This section describes X11R6.9-specific enhancements to the core X11 fonts system.
The scalable font backends (Type 1 and TrueType) can
automatically re-encode fonts to the encoding specified in the
XLFD in `fonts.dir'. For example, a `fonts.dir' file can
contain entries for the Type 1 Courier font such as
cour.pfa -adobe-courier-medium-r-normal--0-0-0-0-m-0-iso8859-1
cour.pfa -adobe-courier-medium-r-normal--0-0-0-0-m-0-iso8859-2
Two of the scalable backends (Type 1 and the FreeType TrueType backend) use a common fontenc layer for font re-encoding. This allows these backends to share their encoding data, and allows simple configuration of new locales independently of font type.
Please note: the X-TrueType (X-TT) backend is not included in X11R6.9. That functionality has been merged into the FreeType backend.>
In the fontenc layer, an encoding is defined by a name (such as
iso8859-1), possibly a number of aliases (alternate names), and
an ordered collection of mappings. A mapping defines the way the
encoding can be mapped into one of the target encodings known to
fontenc; currently, these consist of Unicode, Adobe glyph names,
and arbitrary TrueType ``cmap''s.
A number of encodings are hardwired into fontenc, and are therefore always available; the hardcoded encodings cannot easily be redefined. These include:
iso10646-1: Unicode;iso8859-1: ISO Latin-1 (Western Europe);iso8859-2: ISO Latin-2 (Eastern Europe);iso8859-3: ISO Latin-3 (Southern Europe);iso8859-4: ISO Latin-4 (Northern Europe);iso8859-5: ISO Cyrillic;iso8859-6: ISO Arabic;iso8859-7: ISO Greek;iso8859-8: ISO Hebrew;iso8859-9: ISO Latin-5 (Turkish);iso8859-10: ISO Latin-6 (Nordic);iso8859-15: ISO Latin-9, or Latin-0 (Revised
Western-European);koi8-r: KOI8 Russian;koi8-u: KOI8 Ukrainian (see RFC 2319);koi8-ru: KOI8 Russian/Ukrainian;koi8-uni: KOI8 ``Unified'' (Russian, Ukrainian, and
Byelorussian);koi8-e: KOI8 ``European,'' ISO-IR-111, or ECMA-Cyrillic;microsoft-symbol and apple-roman: these are only
likely to be useful with TrueType symbol fonts.Additional encodings can be added by defining encoding files.
When a font encoding is requested that the fontenc layer doesn't
know about, the backend checks the directory in which the font file
resides (not necessarily the directory with fonts.dir!) for a
file named `encodings.dir'. If found, this file is scanned for
the requested encoding, and the relevant encoding definition file is
read in. The `mkfontdir' utility, when invoked with the
`-e' option followed by the name of a directory containing
encoding files, can be used to automatically build `encodings.dir'
files. Please see the mkfontdir(1)
manual page for more details.
A number of encoding files for common encodings are included with X11R6.9. Information on writing new encoding files can be found in Format of encodings directory files and Format of encoding files later in this document.
For TrueType and OpenType fonts, the FreeType backend scans the mappings in order. Mappings with a target of PostScript are ignored; mappings with a TrueType or Unicode target are checked against all the cmaps in the file. The first applicable mapping is used.
For Type 1 fonts, the FreeType backend first searches for a mapping with a target of PostScript. If one is found, it is used. Otherwise, the backend searches for a mapping with target Unicode, which is then composed with a built-in table mapping codes to glyph names. Note that this table only covers part of the Unicode code points that have been assigned names by Adobe.
Specifying an encoding value of adobe-fontspecific for a
Type 1 font disables the encoding mechanism. This is useful with
symbol and incorrectly encoded fonts (see
Incorrectly encoded fonts below).
If a suitable mapping is not found, the FreeType backend defaults to ISO 8859-1.
The Type 1 backend behaves similarly to the FreeType backend with Type 1 fonts, except that it limits all encodings to 8-bit codes.
In order to use a font in an encoding that the font backend does
not know about, you need to have an `encodings.dir' file either
in the same directory as the font file used or in a system-wide
location (`/usr/X11R6/lib/X11/fonts/encodings/' by default).
The `encodings.dir' file has a similar format to
`fonts.dir'. Its first line specifies the number of encodings,
while every successive line has two columns, the name of the encoding,
and the name of the encoding file; this can be relative to the current
directory, or absolute. Every encoding name should agree with the
encoding name defined in the encoding file. For example,
3
mulearabic-0 /usr/X11R6/lib/X11/fonts/encodings/mulearabic-0.enc
mulearabic-1 /usr/X11R6/lib/X11/fonts/encodings/mulearabic-1.enc
mulearabic-2 /usr/X11R6/lib/X11/fonts/encodings/mulearabic-2.enc
The name of an encoding must be specified in the encoding file's
`STARTENCODING' or `ALIAS' line. It is not enough to create
an `encodings.dir' entry.
If your platform supports it (it probably does), encoding files may be compressed or gzipped.
The `encoding.dir' files are best maintained by the
`mkfontdir' utility. Please see the mkfontdir(1) manual page for more information.
The encoding files are ``free form,'' i.e. any string of
whitespace is equivalent to a single space. Keywords are parsed in a
non-case-sensitive manner, meaning that `size', `SIZE', and
`SiZE' all parse as the same keyword; on the other hand, case is
significant in glyph names.
Numbers can be written in decimal, as in `256', in hexadecimal,
as in `0x100', or in octal, as in `0400'.
Comments are introduced by a hash sign `#'. A `#' may
appear at any point in a line, and all characters following the
`#' are ignored, up to the end of the line.
The encoding file starts with the definition of the name of the encoding, and possibly its alternate names (aliases):
STARTENCODING mulearabic-0
ALIAS arabic-0
-'.
The encoding file may then optionally declare the size of the encoding. For a linear encoding (such as ISO 8859-1), the SIZE line specifies the maximum code plus one:
SIZE 0x2B
jisx0208.1990-0'
(JIS X 0208(1990), double-byte encoding, high bit clear), it
should be
SIZE 0x75 0x80
FIRSTINDEX' line may be
included to specify the minimum glyph index in an encoding. The
keyword `FIRSTINDEX' is followed by two integers, the minimum row
number followed by the minimum column number:
FIRSTINDEX 0x20 0x20
FIRSTINDEX' line is not very
useful. If for some reason however you chose to include on, it should
be followed by a single integer.
Note that in most font backends inclusion of a `FIRSTINDEX' line
has the side effect of disabling default glyph generation, and this
keyword should therefore be avoided unless absolutely necessary.
Codes outside the region defined by the `SIZE' and
`FIRSTINDEX' lines are understood to be undefined. Encodings
default to linear encoding with a size of 256 (0x100). This means
that you must declare the size of all 16 bit encodings.
What follows is one or more mapping sections. A mapping section
starts with a `STARTMAPPING' line stating the target of the mapping.
The target may be one of:
STARTMAPPING unicode
STARTMAPPING cmap 3 1
STARTMAPPING postscript
0x21 0x0660
0x22 0x0661
...
<it/start/ <it/end/ <it/target/
start target
start+1 target+1
...
end target+end-start
0x2121 0x215F 0x8140
0x2121 0x8140
0x2122 0x8141
...
0x215F 0x817E
UNDEFINE' line:
UNDEFINE 0x00 0x2A
UNDEFINE 0x1234
PostScript mappings are different. Every line in a PostScript mapping maps a code to a glyph name
0x41 A
0x42 B
...
A mapping section ends with an ENDMAPPING line
ENDMAPPING
ENDENCODING line
ENDENCODING
In order to make future extensions to the format possible, lines starting with an unknown keyword are silently ignored, as are mapping sections with an unknown target.
Type 1 symbol fonts should be installed using the
adobe-fontspecific encoding.
In an ideal world, all TrueType symbol fonts would be installed using
one of the microsoft-symbol and apple-roman encodings. A
number of symbol fonts, however, are not marked as such; such fonts
should be installed using microsoft-cp1252, or, for older fonts,
microsoft-win3.1.
In order to guarantee consistent results (especially between
Type 1 and TrueType versions of the same font), it is possible to
define a special encoding for a given font. This has already been done
for the ZapfDingbats font; see the file
`encodings/adobe-dingbats.enc'.
A number of text fonts are incorrectly encoded. Incorrect encoding is sometimes done by design, in order to make a font for an exotic script appear like an ordinary Western text font on systems which are not easily extended with new locale data. It is often the result of the font designer's laziness or incompetence; for some reason, most people seem to find it easier to invent idiosyncratic glyph names rather than follow the Adobe glyph list.
There are two ways of dealing with such fonts: using them with the encoding they were designed for, and creating an ad hoc encoding file.
In the case of Type 1 fonts, the font designer can specify a
default encoding; this encoding is requested by using the
`adobe-fontspecific' encoding in the XLFD name. Sometimes, the
font designer omitted to specify a reasonable default encoding, in
which case you should experiment with `adobe-standard',
`iso8859-1', `microsoft-cp1252', and
`microsoft-win3.1'. (The encoding `microsoft-symbol' doesn't
make sense for Type 1 fonts).
TrueType fonts do not have a default encoding. However, most TrueType
fonts are designed with either Microsoft or Apple platforms in mind,
so one of `microsoft-symbol', `microsoft-cp1252',
`microsoft-win3.1', or `apple-roman' should yield reasonable
results.
It is always possible to define an encoding file to put the glyphs
in a font in any desired order. Again, see the
`encodings/adobe-dingbats.enc' file to see how this is done.
By following the directions above, you will find yourself with a
number of fonts with unusual names --- with encodings such as
`adobe-fontspecific', `microsoft-win3.1' etc. In order
to use these fonts with standard applications, it may be useful to
remap them to their proper names.
This is done by writing a `fonts.alias' file. The format of this file
is very simple: it consists of a series of lines each mapping an alias
name to a font name. A `fonts.alias' file might look as follows:
"-ogonki-alamakota-medium-r-normal--0-0-0-0-p-0-iso8859-2" \
"-ogonki-alamakota-medium-r-normal--0-0-0-0-p-0-adobe-fontspecific"
fonts.alias' file is more precisely described in the
mkfontdir(1) manual page.
The FreeType (libfreetype-xtt2) backend (module `freetype',
formerly known as xfsft) is able to deal with both TrueType and
Type 1 fonts. This puts it in conflict with the X-TT and Type 1
backends respectively.
If both the FreeType and the Type 1 backends are loaded, the FreeType backend will be used for Type 1 fonts. If both the FreeType and X-TT backends are loaded, X-TT will be used for TrueType fonts.
The FreeType (libfreetype-xtt2) backend (formerly xfsft)
is a backend based on version 2 of the FreeType library (see the FreeType web site) and has
the X-TT functionalities for CJKV support provided by the After X-TT
Project (see the After X-TT Project web site). The FreeType module has support for the
``fontenc'' style of internationalisation (see
The fontenc layer). This backend supports TrueType font files
(`*.ttf'), OpenType font files (`*.otf'), TrueType Collections
(`*.ttc'), OpenType Collections (`*.otc') and Type 1 font
files (`*.pfa' and `*.pfb').
In order to access the faces in a TrueType Collection file, the face number must be specified in the fonts.dir file before the filename, within a pair of colons, or by setting the 'fn' TTCap option. For example,
:1:mincho.ttc -misc-pmincho-medium-r-normal--0-0-0-0-p-0-jisx0208.1990-0
refers to face 1 in the `mincho.ttc' TrueType Collection file.
The new FreeType backend supports the extended
`fonts.dir' syntax introduced by X-TrueType with a number
of options, collectively known as `TTCap'. A `TTCap' entry follows the
general syntax
option=value:
and should be specified before the filename. The new FreeType
almost perfectly supports TTCap options that are compatible with X-TT
1.4. The Automatic Italic (`ai'), Double Strike (`ds') and
Bounding box Width (`bw') options are indispensable in CJKV.
For example,
mincho.ttc -misc-mincho-medium-r-normal--0-0-0-0-c-0-jisx0208.1990-0
ds=y:mincho.ttc -misc-mincho-bold-r-normal--0-0-0-0-c-0-jisx0208.1990-0
ai=0.2:mincho.ttc -misc-mincho-medium-i-normal--0-0-0-0-c-0-jisx0208.1990-0
ds=y:ai=0.2:mincho.ttc -misc-mincho-bold-i-normal--0-0-0-0-c-0-jisx0208.1990-0
bw=0.5:mincho.ttc -misc-mincho-medium-r-normal--0-0-0-0-c-0-jisx0201.1976-0
bw=0.5:ds=y:mincho.ttc -misc-mincho-bold-r-normal--0-0-0-0-c-0-jisx0201.1976-0
bw=0.5:ai=0.2:mincho.ttc -misc-mincho-medium-i-normal--0-0-0-0-c-0-jisx0201.1976-0
bw=0.5:ds=y:ai=0.2:mincho.ttc -misc-mincho-bold-i-normal--0-0-0-0-c-0-jisx0201.1976-0
setup the complete combination of jisx0208 and jisx0201 using mincho.ttc only. More information on the TTCap syntax is found on the After X-TT Project page.
The FreeType backend uses the fontenc layer in order to support recoding of fonts; this was described in The fontenc layer and especially FreeType-specific notes about fontenc earlier in this document.
The `X-TrueType' backend is a backend based on version 1 of the FreeType library. X-TrueType doesn't use the `fontenc' layer for managing font encodings, but instead uses its own database of encodings.
Since the functionalities for CJKV support introduced by X-TT have been merged into the new FreeType backend, the X-TT backend will be removed from X11R6.9's tree near the future. Therefore, the use of FreeType backend is preferred over the X-TT backend.
General information on X-TrueType may be found at the After X-TT Project page.
When loading a proportional fonts which contain a huge number of glyphs,
the old FreeType delayed glyph rasterisation until the time at which
the glyph was first used. The new FreeType (libfreetype-xtt2) has an
improved `very lazy' metric calculation method to speed up the process when
loading TrueType or OpenType fonts. Although the X-TT module also
has this method, the "vl=y" TTCap option must be set if you want to
use it. This is the default method for FreeType when it loads
multi-byte fonts. Even if you use a unicode font which has tens of
thousands of glyphs, this delay will not be worrisome as long as you use
the new FreeType backend -- its `very lazy' method is super-fast.
The maximum error of bitmap position using `very lazy' method is 1 pixel,
and is the same as that of a character-cell spacing. When the X-TT
backend is used with the `vl=y' option, a chipped bitmap is displayed
with certain fonts. However, the new FreeType backend has minimal problem
with this, since it corrects left- and right-side bearings using
`italicAngle' in the TrueType/OpenType post table, and does automatic
correction of bitmap positions when rasterisation so that chipped bitmaps
are not displayed. Nevertheless if you don't want to use the `very lazy'
method when using multi-bytes fonts, set `vl=n' in the TTCap option to
disable it:
vl=n:luxirr.ttf -b&h-Luxi Serif-medium-r-normal--0-0-0-0-p-0-iso10646-1
Of course, both backends also support an optimisation for character-cell
fonts (fonts with all glyph metrics equal, or terminal fonts). A font
with an XLFD specifying a character-cell spacing `c', as in
-misc-mincho-medium-r-normal--0-0-0-0-c-0-jisx0208.1990-0
or
fs=c:mincho.ttc -misc-mincho-medium-r-normal--0-0-0-0-p-0-jisx0208.1990-0
will not compute the metric for each glyph, but instead trust the font to be a character-cell font. You are encouraged to make use of this optimisation when useful, but be warned that not all monospaced fonts are character-cell fonts.