
Alas, we can’t explain all the tricky details here.
You must not use C initializers for static or global variables unless they are never written once XEmacs is dumped. These variables with initializers are allocated in an area of memory that becomes read-only (on certain operating systems) as a result of dumping XEmacs. See section Pure Storage.
Do not use static variables within functions—place all static
variables at top level in the file. This is necessary because XEmacs on
some operating systems defines the keyword static
as a null
macro. (This definition is used because those systems put all variables
declared static in a place that becomes read-only after dumping, whether
they have initializers or not.)
Defining the C function is not enough to make a Lisp primitive available; you must also create the Lisp symbol for the primitive and store a suitable subr object in its function cell. The code looks like this:
defsubr (&subr-structure-name);
Here subr-structure-name is the name you used as the third
argument to DEFUN
.
If you add a new primitive to a file that already has Lisp primitives
defined in it, find the function (near the end of the file) named
syms_of_something
, and add the call to defsubr
there. If the file doesn’t have this function, or if you create a new
file, add to it a syms_of_filename
(e.g.,
syms_of_myfile
). Then find the spot in ‘emacs.c’ where all
of these functions are called, and add a call to
syms_of_filename
there.
The function syms_of_filename
is also the place to define
any C variables that are to be visible as Lisp variables.
DEFVAR_LISP
makes a C variable of type Lisp_Object
visible
in Lisp. DEFVAR_INT
makes a C variable of type int
visible in Lisp with a value that is always an integer.
DEFVAR_BOOL
makes a C variable of type int
visible in Lisp
with a value that is either t
or nil
.
Here is another example function, with more complicated arguments. This comes from the code for the X Window System, and it demonstrates the use of macros and functions to manipulate Lisp objects.
DEFUN ("coordinates-in-window-p", Fcoordinates_in_window_p, Scoordinates_in_window_p, 2, 2, "xSpecify coordinate pair: \nXExpression which evals to window: ", "Return non-nil if POSITIONS is in WINDOW.\n\ \(POSITIONS is a list, (SCREEN-X SCREEN-Y)\)\n\
Returned value is list of positions expressed\n\ relative to window upper left corner.") (coordinate, window) register Lisp_Object coordinate, window; { register Lisp_Object xcoord, ycoord;
if (!CONSP (coordinate)) wrong_type_argument (Qlistp, coordinate); CHECK_WINDOW (window, 2); xcoord = Fcar (coordinate); ycoord = Fcar (Fcdr (coordinate)); CHECK_NUMBER (xcoord, 0); CHECK_NUMBER (ycoord, 1);
if ((XINT (xcoord) < XINT (XWINDOW (window)->left)) || (XINT (xcoord) >= (XINT (XWINDOW (window)->left) + XINT (XWINDOW (window)->width)))) return Qnil; XFASTINT (xcoord) -= XFASTINT (XWINDOW (window)->left);
if (XINT (ycoord) == (frame_height - 1)) return Qnil;
if ((XINT (ycoord) < XINT (XWINDOW (window)->top)) || (XINT (ycoord) >= (XINT (XWINDOW (window)->top) + XINT (XWINDOW (window)->height)) - 1)) return Qnil;
XFASTINT (ycoord) -= XFASTINT (XWINDOW (window)->top); return (Fcons (xcoord, Fcons (ycoord, Qnil))); }
Note that C code cannot call functions by name unless they are defined
in C. The way to call a function written in Lisp is to use
Ffuncall
, which embodies the Lisp function funcall
. Since
the Lisp function funcall
accepts an unlimited number of
arguments, in C it takes two: the number of Lisp-level arguments, and a
one-dimensional array containing their values. The first Lisp-level
argument is the Lisp function to call, and the rest are the arguments to
pass to it. Since Ffuncall
can call the evaluator, you must
protect pointers from garbage collection around the call to
Ffuncall
.
The C functions call0
, call1
, call2
, and so on,
provide handy ways to call a Lisp function conveniently with a fixed
number of arguments. They work by calling Ffuncall
.
‘eval.c’ is a very good file to look through for examples; ‘lisp.h’ contains the definitions for some important macros and functions.
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Emacs Lisp manipulates many different types of data. The actual data are stored in a heap and the only access that programs have to it is through pointers. Pointers are thirty-two bits wide in most implementations. Depending on the operating system and type of machine for which you compile XEmacs, twenty-four to twenty-six bits are used to address the object, and the remaining six to eight bits are used for a tag that identifies the object’s type.
Because Lisp objects are represented as tagged pointers, it is always
possible to determine the Lisp data type of any object. The C data type
Lisp_Object
can hold any Lisp object of any data type. Ordinary
variables have type Lisp_Object
, which means they can hold any
type of Lisp value; you can determine the actual data type only at run
time. The same is true for function arguments; if you want a function
to accept only a certain type of argument, you must check the type
explicitly using a suitable predicate (@pxref{Type Predicates}).
A.5.1 Buffer Internals | Components of a buffer structure. | |
A.5.2 Window Internals | Components of a window structure. | |
A.5.3 Process Internals | Components of a process structure. |
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Buffers contain fields not directly accessible by the Lisp programmer. We describe them here, naming them by the names used in the C code. Many are accessible indirectly in Lisp programs via Lisp primitives.
name
The buffer name is a string that names the buffer. It is guaranteed to be unique. @xref{Buffer Names}.
save_modified
This field contains the time when the buffer was last saved, as an integer. @xref{Buffer Modification}.
modtime
This field contains the modification time of the visited file. It is set when the file is written or read. Every time the buffer is written to the file, this field is compared to the modification time of the file. @xref{Buffer Modification}.
auto_save_modified
This field contains the time when the buffer was last auto-saved.
last_window_start
This field contains the window-start
position in the buffer as of
the last time the buffer was displayed in a window.
undo_list
This field points to the buffer’s undo list. @xref{Undo}.
syntax_table_v
This field contains the syntax table for the buffer. @xref{Syntax Tables}.
downcase_table
This field contains the conversion table for converting text to lower case. @xref{Case Table}.
upcase_table
This field contains the conversion table for converting text to upper case. @xref{Case Table}.
case_canon_table
This field contains the conversion table for canonicalizing text for case-folding search. @xref{Case Table}.
case_eqv_table
This field contains the equivalence table for case-folding search. @xref{Case Table}.
display_table
This field contains the buffer’s display table, or nil
if it doesn’t
have one. @xref{Display Tables}.
markers
This field contains the chain of all markers that currently point into the buffer. Deletion of text in the buffer, and motion of the buffer’s gap, must check each of these markers and perhaps update it. @xref{Markers}.
backed_up
This field is a flag that tells whether a backup file has been made for the visited file of this buffer.
mark
This field contains the mark for the buffer. The mark is a marker,
hence it is also included on the list markers
. @xref{The Mark}.
mark_active
This field is non-nil
if the buffer’s mark is active.
local_var_alist
This field contains the association list describing the variables local in this buffer, and their values, with the exception of local variables that have special slots in the buffer object. (Those slots are omitted from this table.) @xref{Buffer-Local Variables}.
modeline_format
This field contains a Lisp object which controls how to display the mode line for this buffer. @xref{Modeline Format}.
base_buffer
This field holds the buffer’s base buffer (if it is an indirect buffer),
or nil
.
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Windows have the following accessible fields:
frame
The frame that this window is on.
mini_p
Non-nil
if this window is a minibuffer window.
buffer
The buffer that the window is displaying. This may change often during the life of the window.
dedicated
Non-nil
if this window is dedicated to its buffer.
pointm
This is the value of point in the current buffer when this window is selected; when it is not selected, it retains its previous value.
start
The position in the buffer that is the first character to be displayed in the window.
force_start
If this flag is non-nil
, it says that the window has been
scrolled explicitly by the Lisp program. This affects what the next
redisplay does if point is off the screen: instead of scrolling the
window to show the text around point, it moves point to a location that
is on the screen.
last_modified
The modified
field of the window’s buffer, as of the last time
a redisplay completed in this window.
last_point
The buffer’s value of point, as of the last time a redisplay completed in this window.
left
This is the left-hand edge of the window, measured in columns. (The leftmost column on the screen is column 0.)
top
This is the top edge of the window, measured in lines. (The top line on the screen is line 0.)
height
The height of the window, measured in lines.
width
The width of the window, measured in columns.
next
This is the window that is the next in the chain of siblings. It is
nil
in a window that is the rightmost or bottommost of a group of
siblings.
prev
This is the window that is the previous in the chain of siblings. It is
nil
in a window that is the leftmost or topmost of a group of
siblings.
parent
Internally, XEmacs arranges windows in a tree; each group of siblings has a parent window whose area includes all the siblings. This field points to a window’s parent.
Parent windows do not display buffers, and play little role in display except to shape their child windows. Emacs Lisp programs usually have no access to the parent windows; they operate on the windows at the leaves of the tree, which actually display buffers.
hscroll
This is the number of columns that the display in the window is scrolled horizontally to the left. Normally, this is 0.
use_time
This is the last time that the window was selected. The function
get-lru-window
uses this field.
display_table
The window’s display table, or nil
if none is specified for it.
update_mode_line
Non-nil
means this window’s mode line needs to be updated.
base_line_number
The line number of a certain position in the buffer, or nil
.
This is used for displaying the line number of point in the mode line.
base_line_pos
The position in the buffer for which the line number is known, or
nil
meaning none is known.
region_showing
If the region (or part of it) is highlighted in this window, this field
holds the mark position that made one end of that region. Otherwise,
this field is nil
.
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The fields of a process are:
name
A string, the name of the process.
command
A list containing the command arguments that were used to start this process.
filter
A function used to accept output from the process instead of a buffer,
or nil
.
sentinel
A function called whenever the process receives a signal, or nil
.
buffer
The associated buffer of the process.
pid
An integer, the Unix process ID.
childp
A flag, non-nil
if this is really a child process.
It is nil
for a network connection.
mark
A marker indicating the position of the end of the last output from this process inserted into the buffer. This is often but not always the end of the buffer.
kill_without_query
If this is non-nil
, killing XEmacs while this process is still
running does not ask for confirmation about killing the process.
raw_status_low
raw_status_high
These two fields record 16 bits each of the process status returned by
the wait
system call.
status
The process status, as process-status
should return it.
tick
update_tick
If these two fields are not equal, a change in the status of the process needs to be reported, either by running the sentinel or by inserting a message in the process buffer.
pty_flag
Non-nil
if communication with the subprocess uses a PTY;
nil
if it uses a pipe.
infd
The file descriptor for input from the process.
outfd
The file descriptor for output to the process.
subtty
The file descriptor for the terminal that the subprocess is using. (On
some systems, there is no need to record this, so the value is
nil
.)
tty_name
The name of the terminal that the subprocess is using,
or nil
if it is using pipes.
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