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; Add 2022 to copyright years. # Conflicts: # etc/NEWS # etc/refcards/ru-refcard.tex # lib/cdefs.h # lisp/erc/erc-dcc.el # lisp/erc/erc-imenu.el # lisp/erc/erc-replace.el # lisp/image-dired.el # lisp/progmodes/xref.el # m4/alloca.m4 # m4/byteswap.m4 # m4/errno_h.m4 # m4/getopt.m4 # m4/gnulib-common.m4 # m4/inttypes.m4 # m4/stddef_h.m4 # m4/stdint.m4 # m4/sys_socket_h.m4
905 lines
34 KiB
EmacsLisp
905 lines
34 KiB
EmacsLisp
;;; composite.el --- support character composition -*- lexical-binding: t; -*-
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;; Copyright (C) 2001-2022 Free Software Foundation, Inc.
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;; Copyright (C) 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007,
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;; 2008, 2009, 2010, 2011
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;; National Institute of Advanced Industrial Science and Technology (AIST)
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;; Registration Number H14PRO021
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;; Author: Kenichi Handa <handa@gnu.org>
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;; (according to ack.texi)
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;; Keywords: mule, multilingual, character composition
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;; Package: emacs
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;; This file is part of GNU Emacs.
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;; GNU Emacs is free software: you can redistribute it and/or modify
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;; it under the terms of the GNU General Public License as published by
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;; the Free Software Foundation, either version 3 of the License, or
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;; (at your option) any later version.
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;; GNU Emacs is distributed in the hope that it will be useful,
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;; but WITHOUT ANY WARRANTY; without even the implied warranty of
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;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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;; GNU General Public License for more details.
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;; You should have received a copy of the GNU General Public License
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;; along with GNU Emacs. If not, see <https://www.gnu.org/licenses/>.
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;;; Commentary:
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;;; Code:
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(defconst reference-point-alist
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'((tl . 0) (tc . 1) (tr . 2)
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(Bl . 3) (Bc . 4) (Br . 5)
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(bl . 6) (bc . 7) (br . 8)
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(cl . 9) (cc . 10) (cr . 11)
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(top-left . 0) (top-center . 1) (top-right . 2)
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(base-left . 3) (base-center . 4) (base-right . 5)
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(bottom-left . 6) (bottom-center . 7) (bottom-right . 8)
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(center-left . 9) (center-center . 10) (center-right . 11)
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;; For backward compatibility...
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(ml . 3) (mc . 10) (mr . 5)
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(mid-left . 3) (mid-center . 10) (mid-right . 5))
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"Alist of symbols vs integer codes of glyph reference points.
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A glyph reference point symbol is to be used to specify a composition
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rule in COMPONENTS argument to such functions as `compose-region'.
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The meaning of glyph reference point codes is as follows:
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0----1----2 <---- ascent 0:tl or top-left
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| | 1:tc or top-center
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| | 2:tr or top-right
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| | 3:Bl or base-left 9:cl or center-left
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9 10 11 <---- center 4:Bc or base-center 10:cc or center-center
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| | 5:Br or base-right 11:cr or center-right
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--3----4----5-- <-- baseline 6:bl or bottom-left
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| | 7:bc or bottom-center
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6----7----8 <---- descent 8:br or bottom-right
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Glyph reference point symbols are to be used to specify a composition
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rule of the form (GLOBAL-REF-POINT . NEW-REF-POINT), where
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GLOBAL-REF-POINT is a reference point in the overall glyphs already
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composed, and NEW-REF-POINT is a reference point in the new glyph to
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be added.
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For instance, if GLOBAL-REF-POINT is `br' (bottom-right) and
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NEW-REF-POINT is `tc' (top-center), the overall glyph is updated as
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follows (the point `*' corresponds to both reference points):
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+-------+--+ <--- new ascent
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| | |
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| global| |
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| glyph | |
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-- | | |-- <--- baseline (doesn't change)
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+----+--*--+
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| | new |
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| |glyph|
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+----+-----+ <--- new descent
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A composition rule may have the form (GLOBAL-REF-POINT
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NEW-REF-POINT XOFF YOFF), where XOFF and YOFF specify how much
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to shift NEW-REF-POINT from GLOBAL-REF-POINT. In this case, XOFF
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and YOFF are integers in the range -100..100 representing the
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shifting percentage against the font size.")
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;;;###autoload
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(defun encode-composition-rule (rule)
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"Encode composition rule RULE into an integer value.
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RULE is a cons of global and new reference point symbols
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\(see `reference-point-alist')."
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;; This must be compatible with C macro COMPOSITION_ENCODE_RULE
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;; defined in composite.h.
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(if (and (integerp rule) (< rule 144))
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;; Already encoded.
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rule
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(if (consp rule)
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(let ((gref (car rule))
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(nref (cdr rule))
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xoff yoff)
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(if (consp nref) ; (GREF NREF XOFF YOFF)
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(progn
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(setq xoff (nth 1 nref)
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yoff (nth 2 nref)
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nref (car nref))
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(or (and (>= xoff -100) (<= xoff 100)
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(>= yoff -100) (<= yoff 100))
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(error "Invalid composition rule: %s" rule))
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(setq xoff (+ xoff 128) yoff (+ yoff 128)))
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;; (GREF . NREF)
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(setq xoff 0 yoff 0))
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(or (integerp gref)
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(setq gref (cdr (assq gref reference-point-alist))))
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(or (integerp nref)
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(setq nref (cdr (assq nref reference-point-alist))))
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(or (and (>= gref 0) (< gref 12) (>= nref 0) (< nref 12))
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(error "Invalid composition rule: %S" rule))
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(logior (ash xoff 16) (ash yoff 8) (+ (* gref 12) nref)))
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(error "Invalid composition rule: %S" rule))))
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;; Decode encoded composition rule RULE-CODE. The value is a cons of
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;; global and new reference point symbols.
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;; This must be compatible with C macro COMPOSITION_DECODE_RULE
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;; defined in composite.h.
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(defun decode-composition-rule (rule-code)
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(or (and (natnump rule-code) (< rule-code #x1000000))
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(error "Invalid encoded composition rule: %S" rule-code))
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(let ((xoff (ash rule-code -16))
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(yoff (logand (ash rule-code -8) #xFF))
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gref nref)
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(setq rule-code (logand rule-code #xFF)
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gref (car (rassq (/ rule-code 12) reference-point-alist))
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nref (car (rassq (% rule-code 12) reference-point-alist)))
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(or (and gref (symbolp gref) nref (symbolp nref))
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(error "Invalid composition rule code: %S" rule-code))
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(if (and (= xoff 0) (= yoff 0))
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(cons gref nref)
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(setq xoff (- xoff 128) yoff (- yoff 128))
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(list gref xoff yoff nref))))
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;; Encode composition rules in composition components COMPONENTS. The
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;; value is a copy of COMPONENTS, where composition rules (cons of
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;; global and new glyph reference point symbols) are replaced with
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;; encoded composition rules. Optional 2nd argument NOCOPY non-nil
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;; means don't make a copy but modify COMPONENTS directly.
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(defun encode-composition-components (components &optional nocopy)
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(or nocopy
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(setq components (copy-sequence components)))
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(if (vectorp components)
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(let ((len (length components))
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(i 1))
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(while (< i len)
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(aset components i
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(encode-composition-rule (aref components i)))
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(setq i (+ i 2))))
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(let ((tail (cdr components)))
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(while tail
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(setcar tail
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(encode-composition-rule (car tail)))
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(setq tail (nthcdr 2 tail)))))
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components)
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;; Decode composition rule codes in composition components COMPONENTS.
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;; The value is a copy of COMPONENTS, where composition rule codes are
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;; replaced with composition rules (cons of global and new glyph
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;; reference point symbols). Optional 2nd argument NOCOPY non-nil
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;; means don't make a copy but modify COMPONENTS directly.
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;; It is assumed that COMPONENTS is a vector and is for rule-base
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;; composition, thus (2N+1)th elements are rule codes.
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(defun decode-composition-components (components &optional nocopy)
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(or nocopy
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(setq components (copy-sequence components)))
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(let ((len (length components))
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(i 1))
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(while (< i len)
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(aset components i
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(decode-composition-rule (aref components i)))
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(setq i (+ i 2))))
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components)
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(defun compose-region (start end &optional components modification-func)
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"Compose characters in the current region.
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Characters are composed relatively, i.e. composed by overstriking
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or stacking depending on ascent, descent and other metrics of
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glyphs.
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For instance, if the region has three characters \"XYZ\", X is
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regarded as BASE glyph, and Y is displayed:
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(1) above BASE if Y's descent value is not positive
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(2) below BASE if Y's ascent value is not positive
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(3) on BASE (i.e. at the BASE position) otherwise
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and Z is displayed with the same rule while regarding the whole
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XY glyphs as BASE.
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When called from a program, expects these four arguments.
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First two arguments START and END are positions (integers or markers)
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specifying the region.
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Optional 3rd argument COMPONENTS, if non-nil, is a character, a string
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or a vector or list of integers and rules.
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If it is a character, it is an alternate character to display instead
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of the text in the region.
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If it is a string, the elements are alternate characters. In
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this case, TAB element has a special meaning. If the first
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character is TAB, the glyphs are displayed with left padding space
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so that no pixel overlaps with the previous column. If the last
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character is TAB, the glyphs are displayed with right padding
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space so that no pixel overlaps with the following column.
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If it is a vector or list, it is a sequence of alternate characters and
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composition rules, where (2N)th elements are characters and (2N+1)th
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elements are composition rules to specify how to compose (2N+2)th
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elements with previously composed N glyphs.
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A composition rule is a cons of global and new glyph reference point
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symbols. See the documentation of `reference-point-alist' for more
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details.
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Optional 4th argument MODIFICATION-FUNC is a function to call to
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adjust the composition when it gets invalid because of a change of
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text in the composition."
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(interactive "r")
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(let ((modified-p (buffer-modified-p))
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(inhibit-read-only t))
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(if (or (vectorp components) (listp components))
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(setq components (encode-composition-components components)))
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(compose-region-internal start end components modification-func)
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(restore-buffer-modified-p modified-p)))
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(defun decompose-region (start end)
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"Decompose text in the current region.
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When called from a program, expects two arguments,
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positions (integers or markers) specifying the region."
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(interactive "r")
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(let ((modified-p (buffer-modified-p))
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(inhibit-read-only t))
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(remove-text-properties start end '(composition nil))
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(restore-buffer-modified-p modified-p)))
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(defun compose-string (string &optional start end components modification-func)
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"Compose characters in string STRING.
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The return value is STRING with the `composition' property put on all
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the characters in it.
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Optional 2nd and 3rd arguments START and END specify the range of
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STRING to be composed. They default to the beginning and the end of
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STRING respectively.
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Optional 4th argument COMPONENTS, if non-nil, is a character or a
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sequence (vector, list, or string) of integers. See the function
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`compose-region' for more detail.
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Optional 5th argument MODIFICATION-FUNC is a function to call to
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adjust the composition when it gets invalid because of a change of
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text in the composition."
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(if (or (vectorp components) (listp components))
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(setq components (encode-composition-components components)))
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(or start (setq start 0))
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(or end (setq end (length string)))
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(compose-string-internal string start end components modification-func)
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string)
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(defun decompose-string (string)
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"Return STRING where `composition' property is removed."
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(remove-text-properties 0 (length string) '(composition nil) string)
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string)
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(defun compose-chars (&rest args)
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"Return a string from arguments in which all characters are composed.
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For relative composition, arguments are characters.
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For rule-based composition, Mth (where M is odd) arguments are
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characters, and Nth (where N is even) arguments are composition rules.
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A composition rule is a cons of glyph reference points of the form
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\(GLOBAL-REF-POINT . NEW-REF-POINT). See the documentation of
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`reference-point-alist' for more detail."
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(let (str components)
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(if (consp (car (cdr args)))
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;; Rule-base composition.
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(let ((tail (encode-composition-components args 'nocopy)))
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(while tail
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(setq str (cons (car tail) str))
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(setq tail (nthcdr 2 tail)))
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(setq str (concat (nreverse str))
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components args))
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;; Relative composition.
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(setq str (concat args)))
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(compose-string-internal str 0 (length str) components)))
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(defun find-composition (pos &optional limit string detail-p)
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"Return information about a composition at or near buffer position POS.
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If the character at POS has `composition' property, the value is a list
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\(FROM TO VALID-P).
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FROM and TO specify the range of text that has the same `composition'
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property, VALID-P is t if this composition is valid, and nil if not.
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If there's no composition at POS, and the optional 2nd argument LIMIT
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is non-nil, search for a composition toward the position given by LIMIT.
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If no composition is found, return nil.
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Optional 3rd argument STRING, if non-nil, is a string to look for a
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composition in; nil means the current buffer.
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If a valid composition is found and the optional 4th argument DETAIL-P
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is non-nil, the return value is a list of the form
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(FROM TO COMPONENTS RELATIVE-P MOD-FUNC WIDTH)
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COMPONENTS is a vector of integers, the meaning depends on RELATIVE-P.
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RELATIVE-P is t if the composition method is relative, else nil.
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If RELATIVE-P is t, COMPONENTS is a vector of characters to be
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composed. If RELATIVE-P is nil, COMPONENTS is a vector of characters
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and composition rules as described in `compose-region'.
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MOD-FUNC is a modification function of the composition.
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WIDTH is a number of columns the composition occupies on the screen.
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When Automatic Composition mode is on, this function also finds a
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chunk of text that is automatically composed. If such a chunk is
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found closer to POS than the position that has `composition'
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property, the value is a list of FROM, TO, and a glyph-string
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that specifies how the chunk is to be composed; DETAIL-P is
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ignored in this case. See the function `composition-get-gstring'
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for the format of the glyph-string."
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(let ((result (find-composition-internal pos limit string detail-p)))
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(if (and detail-p (> (length result) 3) (nth 2 result) (not (nth 3 result)))
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;; This is a valid rule-base composition.
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(decode-composition-components (nth 2 result) 'nocopy))
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result))
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(defun compose-chars-after (pos &optional limit object)
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"Compose characters in current buffer after position POS.
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It looks up the char-table `composition-function-table' (which
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see) by a character at POS, and compose characters after POS
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according to the contents of `composition-function-table'.
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Optional 2nd arg LIMIT, if non-nil, limits characters to compose.
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Optional 3rd arg OBJECT, if non-nil, is a string that contains the
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text to compose. In that case, POS and LIMIT index into the string.
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This function is the default value of `compose-chars-after-function'."
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(let ((tail (aref composition-function-table (char-after pos)))
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(font-obj (and (display-multi-font-p)
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(and (not (stringp object))
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(font-at pos (selected-window)))))
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pattern func result)
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(or limit
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(setq limit (if (stringp object) (length object) (point-max))))
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(when (and font-obj tail)
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(save-match-data
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(save-excursion
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(while tail
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(if (functionp (car tail))
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(setq pattern nil func (car tail))
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(setq pattern (car (car tail))
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func (cdr (car tail))))
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(goto-char pos)
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(if pattern
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(if (and (if (stringp object)
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(eq (string-match pattern object) 0)
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(looking-at pattern))
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(<= (match-end 0) limit))
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(setq result
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(funcall func pos (match-end 0) font-obj object nil)))
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(setq result (funcall func pos limit font-obj object nil)))
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(if result (setq tail nil))))))
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result))
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(defun compose-last-chars (args)
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"Compose last characters.
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The argument is a parameterized event of the form
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(compose-last-chars N COMPONENTS),
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where N is the number of characters before point to compose,
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COMPONENTS, if non-nil, is the same as the argument to `compose-region'
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\(which see). If it is nil, `compose-chars-after' is called,
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and that function finds a proper rule to compose the target characters.
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This function is intended to be used from input methods.
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The global keymap binds special event `compose-last-chars' to this
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function. Input method may generate an event (compose-last-chars N COMPONENTS)
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after a sequence of character events."
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(interactive "e")
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(let ((chars (nth 1 args)))
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(if (and (numberp chars)
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(>= (- (point) (point-min)) chars))
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(if (nth 2 args)
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(compose-region (- (point) chars) (point) (nth 2 args))
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(compose-chars-after (- (point) chars) (point))))))
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(global-set-key [compose-last-chars] 'compose-last-chars)
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;;; Automatic character composition.
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;; These macros must match with C macros LGSTRING_XXX and LGLYPH_XXX in font.h
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(defsubst lgstring-header (gstring) (aref gstring 0))
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(defsubst lgstring-set-header (gstring header) (aset gstring 0 header))
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(defsubst lgstring-font (gstring) (aref (lgstring-header gstring) 0))
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(defsubst lgstring-char (gstring i) (aref (lgstring-header gstring) (1+ i)))
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(defsubst lgstring-char-len (gstring) (1- (length (lgstring-header gstring))))
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(defsubst lgstring-shaped-p (gstring) (aref gstring 1))
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(defsubst lgstring-set-id (gstring id) (aset gstring 1 id))
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(defsubst lgstring-glyph (gstring i) (aref gstring (+ i 2)))
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(defsubst lgstring-glyph-len (gstring) (- (length gstring) 2))
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(defsubst lgstring-set-glyph (gstring i glyph) (aset gstring (+ i 2) glyph))
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(defsubst lglyph-from (glyph) (aref glyph 0))
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(defsubst lglyph-to (glyph) (aref glyph 1))
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(defsubst lglyph-char (glyph) (aref glyph 2))
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(defsubst lglyph-code (glyph) (aref glyph 3))
|
||
(defsubst lglyph-width (glyph) (aref glyph 4))
|
||
(defsubst lglyph-lbearing (glyph) (aref glyph 5))
|
||
(defsubst lglyph-rbearing (glyph) (aref glyph 6))
|
||
(defsubst lglyph-ascent (glyph) (aref glyph 7))
|
||
(defsubst lglyph-descent (glyph) (aref glyph 8))
|
||
(defsubst lglyph-adjustment (glyph) (aref glyph 9))
|
||
|
||
(defsubst lglyph-set-from-to (glyph from to)
|
||
(progn (aset glyph 0 from) (aset glyph 1 to)))
|
||
(defsubst lglyph-set-char (glyph char) (aset glyph 2 char))
|
||
(defsubst lglyph-set-code (glyph code) (aset glyph 3 code))
|
||
(defsubst lglyph-set-width (glyph width) (aset glyph 4 width))
|
||
(defsubst lglyph-set-adjustment (glyph &optional xoff yoff wadjust)
|
||
(aset glyph 9 (vector (or xoff 0) (or yoff 0) (or wadjust 0))))
|
||
|
||
;; Return the shallow Copy of GLYPH.
|
||
(defsubst lglyph-copy (glyph) (copy-sequence glyph))
|
||
|
||
;; Insert GLYPH at the index IDX of GSTRING.
|
||
(defun lgstring-insert-glyph (gstring idx glyph)
|
||
(let ((nglyphs (lgstring-glyph-len gstring))
|
||
(i idx))
|
||
(while (and (< i nglyphs) (lgstring-glyph gstring i))
|
||
(setq i (1+ i)))
|
||
(if (= i nglyphs)
|
||
(setq gstring (vconcat gstring (vector glyph)))
|
||
(if (< (1+ i) nglyphs)
|
||
(lgstring-set-glyph gstring (1+ i) nil)))
|
||
(while (> i idx)
|
||
(lgstring-set-glyph gstring i (lgstring-glyph gstring (1- i)))
|
||
(setq i (1- i)))
|
||
(lgstring-set-glyph gstring i glyph)
|
||
gstring))
|
||
|
||
;; Remove glyph at IDX from GSTRING.
|
||
(defun lgstring-remove-glyph (gstring idx)
|
||
(setq gstring (copy-sequence gstring))
|
||
(lgstring-set-id gstring nil)
|
||
(let ((len (length gstring)))
|
||
(setq idx (+ idx 3))
|
||
(while (< idx len)
|
||
(aset gstring (1- idx) (aref gstring idx))
|
||
(setq idx (1+ idx)))
|
||
(aset gstring (1- len) nil))
|
||
gstring)
|
||
|
||
(defun compose-glyph-string (gstring from to)
|
||
(let ((glyph (lgstring-glyph gstring from))
|
||
from-pos to-pos)
|
||
(setq from-pos (lglyph-from glyph)
|
||
to-pos (lglyph-to (lgstring-glyph gstring (1- to))))
|
||
(lglyph-set-from-to glyph from-pos to-pos)
|
||
(setq from (1+ from))
|
||
(while (and (< from to)
|
||
(setq glyph (lgstring-glyph gstring from)))
|
||
(lglyph-set-from-to glyph from-pos to-pos)
|
||
(let ((xoff (if (<= (lglyph-rbearing glyph) 0) 0
|
||
(- (lglyph-width glyph)))))
|
||
(lglyph-set-adjustment glyph xoff 0 0))
|
||
(setq from (1+ from)))
|
||
gstring))
|
||
|
||
(defun compose-glyph-string-relative (gstring from to &optional gap)
|
||
(let ((font-object (lgstring-font gstring))
|
||
(glyph (lgstring-glyph gstring from))
|
||
from-pos to-pos
|
||
ascent descent)
|
||
(if gap
|
||
(setq gap (floor (* (font-get font-object :size) gap)))
|
||
(setq gap 0))
|
||
(setq from-pos (lglyph-from glyph)
|
||
to-pos (lglyph-to (lgstring-glyph gstring (1- to)))
|
||
ascent (lglyph-ascent glyph)
|
||
descent (lglyph-descent glyph))
|
||
(lglyph-set-from-to glyph from-pos to-pos)
|
||
(setq from (1+ from))
|
||
(while (< from to)
|
||
(setq glyph (lgstring-glyph gstring from))
|
||
(lglyph-set-from-to glyph from-pos to-pos)
|
||
(let ((this-ascent (lglyph-ascent glyph))
|
||
(this-descent (lglyph-descent glyph))
|
||
xoff yoff)
|
||
(setq xoff (if (<= (lglyph-rbearing glyph) 0) 0
|
||
(- (lglyph-width glyph))))
|
||
(if (> this-ascent 0)
|
||
(if (< this-descent 0)
|
||
(setq yoff (- 0 ascent gap this-descent)
|
||
ascent (+ ascent gap this-ascent this-descent))
|
||
(setq yoff 0))
|
||
(setq yoff (+ descent gap this-ascent)
|
||
descent (+ descent gap this-ascent this-descent)))
|
||
(if (or (/= xoff 0) (/= yoff 0))
|
||
(lglyph-set-adjustment glyph xoff yoff 0)))
|
||
(setq from (1+ from)))
|
||
gstring))
|
||
|
||
(defun compose-gstring-for-graphic (gstring direction)
|
||
"Compose glyph-string GSTRING under bidi DIRECTION for graphic display.
|
||
DIRECTION is either L2R or R2L, or nil if unknown.
|
||
Combining characters are composed with the preceding base
|
||
character. If the preceding character is not a base character,
|
||
each combining character is composed as a spacing character by
|
||
a padding space before and/or after the character.
|
||
|
||
All non-spacing characters have this function in
|
||
`composition-function-table' unless overwritten."
|
||
(let ((nchars (lgstring-char-len gstring))
|
||
(nglyphs (lgstring-glyph-len gstring))
|
||
(glyph (lgstring-glyph gstring 0)))
|
||
(cond
|
||
;; A non-spacing character not following a proper base character.
|
||
((= nchars 1)
|
||
(let ((lbearing (lglyph-lbearing glyph))
|
||
(rbearing (lglyph-rbearing glyph))
|
||
(width (lglyph-width glyph))
|
||
xoff)
|
||
(if (< lbearing 0)
|
||
(setq xoff (- lbearing))
|
||
(setq xoff 0 lbearing 0))
|
||
(if (< rbearing width)
|
||
(setq rbearing width))
|
||
(lglyph-set-adjustment glyph xoff 0 (- rbearing lbearing))
|
||
gstring))
|
||
|
||
;; This sequence doesn't start with a proper base character.
|
||
((memq (get-char-code-property (lgstring-char gstring 0)
|
||
'general-category)
|
||
;; "Improper" base characters are of the following general
|
||
;; categories:
|
||
;; Mark (nonspacing, combining, enclosing)
|
||
;; Separator (line, paragraph)
|
||
;; Other (control, format, surrogate)
|
||
'(Mn Mc Me Zl Zp Cc Cf Cs))
|
||
nil)
|
||
|
||
;; A base character and the following non-spacing characters.
|
||
(t
|
||
(let ((gstr (font-shape-gstring gstring direction)))
|
||
(if (and gstr
|
||
(> (lglyph-to (lgstring-glyph gstr 0)) 0))
|
||
gstr
|
||
;; The shaper of the font couldn't shape the gstring.
|
||
;; Shape them according to canonical-combining-class.
|
||
(lgstring-set-id gstring nil)
|
||
(let* ((width (lglyph-width glyph))
|
||
(ascent (lglyph-ascent glyph))
|
||
(descent (lglyph-descent glyph))
|
||
(rbearing (lglyph-rbearing glyph))
|
||
(lbearing (lglyph-lbearing glyph))
|
||
(center (/ (+ lbearing rbearing) 2))
|
||
;; Artificial vertical gap between the glyphs.
|
||
(gap (round (* (font-get (lgstring-font gstring) :size) 0.1))))
|
||
(if (= gap 0)
|
||
;; Assure at least 1 pixel vertical gap.
|
||
(setq gap 1))
|
||
(dotimes (i nchars)
|
||
(setq glyph (lgstring-glyph gstring i))
|
||
(when (> i 0)
|
||
(let* ((class (get-char-code-property
|
||
(lglyph-char glyph) 'canonical-combining-class))
|
||
(lb (lglyph-lbearing glyph))
|
||
(rb (lglyph-rbearing glyph))
|
||
(as (lglyph-ascent glyph))
|
||
(de (lglyph-descent glyph))
|
||
(ce (/ (+ lb rb) 2))
|
||
xoff yoff)
|
||
(cond
|
||
((and class (>= class 200) (<= class 240))
|
||
(setq xoff 0 yoff 0)
|
||
(cond
|
||
((= class 200)
|
||
(setq xoff (- lbearing ce)
|
||
yoff (if (> as 0) 0 (+ descent as))))
|
||
((= class 202)
|
||
(if (> as 0) (setq as 0))
|
||
(setq xoff (- center ce)
|
||
yoff (if (> as 0) 0 (+ descent as))))
|
||
((= class 204)
|
||
(if (> as 0) (setq as 0))
|
||
(setq xoff (- rbearing ce)
|
||
yoff (if (> as 0) 0 (+ descent as))))
|
||
((= class 208)
|
||
(setq xoff (- lbearing rb)))
|
||
((= class 210)
|
||
(setq xoff (- rbearing lb)))
|
||
((= class 212)
|
||
(setq xoff (- lbearing ce)
|
||
yoff (if (>= de 0) 0 (- (- ascent) de))))
|
||
((= class 214)
|
||
(setq xoff (- center ce)
|
||
yoff (if (>= de 0) 0 (- (- ascent) de))))
|
||
((= class 216)
|
||
(setq xoff (- rbearing ce)
|
||
yoff (if (>= de 0) 0 (- (- ascent) de))))
|
||
((= class 218)
|
||
(setq xoff (- lbearing ce)
|
||
yoff (if (> as 0) 0 (+ descent as gap))))
|
||
((= class 220)
|
||
(setq xoff (- center ce)
|
||
yoff (if (> as 0) 0 (+ descent as gap))))
|
||
((= class 222)
|
||
(setq xoff (- rbearing ce)
|
||
yoff (if (> as 0) 0 (+ descent as gap))))
|
||
((= class 224)
|
||
(setq xoff (- lbearing rb)))
|
||
((= class 226)
|
||
(setq xoff (- rbearing lb)))
|
||
((= class 228)
|
||
(setq xoff (- lbearing ce)
|
||
yoff (if (>= de 0) 0 (- (- ascent) de gap))))
|
||
((= class 230)
|
||
(setq xoff (- center ce)
|
||
yoff (if (>= de 0) 0 (- (- ascent) de gap))))
|
||
((= class 232)
|
||
(setq xoff (- rbearing ce)
|
||
yoff (if (>= de 0) 0 (- (+ ascent de) gap)))))
|
||
(lglyph-set-adjustment glyph (- xoff width) yoff)
|
||
(setq lb (+ lb xoff)
|
||
rb (+ lb xoff)
|
||
as (- as yoff)
|
||
de (+ de yoff)))
|
||
((and (= class 0)
|
||
(eq (get-char-code-property (lglyph-char glyph)
|
||
;; Me = enclosing mark
|
||
'general-category)
|
||
'Me))
|
||
;; Artificially laying out glyphs in an enclosing
|
||
;; mark is difficult. All we can do is to adjust
|
||
;; the x-offset and width of the base glyph to
|
||
;; align it at the center of the glyph of the
|
||
;; enclosing mark hoping that the enclosing mark
|
||
;; is big enough. We also have to adjust the
|
||
;; x-offset and width of the mark itself properly
|
||
;; depending on how the glyph is designed.
|
||
|
||
;; (non-spacing or not). For instance, when we
|
||
;; have these glyphs:
|
||
;; X position |
|
||
;; base: <-*-> lbearing=0 rbearing=5 width=5
|
||
;; mark: <----------.> lb=-11 rb=2 w=0
|
||
;; we get a correct layout by moving them as this:
|
||
;; base: <-*-> XOFF=4 WAD=9
|
||
;; mark: <----------.> xoff=2 wad=4
|
||
;; we have moved the base to the left by 4-pixel
|
||
;; and make its width 9-pixel, then move the mark
|
||
;; to the left 2-pixel and make its width 4-pixel.
|
||
(let* (;; Adjustment for the base glyph
|
||
(XOFF (/ (- rb lb width) 2))
|
||
(WAD (+ width XOFF))
|
||
;; Adjustment for the enclosing mark glyph
|
||
(xoff (- (+ lb WAD)))
|
||
(wad (- rb lb WAD)))
|
||
(lglyph-set-adjustment glyph xoff 0 wad)
|
||
(setq glyph (lgstring-glyph gstring 0))
|
||
(lglyph-set-adjustment glyph XOFF 0 WAD))))
|
||
(if (< ascent as)
|
||
(setq ascent as))
|
||
(if (< descent de)
|
||
(setq descent de))))))
|
||
(let ((i 0))
|
||
(while (and (< i nglyphs) (setq glyph (lgstring-glyph gstring i)))
|
||
(lglyph-set-from-to glyph 0 (1- nchars))
|
||
(setq i (1+ i))))
|
||
gstring))))))
|
||
|
||
(defun compose-gstring-for-dotted-circle (gstring direction)
|
||
(let* ((dc (lgstring-glyph gstring 0)) ; glyph of dotted-circle
|
||
(fc (lgstring-glyph gstring 1)) ; glyph of the following char
|
||
(gstr (and nil (font-shape-gstring gstring direction))))
|
||
(if (and gstr
|
||
(or (= (lgstring-glyph-len gstr) 1)
|
||
(and (= (lgstring-glyph-len gstr) 2)
|
||
(= (lglyph-to (lgstring-glyph gstr 0))
|
||
(lglyph-to (lgstring-glyph gstr 1))))))
|
||
;; It seems that font-shape-gstring has composed glyphs.
|
||
gstr
|
||
;; Artificially compose the following glyph with the preceding
|
||
;; dotted-circle.
|
||
(setq dc (lgstring-glyph gstring 0)
|
||
fc (lgstring-glyph gstring 1))
|
||
(let ((dc-width (lglyph-width dc))
|
||
(fc-width (- (lglyph-rbearing fc) (lglyph-lbearing fc)))
|
||
(from (lglyph-from dc))
|
||
(to (lglyph-to fc))
|
||
(xoff 0) (yoff 0) (width 0))
|
||
(if (and (< (lglyph-descent fc) 0)
|
||
(> (lglyph-ascent dc) (- (lglyph-descent fc))))
|
||
;; Set YOFF so that the following glyph is put on top of
|
||
;; the dotted-circle.
|
||
(setq yoff (- (- (lglyph-descent fc)) (lglyph-ascent dc))))
|
||
(if (> (lglyph-width fc) 0)
|
||
(setq xoff (- (lglyph-rbearing fc))))
|
||
(if (< dc-width fc-width)
|
||
;; The following glyph is wider, but we don't know how to
|
||
;; align both glyphs. So, try the easiest method;
|
||
;; i.e. align left edges of the glyphs.
|
||
(setq xoff (- xoff (- dc-width) (- (lglyph-lbearing fc )))
|
||
width (- fc-width dc-width)))
|
||
(if (or (/= xoff 0) (/= yoff 0) (/= width 0) (/= (lglyph-width fc) 0))
|
||
(lglyph-set-adjustment fc xoff yoff width))
|
||
(lglyph-set-from-to dc from to)
|
||
(lglyph-set-from-to fc from to))
|
||
(if (> (lgstring-glyph-len gstring) 2)
|
||
(lgstring-set-glyph gstring 2 nil))
|
||
gstring)))
|
||
|
||
;; Allow for bootstrapping without uni-*.el.
|
||
(when unicode-category-table
|
||
(let ((elt `([,(purecopy "\\c.\\c^+") 1 compose-gstring-for-graphic]
|
||
[nil 0 compose-gstring-for-graphic])))
|
||
(map-char-table
|
||
#'(lambda (key val)
|
||
(if (memq val '(Mn Mc Me))
|
||
(set-char-table-range composition-function-table key elt)))
|
||
unicode-category-table))
|
||
;; for dotted-circle
|
||
(aset composition-function-table #x25CC
|
||
`([,(purecopy ".\\c^") 0 compose-gstring-for-dotted-circle]))
|
||
;; For prettier display of fractions
|
||
(set-char-table-range
|
||
composition-function-table
|
||
#x2044
|
||
;; We use font-shape-gstring so that if the font doesn't support
|
||
;; fractional display, the characters are shown separately, not as
|
||
;; a composed cluster.
|
||
(list (vector (purecopy "[1-9][0-9][0-9]\u2044[0-9]+")
|
||
3 'font-shape-gstring)
|
||
(vector (purecopy "[1-9][0-9]\u2044[0-9]+") 2 'font-shape-gstring)
|
||
(vector (purecopy "[1-9]\u2044[0-9]+") 1 'font-shape-gstring))))
|
||
|
||
(defun compose-gstring-for-terminal (gstring _direction)
|
||
"Compose glyph-string GSTRING for terminal display.
|
||
Non-spacing characters are composed with the preceding base
|
||
character. If the preceding character is not a base character,
|
||
each non-spacing character is composed as a spacing character by
|
||
prepending a space before it."
|
||
(let ((nglyphs (lgstring-glyph-len gstring))
|
||
(i 0)
|
||
(coding (lgstring-font gstring))
|
||
glyph)
|
||
(while (and (< i nglyphs)
|
||
(setq glyph (lgstring-glyph gstring i)))
|
||
(if (not (char-charset (lglyph-char glyph) coding))
|
||
(progn
|
||
;; As the terminal doesn't support this glyph, return a
|
||
;; gstring in which each glyph is its own grapheme-cluster
|
||
;; of width 1..
|
||
(setq i 0)
|
||
(while (and (< i nglyphs)
|
||
(setq glyph (lgstring-glyph gstring i)))
|
||
(if (< (lglyph-width glyph) 1)
|
||
(lglyph-set-width glyph 1))
|
||
(lglyph-set-from-to glyph i i)
|
||
(setq i (1+ i))))
|
||
(if (= (lglyph-width glyph) 0)
|
||
(if (eq (get-char-code-property (lglyph-char glyph)
|
||
'general-category)
|
||
'Cf)
|
||
(progn
|
||
;; Compose Cf (format) control characters by
|
||
;; replacing with a space.
|
||
(lglyph-set-char glyph 32)
|
||
(lglyph-set-width glyph 1)
|
||
(setq i (1+ i)))
|
||
;; Compose by prepending a space.
|
||
(setq gstring (lgstring-insert-glyph gstring i
|
||
(lglyph-copy glyph))
|
||
nglyphs (lgstring-glyph-len gstring))
|
||
(setq glyph (lgstring-glyph gstring i))
|
||
(lglyph-set-char glyph 32)
|
||
(lglyph-set-width glyph 1)
|
||
(setq i (+ 2)))
|
||
(let ((from (lglyph-from glyph))
|
||
(to (lglyph-to glyph))
|
||
(j (1+ i)))
|
||
(while (and (< j nglyphs)
|
||
(setq glyph (lgstring-glyph gstring j))
|
||
(char-charset (lglyph-char glyph) coding)
|
||
(= (lglyph-width glyph) 0))
|
||
(setq to (lglyph-to glyph)
|
||
j (1+ j)))
|
||
(while (< i j)
|
||
(setq glyph (lgstring-glyph gstring i))
|
||
(lglyph-set-from-to glyph from to)
|
||
(setq i (1+ i)))))))
|
||
gstring))
|
||
|
||
(defun compose-gstring-for-variation-glyph (gstring _direction)
|
||
"Compose glyph-string GSTRING for graphic display.
|
||
GSTRING must have two glyphs; the first is a glyph for a han character,
|
||
and the second is a glyph for a variation selector."
|
||
(let* ((font (lgstring-font gstring))
|
||
(han (lgstring-char gstring 0))
|
||
(vs (lgstring-char gstring 1))
|
||
(glyphs (font-variation-glyphs font han))
|
||
(g0 (lgstring-glyph gstring 0))
|
||
(g1 (lgstring-glyph gstring 1)))
|
||
(catch 'tag
|
||
(dolist (elt glyphs)
|
||
(if (= (car elt) vs)
|
||
(progn
|
||
(lglyph-set-code g0 (cdr elt))
|
||
(lglyph-set-from-to g0 (lglyph-from g0) (lglyph-to g1))
|
||
(lgstring-set-glyph gstring 1 nil)
|
||
(throw 'tag gstring)))))))
|
||
|
||
;; We explicitly don't handle #xFE0F (VS-16) here, because that's
|
||
;; taken care of by font_range in font.c, which will check for an
|
||
;; emoji font for codepoints used in compositions even if they're not
|
||
;; emoji themselves, and thus choose the Emoji presentation for them
|
||
;; when followed by VS-16. VS-15 *is* handled here, because if it's
|
||
;; handled in font_range, we end up choosing the Emoji presentation
|
||
;; rather than the Text presentation.
|
||
(let ((elt '([".." 1 compose-gstring-for-variation-glyph])))
|
||
(set-char-table-range composition-function-table '(#xFE00 . #xFE0E) elt)
|
||
(set-char-table-range composition-function-table '(#xE0100 . #xE01EF) elt))
|
||
|
||
(defun auto-compose-chars (func from to font-object string direction)
|
||
"Compose the characters at FROM by FUNC.
|
||
FUNC is called with two arguments: GSTRING, which is built for
|
||
characters in the region FROM (inclusive) and TO (exclusive);
|
||
and DIRECTION, which is the bidi directionality of the characters.
|
||
|
||
If the character are composed on a graphic display, FONT-OBJECT
|
||
is a font to use. Otherwise, FONT-OBJECT is nil, and the function
|
||
`compose-gstring-for-terminal' is used instead of FUNC.
|
||
|
||
If STRING is non-nil, it is a string, and FROM and TO are indices
|
||
into the string. In that case, compose characters in the string.
|
||
|
||
The value is a gstring containing information for shaping the characters.
|
||
|
||
This function is the default value of `auto-composition-function' (which see)."
|
||
(let ((gstring (composition-get-gstring from to font-object string)))
|
||
(if (lgstring-shaped-p gstring)
|
||
gstring
|
||
(or (fontp font-object 'font-object)
|
||
(setq func 'compose-gstring-for-terminal))
|
||
(funcall func gstring direction))))
|
||
|
||
(put 'auto-composition-mode 'permanent-local t)
|
||
|
||
(make-variable-buffer-local 'auto-composition-function)
|
||
(setq-default auto-composition-function 'auto-compose-chars)
|
||
|
||
;;;###autoload
|
||
(define-minor-mode auto-composition-mode
|
||
"Toggle Auto Composition mode.
|
||
|
||
When Auto Composition mode is enabled, text characters are
|
||
automatically composed by functions registered in
|
||
`composition-function-table'.
|
||
|
||
You can use `global-auto-composition-mode' to turn on
|
||
Auto Composition mode in all buffers (this is the default)."
|
||
;; It's defined in C, this stops the d-m-m macro defining it again.
|
||
:variable auto-composition-mode)
|
||
;; It's not defined with DEFVAR_PER_BUFFER though.
|
||
(make-variable-buffer-local 'auto-composition-mode)
|
||
|
||
;;;###autoload
|
||
(define-minor-mode global-auto-composition-mode
|
||
"Toggle Auto Composition mode in all buffers.
|
||
|
||
For more information on Auto Composition mode, see
|
||
`auto-composition-mode'."
|
||
:global t
|
||
:variable (default-value 'auto-composition-mode))
|
||
|
||
(defalias 'toggle-auto-composition 'auto-composition-mode)
|
||
|
||
(provide 'composite)
|
||
|
||
;;; composite.el ends here
|