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OpenType™ Feature File Specification

Copyright 2015-2021 Adobe. All Rights Reserved. This software is licensed as OpenSource, under the Apache License, Version 2.0. This license is available at: http://opensource.org/licenses/Apache-2.0.

Document version 1.26 Last updated 7 June 2021

Caution: Portions of the syntax unimplemented by Adobe are subject to change.

Contents

1. Introduction

An OpenType feature file is a text file that contains the typographic layout feature specifications for an OpenType font in an easy-to-read format. It may also contain override values for certain fields in the font tables. It is read in during the creation or editing of an OpenType font. This document specifies the feature file grammar.

This is an example of a complete feature file:

# Script and language coverage
languagesystem DFLT dflt;
languagesystem latn dflt;

# Ligature formation
feature liga {
    substitute f i by f_i;
    substitute f l by f_l;
} liga;

# Kerning
feature kern {
    position A Y -100;
    position a y -80;
    position s f' <0 0 10 0> t;
} kern;

This file specifies the formation of the “f_i” and “f_l” ligatures, and the kern values of the glyph pairs “A” “Y” and “a” “y”. It also specifies a contextual positioning adjustment for “f” when preceded by “s” and followed by “t”. It also specifies that all features will be applied under all languages in the latn script, and for all scripts not named in the feature file.

Note: All “Implementation Notes” and “Currently not implemented” comments in the rest of the specification below refer to the Adobe implementation of the feature file grammar in the makeotf program, unless otherwise indicated.

2. Syntax

2.a. Comments

The # character indicates the start of a comment; the comment extends until the end of the line. Text on a line after the comment is discarded before processing.

2.b. White space

White space is not significant except for delimiting tokens. You can have multiple line endings, spaces, and tabs between tokens. Macintosh, UNIX and PC line endings are all supported.

2.c. Keywords

This is a complete list of keywords in the feature file language. Note that all keywords have a global scope. Although many keywords may be used only in specific contexts, the same keyword is never used in different ways in different contexts.

anchor
anchorDef
anon
anonymous
by
contourpoint
cursive
device [ Not implemented ]
enum
enumerate
exclude_dflt
feature (used as a block and as a statement)
from
ignore (used with substitute and position)
IgnoreBaseGlyphs
IgnoreLigatures
IgnoreMarks
include
include_dflt
language
languagesystem
lookup
lookupflag
mark (can also be used as a tag or lookup block label)
MarkAttachmentType
markClass
nameid
NULL (used in substitute, device, value record, anchor)
parameters
pos
position
required [ Not implemented ]
reversesub
RightToLeft
rsub
script
sub
substitute
subtable
table
useExtension
UseMarkFilteringSet
valueRecordDef
excludeDFLT (deprecated)
includeDFLT (deprecated)

The following keywords are currently specific to these corresponding table/feature blocks:

keyword table implemented
HorizAxis.BaseScriptList BASE table
HorizAxis.BaseTagList BASE table
HorizAxis.MinMax BASE table
VertAxis.BaseScriptList BASE table
VertAxis.BaseTagList BASE table
VertAxis.MinMax BASE table
Attach GDEF table
GlyphClassDef GDEF table
LigatureCaretByDev GDEF table
LigatureCaretByIndex GDEF table
LigatureCaretByPos GDEF table
FontRevision head table
Ascender hhea table
CaretOffset hhea table
Descender hhea table
LineGap hhea table
CapHeight OS/2 table
CodePageRange OS/2 table
Panose OS/2 table
TypoAscender OS/2 table
TypoDescender OS/2 table
TypoLineGap OS/2 table
UnicodeRange OS/2 table
Vendor OS/2 table
winAscent OS/2 table
winDescent OS/2 table
XHeight OS/2 table
sizemenuname size feature
VertTypoAscender vhea table
VertTypoDescender vhea table
VertTypoLineGap vhea table
VertAdvanceY vmtx table
VertOriginY vmtx table
ElidedFallbackName STAT table
ElidedFallbackNameID STAT table
DesignAxis STAT table
AxisValue STAT table
flag STAT table
location STAT table
ElidableAxisValueName STAT table
OlderSiblingFontAttribute STAT table

The following are keywords only where a tag is expected:

DFLT  # can be used only with the script keyword and as the script value with the languagesystem keyword.
dflt  # can be used only with the language keyword and as the language value with the languagesystem keyword.

2.d. Special characters

#    pound sign       Denotes start of comment
;    semicolon        Terminates a statement
,    comma            Separator in various lists
@    at sign          Identifies glyph class names
\    backslash        Identifies CIDs. Distinguishes glyph names from an identical keyword
-    hyphen           Denotes glyph ranges in a glyph class
=    equal sign       Glyph class assignment operator
'    single quote     Marks a glyph or glyph class for contextual substitution or positioning
" "  double quotes    Enclose a name table string
{ }  braces           Enclose a feature, lookup, table, or anonymous block
[ ]  square brackets  Enclose components of a glyph class
< >  angle brackets   Enclose a device, value record, contour point, anchor, or caret
( )  parentheses      Enclose the file name to be included

2.e. Numbers and other metrics

2.e.i. Number

A <number> is a signed decimal integer (without leading zeros). For example:

-150
1000

It is used in device tables [§2.e.iii] and contour points [§2.e.vi], as well as the values of various table fields [§9].

2.e.ii. Metric

A <metric> value is simply a <number> in font design units. It is used in value records [§2.e.iv] for positioning rules, as well as to express the values of various table fields [§9].

[ Note: Multiple master support has been withdrawn as of OpenType specification 1.3. ]

2.e.iii. Device table [ Currently not implemented. ]

A <device> represents a single device table or a null offset to it. It is used in value records [§2.e.iv], anchors [§2.e.vii], and the GDEF table LigatureCaret statements [§9.b].

Device format A:

This specifies a comma-separated list of <number> pairs. The first <number> in a pair represents a ppem size and the second the number of pixels to adjust at that ppem size:

<device <number> <number>,   # ppem size, number of pixels to adjust
       (<number> <number>)>; # zero or more such pairs

For example:

<device 11 -1, 12 -1>  # Adjust by -1 at 11 ppem and 12 ppem
Device format B, the null device:
<device NULL>

This format is used when an undefined <device> is needed in a list of <device> tables.

2.e.iv. Value record

A <valuerecord> is used in some positioning rules [§6].

Except for format A, a <valuerecord> must be enclosed by angle brackets. Note that the <metric> adjustments indicate values (in design units) to add to (positive values) or subtract from (negative values) the placement and advance values provided in the font (in the hmtx and vmtx tables).

Value record format A:
<metric>  # Angle brackets around value are not allowed.

Here the <metric> represents an x advance adjustment, except when used in the vkrn, vpal, vhal, or valt features, in which case it represents a y advance adjustment. All other adjustments are implicitly set to 0. This is the simplest feature file <valuerecord> format, and is provided since it represents the most commonly used adjustment (i.e. for kerning). For example:

-3  # without <>

Note that the use of a single value as y advance can only be triggered when the value record definition is contained within a vkrn, vpal, vhal, or valt feature definition. If it is in a standalone lookup, then the value will be interpreted as an x advance, even if the lookup is referenced from within one of the vertical metric features.

Value record format B:
<<metric> <metric> <metric> <metric>>

Here, the <metric> values represent adjustments for x placement, y placement, x advance, and y advance, in that order. For example:

<-80 0 -160 0>       # x placement adjustment: -80; x advance adjustment: -160
Value record format C: [ Currently not implemented. ]
<<metric> <metric> <metric> <metric> <device> <device> <device> <device>>

Here, the <metric> values represent the same adjustments as in format B. The <device> values represent device tables [§2.e.iii] for x placement, y placement, x advance, and y advance, in that order. This format lets the editor express the full functionality of an OpenType value record. For example:

<-80 0 -160 0 <device 11 -1, 12 -1>
              <device NULL>

              <device 11 -2, 12 -2>
              <device NULL>>

This example specifies adjustments for x placement and x advance, as well as device adjustments at 11 and 12 ppem sizes for x placement and x advance.

Value record format D, the null value record: [ Currently not implemented. ]
<NULL> # Value record not defined
Value record format E, the named value record:
<name>

For example:

<KERN_POS_1>

The name must have been defined with a valueRecordDef statement before being used.

2.e.v. Named value record

The valueRecordDef keyword is used to define a named value record. This name can then be used in value records instead of coordinates. It offers the advantage of being able to change the coordinates in the named value record definition only, and having that single edit change the coordinates used in all the rules in which the named value record is used. The format is:

valueRecordDef <coordinates> name;

where the coordinates can be in value record formats A or B. The anchor name follows the same rules as are used to form glyph names. For example:

valueRecordDef -10 FIRST_KERN;
valueRecordDef <0 0 20 0> SECOND_KERN;

These named value coordinates can then be used in value records. For example:

pos T V <SECOND_KERN>;

Note that when the value record name is used, it must be enclosed by angle brackets, whether it is a single value or four value record. The valueRecordDef is a top level statement, and must be defined outside of feature blocks. It also must be defined before it is used.

2.e.vi. Contour point

A <contour point> is used in anchors [§2.e.vii] and the GDEF table LigatureCaret statements [§9.b]. It takes the format:

contourpoint <number>

where <number> specifies a contour point index. For example:

contourpoint 2

Note: Since OpenType-CFF fonts do not specify contour point indexes, a <contour point> may be used only with TrueType OpenType fonts.

2.e.vii. Anchor

An <anchor> is used in some positioning rules [§6]. It takes 5 formats:

Anchor format A:
<anchor <metric> <metric>>  # x coordinate, y coordinate

For example:

<anchor 120 -20>
Anchor format B:
<anchor <metric> <metric>  # x coordinate, y coordinate
        <contour point>>

For example:

<anchor 120 -20 contourpoint 5>
Anchor format C:
<anchor <metric> <metric>   # x coordinate, y coordinate
        <device> <device>>  # x coordinate device, y coordinate device

For example:

<anchor 120 -20 <device 11 1> <device NULL>>
Anchor format D, the null anchor:
<anchor NULL> # Anchor not defined
Anchor format E, the named anchor:
<anchor <name>>

For example:

<anchor TOP_ANCHOR_1>

An anchor name must be defined before it is used – see the following section on the anchorDef keyword.

2.e.viii. Named anchor definition

The anchorDef keyword is used to define a named anchor. This name can then be used in anchor definitions instead of coordinates. It offers the advantage of being able to change the coordinates in the named anchor definition only, and having that single edit change the coordinates used in all the rules in which the named anchor is used. The format is:

anchorDef <coordinates> <name>;

where the coordinates can be in Anchor Format A or B. The anchor name follows the same rules as are used to form glyph names. For example:

anchorDef 300 0 ANCHOR_1;
anchorDef 120 -20 contourpoint 5 ANCHOR_2;

These named anchors can then be used in anchor definitions. For example:

<anchor ANCHOR_2>

2.f. Glyphs

These are represented by one of:

2.f.i. Glyph name

There are two different contexts for glyph naming: final production names and development names.

For production glyph names, names that are used in shipping font files, the specification is set by the PostScript and Type1 specifications, which define what is expected by existing PostScript interpreters. These limitations are as follows.

A glyph name may be up to 63 characters in length, must be entirely comprised of characters from the following set:

ABCDEFGHIJKLMNOPQRSTUVWXYZ
abcdefghijklmnopqrstuvwxyz
0123456789
.  # period
_  # underscore

and must not start with a digit or period. The only exception is the special character “.notdef”.

“twocents”, “a1”, and “_” are valid glyph names. “2cents” and “.twocents” are “not.

Development glyph names, names used in source data during the development of a font, have a larger supported character set. In addition to the characters allowed for production glyph names, the following characters must also be supported for development glyph names:

U+002A * Asterisk
U+002B + Plus sign
U+002D - Hyphen-minus
U+003A : Colon
U+005E ^ Circumflex accent
U+007C | Vertical bar
U+007E ~ Tilde

However, none of these characters are allowed at the start of a glyph name.

For glyphs where the development glyph name differs from the final production glyph name, an implementation of the feature file syntax must be able to accept either name in source files, but must produce output data which contains either only development glyph names or only final production glyph names.

A glyph name alias database may be used by the implementation of the feature file grammar to map from development glyph names in the source font data to final production glyph names. If it is used, then it is the responsibility of the implementation to correlate the development glyph names used in the feature file with the final glyph names in the font.

In order disambiguate whether a text token is a range argument or a glyph name which contains a hyphen, the implementation should first assume that the token is a glyph name. If there is no glyph in the source data with a name that matches the token, then the implementation should interpret the token as a range argument.

An initial backslash serves to differentiate a glyph name from an identical keyword in the feature file language. (See §2.c for a list of keywords.) For example, a glyph named “table” must be specified in the feature file as:

\table

2.f.ii. CID

CIDs are represented by a non-negative <number>2.e.i] preceded by a backslash. For example:

\101
\0

2.g. Glyph classes

Note: The feature file glyph classes described in this section are not to be confused with glyph classes of OpenType Layout ClassDefs. The latter are described in the chapter “Common Table Formats” in the OpenType specification.

A feature file glyph class, <glyphclass>, represents a single glyph position in a sequence and is denoted by a list of glyphs enclosed in square brackets. For example:

[endash emdash figuredash]

An example of a sequence which contains a glyph class is:

space [endash emdash figuredash] space

This would match any of the 3 sequences “space endash space”, “space emdash space”, or “space figuredash space” during OpenType layout.

A feature file glyph class that contains only one single glyph is known as a singleton glyph class.

A feature file glyph class is also used to represent the set of alternate glyphs in an alternate substitution lookup type rule.

2.g.i. Ranges

A glyph range is a notational mechanism in the feature file grammar that makes it possible to define a class of several glyphs is a concise way. The mechanism makes use of glyph names that use a contiguous alphabetic sequence A to Z or a to z (or sub-sequences thereof), or that use contiguous numeric sequences, such as 0 to 9. A range is specified by referencing starting and ending glyph names, and all of the glyph names in the implied sequence are included in the class. The glyphs referenced by these names do not have to be in a contiguous sequence in a font file or sources; only their names need to be in a contiguous sequence.

If a glyph name within the implied sequence does not correspond to a glyph in the font file or font sources, it is ignored.

A range of glyphs is denoted by a hyphen:

[<firstGlyph> - <lastGlyph>]

Spaces around the hyphen are not required, so these are also valid ranges:

[\0-\31]
[A-Z]

For CID fonts, the ordering is the CID ordering.

For non-CID fonts, the ordering is independent of the ordering of glyphs in the font. <firstGlyph> and <lastGlyph> must be the same length and can differ only in one of the following ways:

  1. By a single letter from A-Z, either uppercase or lowercase. For example:

    [A.swash - Z.swash]
    [a - z]
    

    The range is expanded by incrementing the letter that differs, while keeping the rest of the glyph name the same.

  2. By up to 3 decimal digits in a contiguous run. For example:

    [ampersand.01 - ampersand.58]
    

    The range is expanded by incrementing the number values, while keeping the rest of the glyph name the same.

    [ampersand.1 - ampersand.58]  # invalid
    

    is not a valid glyph class since the length of the glyph names differ.

Note that

[zero - nine]

is not a valid glyph range, as the intended range is not in alphabetic order. It must be enumerated explicitly:

@digits = [zero one two three four five six seven eight nine];

2.g.ii. Named glyph classes

A glyph class can be named by assigning it to a glyph class name, which begins with the “@” character, and then referred to later on by the glyph class name. For example:

@dash = [endash emdash figuredash];     # Assignment
space @dash space                       # Usage

The part of the glyph class name after the “@” is subject to the same name restrictions that apply to a production glyph name except that hyphens are also allowed.

Glyph class assignments can appear anywhere in the feature file. A glyph class name may be used in the feature file only after its definition.

When a glyph class name occurs within square brackets, its elements are simply added onto the other elements in the glyph class being defined. For example:

@Vowels.lc = [a e i o u];
@Vowels.uc = [A E I O U];
@Vowels = [@Vowels.lc @Vowels.uc y Y];

Here the last statement is equivalent to:

@Vowels = [a e i o u A E I O U y Y];

No square brackets are needed if a glyph class name is assigned to another single glyph class name. For example:

@Figures_lining_tabular = @FIGSDEFAULT;

Ranges, glyphs, and glyph class names can be combined in a glyph class. For example:

[A.oldstyle - Z.oldstyle ampersand.oldstyle  @smallCaps]

Implementation note: When feature file glyph sequences (including glyph classes) are converted into OpenType Layout ClassDefs or Coverages in the font, the Adobe implementation ensures that ClassDefs or Coverages that are identical are shared, even if they are in different features. This happens regardless of whether ranges, glyphs or glyph class names were used to express the feature file glyph classes. (The only exception to this is for lookups that use the Extension lookup types: such lookups will not share their ClassDefs and Coverages with non-extension lookups.)

2.h. Tags

Tags are four-letter identifiers. These are denoted simply by tag name, without any final spaces, and are distinguished from glyph names by context. For example:

DEU

Note that the final space in the example is implicit.

A tag can only have characters from the following set:

ABCDEFGHIJKLMNOPQRSTUVWXYZ
abcdefghijklmnopqrstuvwxyz
0123456789
.  # period
_  # underscore
!  # Exclamation point
$  # Dollar sign
%  # Percent sign
&  # Ampersand
*  # Asterisk
+  # Plus sign
:  # Colon
?  # Question mark
^  # Caret
'  # Back-quote
|  # Vertical bar
~  # Tilde

and must not start with a digit or hyphen. However, use of characters beyond those in production glyph names is not recommended.

The keyword mark is a valid tag but other (short) keywords are not. The special language tag dflt denotes the default language system of the corresponding script.

2.i. Lookup block labels

The same length and name restrictions that apply to a production glyph name apply to a lookup block label. For historical reasons the keyword `mark’ also accepted as a label but other keywords are not.

3. Including files

Including files is indicated by the directive:

include(<filename>);

For example:

include(../family.fea);

An include directive is valid in any context that otherwise contains statements ending in semicolons: “Top-level” statements; feature, lookup, table, cvParameter, and AxisValue blocks; and name groups. (An implementation that processes include statements at the token level is not required to enforce these restrictions.)

The implementation software is responsible for handling the search paths for the location of the included files.

Because of variations in implementations over time, a relative include path should be resolved in the order described below; the first which matches should be used.

  1. If the source font is UFO format, then relative to the UFO’s font directory
  2. relative to the top-level include file
  3. relative to the parent include file

A maximum include depth of 50 ensures against infinite include loops (files that include each other).

4. Specifying features

4.a. feature

Each feature is specified in a feature block:

feature <feature tag> {
    # specifications go here
} <feature tag>;

For example:

feature liga {
    # ...
} liga;

The aalt feature is treated specially; see §8.a. For example, the useExtension keyword may optionally precede { in its feature block syntax, and other features can be referred to with a feature statement within its feature block. The size feature is also treated specially; see §8.b.

A feature file “rule” is a statement that specifies glyph substitution or glyph positioning. A feature block may contain glyph substitution rules [§5], glyph positioning rules [§6], or both.

A lookup is a group of rules of the same type. See §4.e.

4.b. Language system

An OpenType language system is any combination of a script tag and a language tag. (In the text of this document, the notation <script tag>/<language tag> is used to refer to a language system; for example, script latn/language dflt denotes the default language of the Latin script.)

The lookups in every OpenType feature must be registered under one or more language systems. The lookups of a particular feature may vary across the language systems under which the feature is registered.

There are two ways to specify language system in the feature file: with the languagesystem keyword outside of feature definition blocks, and by the script and language keywords within feature definition blocks.

4.b.i. languagesystem

In practice, most or all of the features in a font will be registered under the same set of language systems, and a particular feature’s lookups will be identical across the language systems under which the feature is registered.

The languagesystem statement provides a simple directive to use in this case. It is the simplest way to specify language system in the feature file. (For the aalt and size features, it is the only way to specify language system.) One or more such statements may be present in the feature file at global scope (i.e. outside of the feature blocks or any other blocks) and before any of the feature blocks:

languagesystem <script tag> <language tag>;

When these statements are present, then all the lookups in each feature that does not contain an explicit script or language statement (see 4.b.ii below) will be registered under every language system specified by the languagesystem statement(s). If a feature block does contain script or language tags, then all lookups that occur before the first script or language tag will also be applied under all the specified language systems.

If no languagesystem statement is present, then the implementation must behave exactly as though the following statement were present at the beginning of the feature file:

languagesystem DFLT dflt;

If any languagesystem statement is used, then the statement specifying:

languagesystem DFLT dflt;

must be specified explicitly; if not, this language system will not be included in the font. This script/language pair is special: it is used if a program cannot find a match in the font to the current writing script and language. If it is not in your font, then all the rules may be invisible to the program if your font does not have a match for the current script and language. It is strongly recommended to use the statement languagesystem DFLT dflt;.

If the statement languagesystem DFLT dflt; is present, it must be the first of the languagesystem statements. Any other language statements using the DFLT script tag must precede all other language statements.

Please see example 1 in §4.h below.

4.b.ii. script and language

Occasionally a feature may need to be specified whose lookups vary across the language systems of the feature, or whose language systems vary from the set of language systems of the rest of the features in the file, as specified by the languagesystem statements. In these cases, script and language statements will need to be used within the feature block itself. Such statements affect only that feature. Note: you may not use the script or language keywords within a standalone lookup block.

Rules that are specified after the start of a feature and before the first script and/or language statement will be included in all the language systems specified by the languagesystem statements. If you do not want any of the rules in the feature to be registered under the language systems specified by the languagesystem statements, then a script and/or language statement for a script must be present before the first rule in the feature.

Once the first script or language statement occurs within a feature block, subsequent lookups and rules are registered only within the currently specified script and language. To register a rule or lookup under more than one script and language, you must explicitly include it following each script and language specification.

The one exception to this rule are the default lookups. There are two levels of default lookups. Rules specified between the start of a feature definition and the first script are added to all language-systems, unless a language statement specifies the exclude_dflt keyword. Rules specified between the occurrence of the script statement and the first language statement other than dflt are added to explicitly specified languages for the current script, but not to other scripts, nor to other languages of the same script that are not named in the feature. If your font has several languages for a given script, and you need language specific rules for only some of the languages, you should still explicitly name all of the languages so that they will inherit the script-level default rules.

The current script and language attributes may be changed as follows:

script statement:
script <script tag>;

For example:

script kana;

When a script statement is seen, the language attribute is implicitly set to dflt, and the lookupflag attribute is implicitly set to 0. The script attribute stays the same until explicitly changed by another script statement or until the end of the feature.

language statement:

The language attribute stays the same until explicitly changed, until the script is changed, or until the end of the feature. To change the language attribute, use the language statement:

language <language tag> [exclude_dflt|include_dflt] [required];

To exclude a set of rules from only one or a few languages, you must define the set of rules as a lookup, and explicitly include the lookup in under the languages that should include it, and omit it from the rules included under the languages where it should be excluded.

Note: the excludeDFLT and includeDFLT keywords still work, but are deprecated and will cause a warning to appear.

Here is an example statement:

language DEU;

As a result of this statement, (a) the language attribute is changed to DEU , and (b) the current default lookups are automatically included into the language system specified by the current script and language DEU.

If (b) is not desired, as may occasionally be the case, then the keyword exclude_dflt must follow the language tag. For example:

language DEU exclude_dflt;

The keyword include_dflt may be used to explicitly indicate the default default lookup-inheriting behavior. For example:

language DEU include_dflt;
# Same as:    language DEU;

The keyword required, when present, specifies the current feature as the required feature for the specified language system.

[ The keyword required is currently not implemented. ]

Since the aalt and size features are treated specially, script and language statements are not allowed within these features.

Special notes:

Please see §4.h below for detailed examples.

4.c. parameters

The parameters statement specifies the feature parameters for the currently defined language system. It is currently supported only for the size, ssXX, and cvXX features; see § 8.b, 8.c and 8.d.

4.d. lookupflag

The chapter “Common Table Formats” in the OpenType specification describes the LookupFlag field in the Lookup table.

The lookupflag attribute defaults to 0 at the start of a feature or named lookup block.

The lookupflag attribute stays the same until explicitly changed, until a lookup reference statement is encountered that changes it, until the script is changed, or until the end of the feature.

To change the lookupflag attribute explicitly, use the lookupflag statement, which takes two formats:

lookupflag format A:
lookupflag <named lookupflag value> (<named lookupflag value>)*;

Here, the individual lookup flag values to be set are expressed in a list of one or more <named lookupflag value>s, in no particular order, separated by spaces. A <named lookupflag value> is one of the following:

RightToLeft
IgnoreBaseGlyphs
IgnoreLigatures
IgnoreMarks
MarkAttachmentType <glyphclass|glyphclass name>
UseMarkFilteringSet <glyphclass|glyphclass name>

At most one of each of the above 6 kinds of <named lookupflag> values may be present in a lookupflag statement. For example, to skip over base glyphs and ligature glyphs:

lookupflag IgnoreBaseGlyphs IgnoreLigatures;

Base, ligature, and mark glyphs are specified in the glyph class definition of the GDEF table.

To skip over all mark glyphs except for those of mark class @TOP_MARKS:

lookupflag MarkAttachmentType @TOP_MARKS;

The class name used with MarkAttachmentType can be either a regular glyph class name or a mark class name. The glyph sets of the referenced classes must not overlap, and the MarkAttachmentType statement can reference at most 15 different classes.

The flag UseMarkFilteringSet was added in OpenType spec 1.6. This works the same as the MarkAttachmentType, but allows you to use up to 16K different mark classes, and allows the glyph sets of the referenced classes to overlap.

MarkAttachmentType and UseMarkFilteringSet can also use glyph classes directly, with the same restrictions as above.

lookupflag UseMarkFilteringSet [acute grave];
lookupflag format B:
lookupflag <number>;

Here the entire lookup flag value is specified simply as a <number>. The format A example above could equivalently be expressed as:

lookupflag 6;

Format A is clearly a superior choice for human readability when the lookupflag value is not 0. However, a lookupflag value of 0 can be set only with format B, not with format A:

lookupflag 0;

The base glyphs, ligatures, and mark classes are defined in the GlyphClassDef of the GDEF table block [§9.b].

4.e. lookup

A lookup is a group of rules of the same type. The font editor can label a run of rules and refer to it explicitly later on, in order to have different parts of the font tables refer to the same lookup. This decreases the size of the font in addition to freeing the editor from maintaining duplicate sets of rules.

A lookup in the OpenType font will be created from each named lookup block or each run of rules with the same feature, script, language, lookupflag and lookup type attribute.

To define and label a lookup, use a named lookup block:

lookup <label> [useExtension] {
    # rules to be grouped
} <label>;

A named lookup block may be defined either inside or outside of a feature block. In either case, it may be referenced in different feature blocks. If it is defined outside a feature block, is is referred to as a ‘standalone’ lookup.

The lookup will be created with a GSUB or GPOS Extension lookup type if and only if the optional useExtension keyword is used.

A lookup block may be defined either inside or outside of feature blocks. Note: you may not use the script or language keywords within a standalone lookup block.

The useExtension keyword has two effects: all the records of all types that are referenced by a lookup qualifier are placed in one contiguous block of data, and the offset to the lookup may be 32 bits rather than limited to 16 bits.

When your font cannot be built because of an offset overflow error (meaning that the offset from one record to another record exceeds the 64 Kbyte limit imposed by the maximum size possible for a 16-bit offset field), then add this qualifier to the largest lookup. Keep adding it to more lookups until your font will build.

(Note: Extension lookup types were added in OpenType specification v1.3).

(See also §8.a for how to specify the entire aalt feature be made with the Extension lookup type.)

To refer to the lookup later on, use a lookup reference statement:

lookup <label>;

For example:

lookup SHARED {      # lookup definition
    # ...
} SHARED;

# ...
lookup SHARED;       # lookup reference

An example of a lookup that uses the Extension lookup type:

lookup EXTENDED_KERNING useExtension {       # lookup definition
    # ...
} EXTENDED_KERNING;

# ...
lookup EXTENDED_KERNING;    # lookup reference. useExtension not needed

Since the labeled block literally defines a single lookup in the font, the rules within the lookup block must be of the same lookup type and have the same lookupflag attribute. A lookup block may not contain any other kind of block. The order of lookups within a font is defined by the order of the lookup definitions in the feature file.

For contextual rules, the rules of the lookup are ordered in the font file in the same order that they are written in the feature file. For non-contextual rules, the implementation sorts the rules to avoid conflict; for example, the ligature substitution rule for f_f_i will be written before the ligature substitution rule for f_i, no matter what their order is in the feature file.

4.f. markClass

The markClass keyword is used to identify a mark glyph class definition statement.

A mark glyph class name is defined differently than a regular glyph class. The mark class definition is built up by a one or more of statements in the form:

markClass <glyph|glyphclass> <anchor> <mark glyph class name>;

Each additional mark statement for a mark class adds the referenced glyphs to that mark class.

The <anchor>2.e.vii] indicates the point on the mark glyph(s) by which it is attached to a matching anchor point on a base glyph. If a mark glyph has an anchor point at <anchor 300, 0> and the base glyph has an anchor point at <anchor 400 300>, then the mark glyph will be shifted so that the point x = 300, y = 0 in its design space will be superimposed on the point x = 300, y = 400 in the design space of the base glyph.

For example:

markClass [acute grave dieresis] <anchor 350 0> @MARK_TOP_ACCENTS;

If all the mark glyphs which belong to a mark class have the same anchor, then the mark class can be defined with a single statement, as above. However, a single mark statement can define only a single anchor point, so when glyphs in a mark class have different anchor points, more than one mark statement must be used to define the mark class. For example:

markClass [acute grave] <anchor 350 0> @MARK_TOP_ACCENTS;
markClass [dieresis umlaut] <anchor 400 0> @MARK_TOP_ACCENTS;

Note: All mark class definition statements must precede any use of a mark class in the feature file. Once any position statement has referenced a mark class, no more mark statements are allowed.

Note: The mark classes used within a single lookup must be disjoint: none may include a glyph which is in another mark class that is used within the same lookup.

Note: If a GDEF table is not explicitly defined in the feature file, then an implementation of this syntax will create one. In this case, it will use the set of defined mark classes to define the mark glyphs for the GDEF GlyphClass. In this case, the assignment of a glyph to the GDEF GlyphClass mark class may conflict with other assignments to the other GDEF GlyphClass classes. In this case, an implementation should warn the user of the conflict.

The set of mark classes has an implicit order. An implementation should order the mark classes in the order of occurrence of the first definition statement for a mark glyph class. In the example:

markClass [acute grave] <anchor 350 0> @MARK_TOP_ACCENTS;
markClass [cedilla hook] <anchor 300 0> @MARK_BOTTOM_ACCENTS;
markClass [dieresis umlaut] <anchor 400 0> @MARK_TOP_ACCENTS;

the mark class order will be:

@MARK_TOP_ACCENTS # mark class index 0
@MARK_BOTTOM_ACCENTS # mark class index 1

4.g. subtable

The feature file implementation must insert subtable breaks among the rules for a particular lookup if needed. For example, if a set of alternate substitution rules specified in the feature file exceeds the subtable size limit, several subtables must be automatically created.

The subtable statement may be used as follows:

subtable;

to explicitly force a subtable break after the previous rule.

This statement must be respected in Pair Adjustment Positioning Format 2 (i.e. pair class kerning) but in other cases may be ignored and the implementation software may insert its own subtable breaks. See 6.b.iii for details. This hint to the compiler is required for class kerning, as it is difficult for a compiler to determine where to best place a subtable break in this lookup type, in order to reduce lookup size.

4.h. Examples

Example 1:

The following is an example of an entire feature file and demonstrates the two ways to register features under language systems (see §4.b above):

languagesystem DFLT dflt;
languagesystem latn dflt;
languagesystem latn DEU;
languagesystem latn TRK;
languagesystem cyrl dflt;

feature smcp {
    sub [a-z] by [A.sc-Z.sc];
    # Since all the rules in this feature are of the same type, they will be grouped in a single lookup.
    # Since no script or language keyword has been specified yet,
    # the lookup will be registered for this feature under all the language systems.
} smcp;

feature liga {
    sub f f by f_f;
    sub f i by f_i;
    sub f l by f_l;
    # Since all the rules in this feature are of the same type, they will be
    # grouped in a single lookup.
    # Since no script or language keyword has been specified yet,
    # the lookup will be registered for this feature under all the language systems.

    script latn;
        language dflt;
        # lookupflag 0;      (implicit)
            sub c t by c_t;
            sub c s by c_s;
        # The rules above will be placed in a lookup that is registered for all
        # the specified languages for the script latn, but not any other scripts.

        language DEU;
        # script latn;       (stays the same)
        # lookupflag 0;      (stays the same)
            sub c h by c_h;
            sub c k by c_k;
        # The rules above will be placed in a lookup that is registered only
        # under the script 'latn', 'language DEU'.

        language TRK;
        # This will inherit both the top level default rules - the rules defined
        # before the first 'script' statement, and the script-level default
        # rules for 'latn: all the lookups of this feature defined after the
        # 'script latn' statement, and before the 'language DEU' statement.
        # If 'TRK' were not named here, it would not inherit the default rules
        # for the script 'latn'.
} liga;

feature kern {
    pos a y -150;
    # [more pos statements]
    # All the rules in this feature will be grouped in a single lookup
    # that is registered under all the languagesystems.
} kern;

In the above example feature file, the smcp and kern features will be registered under the DFLT/dflt, latn/dflt, latn/DEU , latn/TRK and cyrl/dflt language systems since no explicit script or language statements are present in those features.

In the liga feature, the f_f, f_i and f_l ligature substitutions will be applied under all language systems. The c_t and c_s ligature substitutions will be applied under all languages of the script latn, but not under any other scripts. The c_h and c_k ligature substitutions will be applied when the language is German (i.e. they are registered only under latn/DEU ).

Example 2:

The following example illustrates labeled lookup blocks and the use of the exclude_dflt keyword:

languagesystem DFLT dflt;
languagesystem latn dflt;
languagesystem latn DEU;
languagesystem cyrl dflt;
languagesystem cyrl SRB;
languagesystem grek dflt;

feature liga {
    # start of default rules that are applied under all language systems.
    lookup HAS_I {
        sub f f i by f_f_i;
        sub f i by f_i;
    } HAS_I;

    lookup NO_I {
        sub f f l by f_f_l;
        sub f f by f_f;
    } NO_I;

    # end of default rules that are applied under all language systems.

    script latn;
        language dflt;
        # default lookup for latn included under all languages for the latn script
        sub f l by f_l;

        language DEU;
        # default lookups included under the DEU language.
        sub c h by c_h;
        sub c k by c_k;

        language TRK exclude_dflt;   # default lookups are excluded.
            lookup NO_I;             # Only this lookup is included under the TRK language

    script cyrl;
        language SRB;
            sub c t by c_t; # this rule will apply only under script cyrl language SRB.
} liga;

Note that if you specify no explicit rules or lookup references after a script and language statement, then the effect is to include all the default rules for all scripts for the feature. Note also that lookup HAS_I must be placed before lookup NO_I since the f_f_i substitution must precede the f_f substitution when both are applied. (See 7: Ordering of lookups and rules in the feature file).

The ordering of ligature rules within a particular lookup does not matter, excepting contextual rules, as the implementation will sort non-contextual rules in order to avoid conflict. For example, in lookup HAS_I, the f_i substitution may be placed before the f_f_i substitution, because the implementation will sort the f_f_i substitution first when writing the lookup to the font. (See 5.d: Ligature substitution).

5. Glyph substitution (GSUB) rules

Glyph substitution rules begin with the keyword substitute; this keyword may be abbreviated as sub. (The ignore keyword may precede the substitute keyword in some cases.) The GSUB lookup type is auto-detected from the format of the rest of the rule.

5.a. [GSUB LookupType 1] Single substitution

A Single Sub rule is specified in one of the following formats:

substitute <glyph> by <glyph>;            # format A
substitute <glyphclass> by <glyph>;       # format B
substitute <glyphclass> by <glyphclass>;  # format C

Format B specifies that any glyph in the target glyph class must be replaced by the same replacement glyph.

Format C specifies that any of the glyphs in the target glyph class must be replaced by its corresponding glyph (in the order of glyphs in the glyph classes) in the replacement glyph class. If the replacement is a singleton glyph class, then the rule will be treated identically to a format B rule. If the replacement class has more than one glyph, then the number of elements in the target and replacement glyph classes must be the same.

For example:

sub a by A.sc;                                                 # format A
substitute [one.fitted one.oldstyle one.tab.oldstyle] by one;  # format B
substitute [a - z] by [A.sc - Z.sc];                           # format C
substitute @Capitals by @CapSwashes;                           # format C

The third line in the above example produces an identical representation in the font as:

substitute a by A.sc;
substitute b by B.sc;
substitute c by C.sc;
# ...
substitute z by Z.sc;

If the replacement glyph is the reserved word NULL, then the substitution has no replacement, removing the input glyph from the glyph sequence:

substitute a by NULL;

Omitting the by clause is equivalent to adding by NULL.

5.b. [GSUB LookupType 2] Multiple substitution

A Multiple Sub rule is specified as:

substitute <glyph> by <glyph sequence>;

<glyph sequence> contains two or more glyphs. It may not contain glyph classes. (If it did, the rule would be ambiguous as to which replacement sequence were required.) For example:

substitute f_f_i by f f i;            # Ligature decomposition

5.c. [GSUB LookupType 3] Alternate substitution

An Alternate Sub rule is specified as:

substitute <glyph> from <glyphclass>;

For example:

substitute ampersand from [ampersand.1 ampersand.2 ampersand.3];

5.d. [GSUB LookupType 4] Ligature substitution

A Ligature Sub rule is specified as:

substitute <glyph sequence> by <glyph>;

<glyph sequence> must contain two or more of <glyph|glyphclass>. For example:

substitute [one one.oldstyle] [slash fraction] [two two.oldstyle] by onehalf;

Since the OpenType specification does not allow ligature substitutions to be specified on target sequences that contain glyph classes, the implementation software will enumerate all specific glyph sequences if glyph classes are detected in <glyph sequence>. Thus, the above example produces an identical representation in the font as if all the sequences were manually enumerated by the font editor:

substitute  one           slash     two           by  onehalf;
substitute  one.oldstyle  slash     two           by  onehalf;
substitute  one           fraction  two           by  onehalf;
substitute  one.oldstyle  fraction  two           by  onehalf;
substitute  one           slash     two.oldstyle  by  onehalf;
substitute  one.oldstyle  slash     two.oldstyle  by  onehalf;
substitute  one           fraction  two.oldstyle  by  onehalf;
substitute  one.oldstyle  fraction  two.oldstyle  by  onehalf;

A contiguous set of ligature rules does not need to be ordered in any particular way by the font editor; the implementation software must do the appropriate sorting. So:

sub f f     by f_f;
sub f i     by f_i;
sub f f i   by f_f_i;
sub o f f i by o_f_f_i;

will produce an identical representation in the font as:

sub o f f i by o_f_f_i;
sub f f i   by f_f_i;
sub f f     by f_f;
sub f i     by f_i;

5.e. [GSUB LookupType 5] Contextual substitution

This LookupType is a functional subset of GSUB LookupType 6, chaining contextual substitution. Thus, all desired rules of this LookupType can be expressed in terms of chaining contextual substitution rules.

5.f. [GSUB LookupType 6] Chaining contextual substitution

5.f.i. Specifying a Chain Sub rule and marking sub-runs

A Chain Substitution rule target sequence has three parts: backtrack, input, and lookahead glyph sequences. A glyph sequence comprises one or more glyphs or glyph classes.

The most important is input glyph sequence. This is the sequence of glyphs and glyph classes to which substitution operations are applied. Optionally, a prefix (also known as backtrack) glyph sequence may be specified, as well as a suffix (also known as lookahead) glyph sequence. The entire sequence of glyphs — prefix plus input plus suffix — must match in the current context for the rule to be applied. The match sequence is aligned to the current context by aligning the first glyph of the input sequence with the current glyph of the text being processed. If the rule is matched, then the current context moves the current glyph pointer ahead in the original text by the length of the input sequence. Note that in the FEA syntax, the entire context string (backtrack sequence + input sequence + look-ahead sequence) are all written in the text string order. This is worth emphasis, as inside the lookup rule, the glyphs of the backtrack sequence are written in reverse order from the text to be matched. Developers of font editing tools who know this are sometimes confused by the FEA syntax.

For each glyph or glyph class in the input sequence, the contextual rule may specify one or more lookups (§4.e) to be applied at that position. Note that the specified lookups may contain many rules; the implementation must ensure that only one rule in a referenced lookup will match at that position in the input sequence. Lookups cannot be specified for the glyphs or glyph classes in the backtrack and lookahead sequences.

The input sequence is defined by appending the mark (') character to all the glyph names and class names within the input sequence.

The most general form of the contextual substitution rule is to explicitly reference named lookups in the rule.

Example 1:

Define two standalone lookups (§4.e), and then reference them in the input sequence of contextual substitution rules with the keyword lookup and the lookup name.

lookup CNTXT_LIGS {
    substitute f i by f_i;
    substitute c t by c_t;
} CNTXT_LIGS;

lookup CNTXT_SUB {
    substitute n by n.end;
    substitute s by s.end;
} CNTXT_SUB;

feature test {
    substitute [ a e i o u] f' lookup CNTXT_LIGS i' n' lookup CNTXT_SUB;
    substitute [ a e i o u] c' lookup CNTXT_LIGS t' s' lookup CNTXT_SUB;
} test;

Note that both the contextual substitution rules use the same lookups. This is because there is more than one rule in each referenced lookup, and different rules within the referenced lookups will match in the different contexts. In the first contextual substitution rule, the lookup CNTXT_LIGS will be applied at the input sequence glyph “f”, and the glyphs “f” and “i” will be replaced by “f_i”. The lookup CNTXT_SUB will be applied at the input sequence glyph “n”, and the glyph “n” will be replaced by “n.end”. This will happen only when the sequence “f i n” is preceded by any one of the glyphs “a e i o u”. Likewise, in the second contextual substitution rule the glyphs “c” and “t” will be replaced by “c_t”, and the glyph “s” will be replaced by “s.end”. This will happen only when the sequence “c t s” is preceded by any one of the glyphs “a e i o u”.

This form of the contextual substitution rule is the most flexible. You can specify a substitution lookup for more than one input sequence glyph or glyph class, the referenced lookups can be of different types, and the referenced lookups can have different lookup flags that the parent contextual lookup. The drawback is that it is difficult to understand what substitution rule will be applied, and the implementation may not warn if the referenced lookup does not contain a rule that matches the context.

If there is only a single substitution operation, and it is either single substitution or ligature substitution, then the operation can be specified in-line and its type will be auto-detected from the input and replacement sequence in the same way as in their corresponding standalone (i.e. non-contextual) statements.

Example 2:

This calls a Single Sub rule. The rule below means: in sequences “a d” or “e d” or “n d”, substitute “d” by “d.alt”.

substitute [a e n] d' by d.alt;

This format requires that there be only one glyph or glyph class in the input sequence.

Example 3:

This also calls a Single Sub rule. The rule below means: if a capital letter is followed by a small capital, then replace the small capital by its corresponding lowercase letter.

substitute [A-Z] [A.sc-Z.sc]' by [a-z];

This format requires that there be only one glyph or glyph class in the input sequence.

Example 4:

This calls a Ligature Sub lookup. The rule below means: in sequences “e t c” or “e.begin t c”, substitute the first two glyphs by the ampersand.

substitute [e e.begin]' t' c by ampersand;

This format will assume that the entire input sequence is a sequence of ligature components.

Example 5:

In this example two Multiple Sub lookups are applied to the same input. The rule below means: in lookup REORDER_CHAIN the sequence “ka ka.pas_cakra.ns” is first substituted by “ka” and then a second lookup substitutes the remaining “ka” by the sequence “ka.pas_cakra ka”.

lookup REMOVE_CAKRA {
    sub ka ka.pas_cakra.ns by ka;
} REMOVE_CAKRA;

lookup REORDER_CAKRA {
    sub ka by ka.pas_cakra ka;
} REORDER_CAKRA;

lookup REORDER_CHAIN {
    sub ka' lookup REMOVE_CAKRA lookup REORDER_CAKRA ka.pas_cakra.ns' ;
} REORDER_CHAIN;

5.f.ii. Specifying exceptions to the Chain Sub rule

Exceptions to a chaining contextual substitution rule are expressed by inserting a statement of the following form anywhere before the chaining contextual rule and in the same lookup as it:

ignore substitute <backtrack glyph sequence>*
<marked glyph sequence>
<lookahead glyph sequence>*;

The backtrack and lookahead sequences may be omitted, but there must be at least one marked glyph or glyph class.

For convenience, several ignore statements may be collapsed into one by separating the matching sequences with a comma. See Example 3. The following three statements:

ignore substitute <match sequence1>;
ignore substitute <match sequence2>;
ignore substitute <match sequence3>;

can be written as:

ignore substitute <match sequence1>, <match sequence2>, <match sequence3>;

Note that each match sequence is in effect a complete ignore statement, and contains its own independent backtrack, marked glyph, and lookahead sequences.

The ignore substitute statement works by creating subtables in the GSUB that tell the OT layout engine simply to match the specified sequences, and not to perform any substitutions on them. As a result of the match, remaining rules (i.e. subtables) in the lookup will be skipped when the rule matches. (See OT layout algorithm.)

Example 1:

Ignoring specific sequences: The ignore substitute rules below will block any subsequent rules that specify a substitution for “d” when the context around “d” matches any of the sequences “f a d”, “f e d”, or “a d d”.

Note that the marked glyphs in the exception sequences indicate where a substitution would have occurred; this is necessary for the OpenType layout engine to correctly handle skipping this sequence.

ignore substitute f [a e] d';
ignore substitute a d' d;
substitute [a e n] d' by d.alt;

Matching a beginning-of-word boundary:

Example 2:
ignore substitute @LETTER f' i';
substitute f' i' by f_i.begin;

The example above shows how a ligature may be substituted at a word boundary. @LETTER must be defined to include all glyphs considered to be part of a word. The substitute statement will get applied only if the sequence doesn’t match “@LETTER f i”; i.e. only at the beginning of a word.

Example 3:

Matching a whole word boundary:

ignore substitute @LETTER a' n' d', a' n' d' @LETTER;
substitute a' n' d' by a_n_d;

In this example, the a_n_d ligature will apply only if the sequence “a n d” is neither preceded nor succeeded by a @LETTER. Also, note the use of the comma in the ignore statement: this is equivalent to writing:

ignore substitute @LETTER a' n' d';
ignore substitute a' n' d' @LETTER;
substitute a' n' d' by a_n_d;
Example 4:

This shows a specification for the contextual swashes feature:

feature cswh {

    # --- Glyph classes used in this feature:
    @BEGINNINGS = [A-N P-Z Th m];
    @BEGINNINGS_SWASH = [A.swash-N.swash P.swash-Z.swash T_h.swash m.begin];
    @ENDINGS = [a e z];
    @ENDINGS_SWASH = [a.end e.end z.end];

    # --- Beginning-of-word swashes:
    ignore substitute @LETTER @BEGINNINGS';
    substitute @BEGINNINGS' by @BEGINNINGS_SWASH;

    # --- End-of-word swashes:
    ignore substitute @ENDINGS' @LETTER;
    substitute @ENDINGS' by @ENDINGS_SWASH;

} cswh;

If a feature only targets glyphs at the beginning or ending of a word, such as the init and fina features, then the application could be made responsible for detecting the word boundary; the feature itself would be simply defined as the appropriate substitutions without regard for word boundary. Such application responsibilities must be described in the feature tag registry.

5.g. [GSUB LookupType 7] Extension substitution

The useExtension keyword specifies creating lookups of this lookup type. See §4.e and §8.a.

5.h. [GSUB LookupType 8] Reverse Chaining Single Substitution

A Reverse Chaining Single Substitution shares the same syntax as a Chaining Contextual Substitution rule. The syntactic differences are that it can specify only single substitutions, the marked target sequence can consist of only a single glyph or glyph class, and the rule is specified with the keyword reversesub or rsub. An application’s layout engine will also treat this rule differently than any other rule type; the lookup is applied to the text string in the reverse of the logical reading order.

The rule is specified as follows:

reversesub [a e n] d' by d.alt;

As with substitute, if the replacement glyph is the reserved word NULL then the reverse substitution has no replacement, removing the glyph from the sequence. Omitting the by clause is equivalent to adding by NULL.

6. Glyph positioning (GPOS) rules

Glyph positioning rules begin with the keyword position; this keyword may be abbreviated as pos. (The enumerate or ignore keywords may precede the position keyword in some cases.) The GPOS lookup type is auto-detected from the format of the rest of the rule.

Glyph positioning is specified in terms of metrics [§2.e.ii], device tables [§2.e.iii], value records [§2.e.iv], and anchors [§2.e.vii]. In all positioning rules, these are inserted immediately after the glyph(s) they apply to, with the exception of Pair Pos format B.

6.a. [GPOS LookupType 1] Single adjustment positioning

A Single Pos rule is specified as:

position <glyph|glyphclass> <valuerecord>;

Here, the <glyph|glyphclass> is adjusted by the <valuerecord>2.e.iv]. For example, to reduce the left and right side-bearings of a glyph each by 80 design units:

position one <-80 0 -160 0>;

6.b. [GPOS LookupType 2] Pair adjustment positioning

6.b.i. Specific and class pair kerning

Rules for this LookupType are usually used for kerning, and may be in either of 2 formats:

Pair Pos format A:
position <glyph|glyphclass> <valuerecord>
         <glyph|glyphclass> <valuerecord>;

The first <valuerecord>2.e.iv] corresponds to the first <glyph|glyphclass>, and the second <valuerecord> corresponds to the second <glyph|glyphclass>. The following example illustrates an unusual way to specify a kern value of -100:

position T -60 a <-40 0 -40 0>;
Pair Pos format B:
position <glyph|glyphclass> <glyph|glyphclass>
         <valuerecord>;     # for first <glyph|glyphclass>

This format is provided since it closely parallels the way kerning is expressed in AFM files. Thus, it is a shorter way of expressing:

position <glyph|glyphclass> <valuerecord format A> <glyph|glyphclass> <NULL>;

Kerning can most easily be expressed with this format. This will result in adjusting the first glyph’s x advance, except when in the vrkn feature, in which case it will adjust the first glyph’s y advance. Some examples:

pos T a -100;        # specific pair (no glyph class present)
pos [T] a -100;      # class pair (singleton glyph class present)
pos T @a -100;       # class pair (glyph class present, even if singleton)
pos @T [a o u] -80;  # class pair

Note that in both formats A and B, if at least one glyph class is present (even if it is a singleton glyph class), then the rule is interpreted as a class pair; otherwise, the rule is interpreted as a specific pair.

In the kern feature, the specific glyph pairs should precede the glyph class pairs in the feature file, mirroring the way that they will be stored in the font. Otherwise, depending on the implementation, the specific glyph pairs following any class pair may never be applied. (See §7, “Ordering of lookups and rules in the feature file,” below.)

feature kern {
    # specific pairs for all scripts
    # class pairs for all scripts
} kern;

6.b.ii. Enumerating pairs

If some specific pairs are more conveniently represented as a class pair, but the editor does not want the pairs to be in a class kerning subtable, then the class pair must be preceded by the keyword enumerate (which can be abbreviated as enum). The implementation software will enumerate such pairs as specific pairs. Thus, these pairs can be thought of as “class exceptions” to class pairs. For example:

@Y_LC = [y yacute ydieresis];
@SMALL_PUNC = [comma semicolon period];

enum pos @Y_LC semicolon -80;     # specific pairs
pos      f quoteright 30;         # specific pair
pos      @Y_LC @SMALL_PUNC -100;  # class pair

The enum rule above can be replaced by:

pos y semicolon -80;
pos yacute semicolon -80;
pos ydieresis semicolon -80;

without changing the representation in the font. Since this representation is convenient for generating a large number of specific pairs, it may be used even when some of the pairs generated by the enum rules are incorrect. Specific pairs generated by an enum rule may be overridden by specifying preceding single pairs. Because of this case, it is not an error when specific kern pairs conflict because they have the same glyphs. When specific kern pair rules conflict, the first rule specified is used, and later conflicting rule are skipped.

6.b.iii. Subtable breaks

The implementation software will insert a subtable break within a run of class pair rules if a single subtable cannot be created due to class overlap. A warning will be emitted. For example:

pos [Ygrave] [colon semicolon] -55;   # [line 99]   In first subtable
pos [Y Yacute] period -50;            # [line 100]  In first subtable
pos [Y Yacute Ygrave] period -60;     # [line 101]  In second subtable

will produce a warning that a new subtable has been started at line 101, and that some kern pairs within this subtable may never be accessed. Note that this allows the font to be built, but the result will not match the developer’s intention. The kerning feature will not work as expected until the causes for all such errors are removed. The pair “Ygrave period” will have a value of 0 if the above example comprised the entire lookup, since “Ygrave” is in the coverage (i.e. union of the first glyphs) of the first subtable. One way to understand this is to imagine a lookup table of kern class pairs as a spreadsheet of all possible pairs of kern left-side classes that are used in the lookup table with all the kern right-side classes that are used in the lookup table. Imagine each left side class is the title of a row in the spreadsheet, and each right side class is the title of a column. A glyph can be put in only one row title, and in only one column title. All glyphs not named in a row title get put together in a special row title. All glyphs not named in a column title get put together in a special column title. When you specify the value of a class pair, you are specifying the value in only one cell of the spreadsheet. When you specify a series of kern pair rules between a particular left side class and a series of right side classes, you are filling in a series of cells in the row for the specific left side class. All cells for which no values are specified are set to 0. When programs look for a kern value between “Ygrave” and something else, they look through the list of left side class definitions to find the first occurrence of “Ygrave”. By definition, the first spreadsheet row which includes “Ygrave” will define the kern pair value of “Ygrave” with all other right-side classes, e.g spreadsheet columns. Since a pair value with a right-side period has not been explicitly defined at this point, the default value is 0. Since the programs will not look further than this row, the kern class pair:

pos [Y Yacute Ygrave] period -60;

will never be used.

Sometimes the class kerning subtable may get too large. The editor can make it smaller by forcing subtable breaks at any point by inserting the statement:

subtable;

between two class kerning rules. The new subtable created will still be in the same lookup, so the editor must ensure that the coverages of the subtables thus created do not overlap, since the processing rules will not find and report a conflict.

When seeking to decrease the class table size, it is best to place subtable breaks between blocks of rules where there is no cross linking, such that no left side class in one block is used with any right side class in the other block. However, in most large Western fonts, such groups are so small that breaking them into separate subtables does not yield much decrease in the overall lookup size. In this common case, an adequate strategy is to first divide the entire list of kern class rules in two roughly equal blocks with a subtable break. If this does not make the class kern tables small enough, then continue to subdivide each block of rules in two with a subtable break. Because the class definitions must be repeated for each subtable, a point of diminishing returns usually comes with around 6 subtable breaks.

6.c. [GPOS LookupType 3] Cursive attachment positioning

A Cursive Pos rule is specified as:

position cursive
    <glyph|glyphclass>
    <anchor>   # Entry anchor
    <anchor>;  # Exit anchor

The first <anchor>2.e.vii] indicates the entry anchor point for <glyph|glyphclass>; the second, the exit anchor point.

For example, to define the entry point of glyph meem.medial to be at x=500, y=20, and the exit point to be at x=0, y=-20:

position cursive meem.medial <anchor 500 20> <anchor 0 -20>;

A glyph may have a defined entry point, exit point, or both. <anchor> format D, the null anchor, must be used to indicate that an <anchor> is not defined.

position cursive meem.end <anchor 500 20> <anchor NULL>;

6.d. [GPOS LookupType 4] Mark-to-Base attachment positioning

A Mark-to-Base Pos rule is specified as:

position base <glyph|glyphclass> # base glyph(s)
    # Anchor and mark glyph class, repeated for each
    # attachment point on the base glyph(s)
    <anchor> mark <named mark glyphclass> +
    ;

Each <anchor>2.e.vii] indicates the anchor point on the base glyph(s) to which the mark class’ anchor point should be attached.

A single Mark-To-Base statement must specify all the anchor points and their attaching mark classes.

This rule type does not actually support base glyph classes; the feature file syntax allows this in order to compactly specify Mark-To-Base rules for the set of glyphs which have the same anchor points. A feature file rule which uses a glyph class for the base glyph is expanded in the font to a separate rule for each glyph in the base class, although they will share the same anchor and mark class records.

The named mark glyph classes and the anchor points of all the mark glyphs in the named mark classes must have been previously defined in the feature file by markClass statements [§4.f].

Note: The mark classes used within a single lookup must be disjoint: none may include a glyph which is in another mark class that is used within the same lookup.

For example, to specify that the anchor of mark glyphs acute and grave is at x=30, y=600, and that the anchor of mark glyphs dieresis and umlaut is at x=60, y=600, and to position the anchor point of the four mark glyphs at anchor point x=250, y=450 of glyphs a, e, o and u:

markClass [acute grave] <anchor 150 -10> @TOP_MARKS;
markClass [dieresis umlaut] <anchor 300 -10> @TOP_MARKS;
markClass [cedilla] <anchor 300 600> @BOTTOM_MARKS;

position base [a e o u] <anchor 250 450> mark @TOP_MARKS
                        <anchor 250 -10> mark @BOTTOM_MARKS;

6.e. [GPOS LookupType 5] Mark-to-Ligature attachment positioning

A Mark-to-Ligature Pos rule is specified as:

position ligature <ligature glyph|glyphclass>   # ligature glyph or glyph class
    # Anchor and named mark glyph class, repeated for
    # each anchor point on the first component glyph:
    <anchor> mark <named mark glyph class> +

    # Start of anchor and mark info for the next ligature component
    ligComponent

    # Anchor and named mark glyph class, repeated for
    # each anchor point on the next component glyph:
    <anchor> mark <named mark glyph class> +

    # Additional blocks of ligComponent plus anchor and named mark glyph class
    ;

The statement must specify all the anchor-mark class pairs for all the ligature components. It follows the form of the Mark-To-Base rule, except that a set of anchor-mark class pairs must be specified for each component glyph in the ligature. The set of anchor-mark class pairs for one component is separated for the set of the next component by the ligComponent keyword. If there are no anchor points on a component, it must still specify at least one anchor, which should be the NULL anchor. It is not required that each component have the same number of anchor points.

The named mark glyph classes and the anchor points of all the mark glyphs in the named mark classes must have been previously defined in the feature file by markClass statements [§4.f].

The example in the OpenType specification for this LookupType could be expressed as:

# 1. Define mark anchors:
markClass sukun    <anchor 261 488> @TOP_MARKS;
markClass kasratan <anchor 346 -98> @BOTTOM_MARKS;

# 2. Define mark-to-ligature rules:
position ligature lam_meem_jeem
    <anchor 625 1800> mark @TOP_MARKS     # mark above lam
    ligComponent                          # start specifying marks for meem
    <anchor 376 -368> mark @BOTTOM_MARKS  # mark below meem
    ligComponent                          # start specifying marks for jeem
    <anchor NULL>;                        # jeem has no marks

Note that a NULL anchor needs to be specified for a ligature component only when it has no non-NULL anchors. Otherwise, the implementation will supply a NULL anchor for each mark class that is not used by a ligature component.

If a glyph class is used, each ligature in the glyph class must have the same number of components and the same anchor positions on each component.

6.f. [GPOS LookupType 6] Mark-to-Mark attachment positioning

A Mark-to-Mark Pos rule is specified as:

position mark <glyph|glyphclass> # mark glyph(s)
    # Anchor and mark glyph class, repeated for each
    # attachment point on the mark glyph(s)
    <anchor> mark <named mark glyphclass> +
    ;

This rule is distinguished from a Mark-to-Base Pos rule [§6.d] by the first mark keyword. Otherwise, it has the same syntax and restrictions.

The example in the OpenType specification for this LookupType could be expressed as:

# 1. Define name mark class:
markClass damma <anchor 189 -103> @MARK_CLASS_1;
# 2. Define mark-to-mark rule:
position mark hamza <anchor 221 301> mark @MARK_CLASS_1;

6.g. [GPOS LookupType 7] Contextual positioning

This LookupType is a functional subset of GPOS LookupType 8, chaining contextual positioning. Thus, all desired rules of this LookupType can be expressed in terms of chaining contextual positioning rules.

6.h. [GPOS LookupType 8] Chaining contextual positioning

6.h.i. Specifying a Chain Positioning rule and marking sub-run

A Chain Positioning rule target sequence has three parts: backtrack, input, and lookahead glyph sequences. A glyph sequence comprises one or more glyphs or glyph classes.

The most important is input glyph sequence. This is the sequence of glyphs and glyph classes to which positioning operations are applied. Optionally, a prefix (also known as backtrack) glyph sequence may be specified, as well as a suffix (also known as lookahead) glyph sequence. The entire sequence of glyphs — prefix plus input plus suffix — must match in the current context for the rule to be applied. The match sequence is aligned to the current context by aligning the first glyph of the input sequence with the current glyph of the text being processed. If the rule is matched, then the current context moves the current glyph pointer ahead in the original text by the length of the input sequence. Note that in the FEA syntax, the entire context string (backtrack sequence + input sequence + look-ahead sequence) are all written in the text string order. This is worth emphasis, as inside the lookup rule, the glyphs of the backtrack sequence are written in reverse order from the text to be matched. Developers of font editing tools who know this are sometimes confused by the FEA syntax.

For each glyph or glyph class in the input sequence, the contextual rule may specify one or more lookups (§4.e) to be applied at that position. Note that the specified lookups may contain many rules; the implementation must ensure that only one rule in a referenced lookup will match at that position in the input sequence. Lookups cannot be specified for the glyphs or glyph classes in the backtrack and lookahead sequences.

The input sequence is defined by appending the mark (') character to all the glyph names and class names (and only these names) within the input sequence. Applying the mark (') character to keywords such as anchor and mark or a value record will result in a syntax error.

6.h.ii. Specifying Contextual Positioning with explicit lookup references

The most general form of the contextual substitution rule is to explicitly reference named lookups in the rule.

Example:

Define two standalone lookups (§4.e), and then reference them in the input sequence of contextual positioning rules with the keyword lookup and the lookup name.

markClass [acute grave] <anchor 150 -10> @ALL_MARKS;

lookup CNTXT_PAIR_POS {
     position T o -10;
     position T c -12;
 } CNTXT_PAIR_POS;

lookup CNTXT_MARK_TO_BASE {
     position base o <anchor 250 450> mark @ALL_MARKS;
     position base c <anchor 250 450> mark @ALL_MARKS;
 } CNTXT_MARK_TO_BASE;

feature test {
     position T' lookup CNTXT_PAIR_POS [o c]' @ALL_MARKS' lookup CNTXT_MARK_TO_BASE;
 } test;

This rule has only an input sequence, and no backtrack or lookahead sequence. It will match when the current glyph is ‘T’, followed by either ‘o’ or ‘c’, followed by any mark glyph. The lookup CNTXT_PAIR_POS will applied to the ‘T’, and the lookup CNTXT_MARK_TO_BASE will be applied to the glyphs in the class @ALL_MARKS.

This form of the contextual positioning rule is the most flexible. You can specify a positioning lookup for more than one input sequence glyph or glyph class, the referenced lookups can be of different types, and the referenced lookups can have different lookup flags that the parent contextual lookup. The drawback is that it is difficult to understand what position rule will be applied, and the implementation may not warn if the referenced lookup does not contain a rule that matches the context.

When it is acceptable to specify a positioning rule for only one input glyph or glyph class in the input sequence, and that the referenced lookup have the same lookup flag as the parent contextual lookup, then you can specify a contextual rule with the positioning rule in-line. This is much easier to understand.

6.h.iii. Specifying Contextual Positioning with in-line single positioning rules

Example 1:
position [quoteleft quotedblleft ][Y T]' <0 0 20 0> [quoteright quotedblright];
position [quoteleft quotedblleft ][Y T]' 20 [quoteright quotedblright];

Both of these rules have an input sequence of a single glyph position, for which the glyph class [Y T] is specified. The marked glyph class is followed by a value record. The first form shows a full value record which allows you to alter both the (x,y) coordinates of the origin and the (x,y) coordinates of the advance width. The second rule shows the simple form of the value record, which specifies a value for only a change to the x value of the advance width. Note that the value record modifies the glyph which it follows. These both increase the advance width of Y or T by 20, when preceded by either quoteleft or quotedblleft, and followed by quoteright or quotedblright. Note that not all marked glyphs or glyph classes in the input sequence must be followed by a value record; if this is omitted, then the item’s positioning info will not be affected.

Example 2:
position s f' 10 t;
position s f' 10 t' -5 period;

The first example specifies a kern pair “ft” when preceded by “s”, and increases the x-advance of f by 10. The second specifies a kern triplet “ft.”, when preceded by “s”. The x-advance of f is increased by 10, and the x-advance of t is decreased by 5. The entire run of marked glyphs will be consumed by a rule; in the first case, after matching this rule, the set of rules in current lookup will next be applied starting at the glyph “t”. In the second case, the rules will next be applied starting at the glyph “period”.

Special notes on contextual kerning

Contextual positioning rules must be in a different lookup than pair positioning rules, since the rules are of different lookup types. Because each lookup is applied independently of the other lookup(s) over the entire text stream, the positioning change specified in a pair kerning rule will be added to the positioning change specified in a contextual kerning rule, whenever the two rules match the same glyph pair in the text stream. This effect can be managed by specifying the contextual kerning rules values so that the sum of the pair positioning rule value and the contextual positioning rule value add to the desired value, as in example 3A.

Example 3A:
position L quoteright -150;
position quoteright A -120;
position L' 50 quoteright' 70 A;

Desired final kern adjustment: L' -100 quoteright' -50 A;

In this example, the intended kern correction for the triplet “L quoteright A” is an adjustment of -100 to the advance width of the L when followed by quoteright, and of -50 to the advance width of quoteright when followed by A. However, since the pair positioning rules will adjust the pair “L quoteright” by -150 and the pair “quoteright A” by -120, the adjustment values in the contextual rule for the triplet must be set as shown. This approach is feasible, but difficult to understand.

Another approach is to simply make all the kerning be contextual by marking the first glyph or glyph class of each pair positioning rule. Since all the kern rules will then be in a single lookup, only one rule will match in any context, and there is no need to figure out which rules add up. This solution is shown in example 3B using feature file syntax for contextual positioning. Notice, however, that the triplet rule has to be defined before the other two rules. Otherwise, the pair positioning rules will block the triplet’s positioning adjustment.

Example 3B:
position L' -100 quoteright' -50 A;
position L' -150 quoteright;
position quoteright' -120 A;
position s f' 10 t period;

In order to make pair positioning rules easier to read and write as contextual kern pairs, the feature file syntax will identify a special case of contextual rule which contains only one marked glyph or glyph class, followed by one or more unmarked glyph or glyph class, plus a value record. This will be treated as a contextual pair positioning statement, and will be the only one case where a value record may follow an unmarked glyph. Example 3B can thus be written as example 3C. Both examples are exactly equivalent.

Example 3C:
position L' -100 quoteright' -50 A;
position L' quoteright -150;  # special cases of contextual positioning
position quoteright' A -120;  # where value record follows unmarked glyph,
position s f' t 10 period;    # making them exactly equivalent to 3B.

Note that the following statement (Example 3D) is NOT a pair kerning statement, and would almost always be an error of intent.

Example 3D:
position L' quoteright' -150;

This statement does two things that are not desirable in pair kerning statement. First, it decreases the advance width of quoteright, not L. Second, it will move the current glyph pointer forward by 2 glyphs, skipping over the quoteright so that quoteright will not be examined for matching kern rules.

The FEA syntax will not allow applying positioning lookups of different types in one contextual rule. For example, if you want to position sukun over lam_meem_jeem when followed by alef, and kern lam_meem_jeem with alef in this context, you need to put the mark and kern rules in different lookups.

Example 4:
markClass sukun <anchor 0 0> @TOP_CLASS;

lookup MARK_POS {
    position base lam_meem_jeem' <anchor 625 1800> mark @TOP_CLASS alef;
} MARK_POS;

lookup MARK_KERN {
    position lam_meem_jeem' 5 @TOP_CLASS
    alef;
} MARK_KERN;

The rule in lookup MARK_POS will position sukun over lam_meem_jeem when followed by alef. The second rule will add 5 to the advance width of lam_meem_jeem when followed by sukun and then by alef.

Example 6:
lookup a_reduce_sb {
    pos a <-80 0 -160 0>;
} a_reduce_sb;

lookup a_raise {
    pos a <0 100 0 0>;
} a_raise;

feature kern {
    pos a' lookup a_reduce_sb lookup a_raise b;
} test;

In this example the rule in the kern feature will match the sequence “a b” and apply multiple lookups to the input “a”. The first lookup will subtract 80 units from the x placement and 160 units from the x advance of “a”. The second lookup will adjust the y placement of “a” by 100 units.

Example 7:
lookup REPHA_SPACE {
    pos ka-gran <0 0 644 0>;
} REPHA_SPACE;

lookup ANUSVARA_SPACE {
    pos ka-gran <0 0 510 0>;
} ANUSVARA_SPACE;

lookup ADD70 {
    pos ka-gran <0 0 70 0>;
} ADD70;

lookup ADD_ADVANCE_WIDTH {
    pos ka-gran' lookup REPHA_SPACE lookup ANUSVARA_SPACE lookup ADD70 repha-gran anusvara-gran;
    pos ka-gran' lookup REPHA_SPACE lookup ADD70 repha-gran;
    pos ka-gran' lookup ANUSVARA_SPACE lookup ADD70 anusvara-gran;
} ADD_ADVANCE_WIDTH;

feature dist {
    lookup ADD_ADVANCE_WIDTH;
} dist;

In this example the rules in ADD_ADVANCE_WIDTH will match the sequences “ka-gran repha-gran anusvara-gran”, “ka-gran repha-gran”, or “ka-gran anusvara-gran” and apply multiple lookups to the input. Here each lookup adds advance width to “ka-gran” based on the following glyphs.

6.h.iv. Specifying Contextual Positioning with in-line cursive positioning rules

The contextual form of the cursive positioning rule consists of simply adding contextual glyphs or glyph classes before the cursive keyword, and/or after the anchors. The base glyph must be marked as part of the input sequence; the others may or may not be marked.

position @BACKTRACK_GLYPHS_FOR_MEEM cursive
meem.medial' <anchor 500 20> <anchor 0 -20> @LOOKAHEAD_GLYPHS_FOR_MEEM;

6.h.v. Specifying Contextual Positioning with in-line mark attachment positioning rules

For all three forms of the mark attachment rules - Mark-To-Base, Mark-To-Ligature, and Mark-To-Mark - the contextual form of the positioning rules consist of inserting glyph sequences in one or more of three places in the rule:

  1. before the initial base, ligature, or mark keyword
  2. after the base glyph or glyph class
  3. after all the anchor-mark class clauses

At least one of the mark classes must be marked as part of the input sequence; the other glyphs or glyph classes in the contextual sequence may or may not be marked. There is special treatment of the mark classes. The implementation creates a glyph class which is the input glyph class to which the positioning lookup is applied. Each mark class that is marked as part of the input sequence is added to this glyph class. If the rule has four mark classes, and three are marked as part of the input sequence. the result is a single glyph class in the input sequence which contains the glyphs from the three marked mark classes. The base glyph or glyph class is also always added in the contextual sequence.

For example:

position [T V F] base [a e o u] <anchor 250 450> mark @TOP_MARKS'
                                <anchor 250 -10> mark @BOTTOM_MARKS' @VOWELS;

This contextual rule will match when the current context matches the 4 item glyph sequence “[T V F] [a e o u] [top and bottom marks] @VOWELS”. The input sequence has only one item, a glyph class which consists of all the glyphs from the two mark classes.

6.h.vi. Specifying exceptions to the Chain Pos rule

Exceptions to a chaining contextual positioning rule are expressed by inserting a statement of the following form anywhere before the chaining contextual rule and in the same lookup:

ignore position <marked glyph sequence> (, <marked glyph sequence>)*;

This rule works in exactly the same was as specifying exceptions to a chaining contextual substitution rule [§5.f.ii].

6.i. [GPOS LookupType 9] Extension positioning

The useExtension keyword specifies creating lookups of this lookup type. See §4.e.

7. Ordering of lookups and rules in the feature file

7.a. An OpenType Layout engine’s layout algorithm

The following is a reference summary of the algorithm used by an OpenType layout (OTL) engine to perform substitutions and positionings. The important aspect of this for a feature file editor is that each lookup corresponds to one “pass” over the glyph run (see step 4 below). Thus, each lookup has as input the accumulated result of all previous lookups in the LookupList (whether in the same feature or in other features).

1. All glyphs in the client’s glyph run must belong to the same language system. (Glyph sequence matching may not occur across language systems.)


Do the following first for the GSUB and then for the GPOS:

2. Assemble all features (including any required feature) for the glyph run’s language system.

3. Assemble all lookups in these features, in LookupList order, removing any duplicates. (All features and thus all lookups needn’t be applied to every glyph in the run.)

4. For each lookup:

5. For each glyph in the glyph run:

6. If the lookup is applied to that glyph and the lookupflag doesn’t indicate that that glyph is to be ignored:

7. For each subtable in the lookup:

8. If the subtable’s target context is matched:

9. Do the glyph substitution or positioning,


OR:

If this is a (chain) contextual lookup do the following [(10)-(11)] in the subtable’s Subst/PosLookupRecord order:

10. For each (sequenceIndex, lookupListIndex) pair:

11. Apply lookup[lookupListIndex] at input sequence[sequenceIndex] [steps(7)-(11)]

12. Goto the glyph after the input sequence matched in (8) (i.e. skip any remaining subtables in the lookup).

The “target context” in step 8 above comprises the input sequence and any backtrack and lookahead sequences.

The input sequence must be matched entirely within the lookup’s “application range” at that glyph (that contiguous subrun of glyphs including and around the current glyph on which the lookup is applied). There is no such restriction on the backtrack and lookahead sequences.

“Matching” includes matching any glyphs designated to be skipped in the lookup’s LookupFlag.

7.b. Ordering of lookups and subtables

A lookup in the OpenType font will be created from each named lookup block [§4.e] or each run of rules with the same feature, script, language, lookupflag and lookup type attribute.

Lookups will be created in the GSUB/GPOS table’s LookupList in the same order as the corresponding named lookup blocks or runs of rules in the feature file, except for the lookups that comprise the aalt feature. These will always be created before all other features [§8.a].

A lookup may contain one or more subtables. Subtable breaks may have been inserted by the implementation software due to format restrictions, or they may have been explicitly requested by the editor [§4.f]. In either case, subtables will be created in the same order as the corresponding subtables in the feature file, if the order is relevant to OT layout. If the order is irrelevant, the implementation may choose to order subtables within a lookup in any manner.

Note that the lookup sharing mechanism (i.e. a lookup reference statement that refers to a named lookup block) is implemented simply by referring to the LookupList index of the lookup as many times as needed in the Feature tables.

7.c. Ordering of rules within a lookup

In the feature file, the ordering of rules within a lookup is important only for chaining contextual substitution and chaining contextual positioning rules. This is because in all other cases of LookupTypes (including ligature substitutions, see [§5.d]), the appropriate ordering is automatically deduced, and the implementation sorts the rules accordingly when writing them to the font file.

8. Specially handled features

8.a. The all alternates feature (aalt)

The aalt feature consists of a feature definition block which contains a series of statements in the form:

feature <feature tag>;

followed by one or more single and alternates substitution rules.

The feature file parser should create the aalt feature from the feature file definition as follows:

  1. Considering only features indicated by:

    feature <feature tag>;

    in the aalt specification feature block (see example below), combine all single and alternate substitutions in those features (including single substitutions that appear within a chaining contextual rule) into groups with the first glyph in the group being the target glyph of the substitution. Subsequent elements of the group will be ordered by the order of the relevant rule in the feature file. Duplicate glyphs will be removed.

    The aalt feature block must appear before the feature block of any <feature tag> it references in the above manner. It will also always be created as the first feature in the font (i.e. its lookups will be at the beginning of the GSUB LookupList).

  2. Add any additional single and alternate substitutions in the aalt specification to the groups that were created algorithmically, by step 1. This facility is provided to fine-tune the semantic groups, for instance, if certain glyphs weren’t referenced in any of the features indicated in step 1 above. This can also be used to override substitutions specified by including other features: for any target glyph, the alternate glyphs specified by this mechanism precede in order any other alternate glyphs.

  3. If there are only two glyphs in a group, create a single substitution in the aalt feature, with the first glyph being the target glyph and the second glyph being the replacement glyph. If there are more than two glyphs in a group, create an alternate substitution in the aalt feature, with the first glyph being the target glyph and the remaining glyphs being the alternate set. These alternate glyphs will be sorted in the order that the source features are named in the aalt definition, not the order of the feature definitions in the file. Alternates defined explicitly, as in step 2 above, will precede all others.

The useExtension keyword:

The useExtension keyword may optionally precede { in the feature block syntax. The aalt lookups will be created with the GSUB Extension lookup type if and only if the useExtension keyword is used. Note that since the Extension lookup types were added in OpenType specification v1.3, they will not be recognized by all OpenType layout parsers.

Specifying language system:

This feature will be registered under all language systems specified by languagesystem statements; see §4.b.i above.

The following are not allowed in the aalt feature definition: script, language, lookupflag, and subtable statements; named lookup blocks and lookup reference statements. The aalt lookups will be created with LookupFlag 0.

Examples:

languagesystem DFLT dflt;
languagesystem latn dflt;
languagesystem latn TRK;
languagesystem cyrl dflt;

feature aalt {
    feature salt;
    feature smcp;
    substitute d by d.alt;
} aalt;

feature smcp {
    sub [a-c] by [A.sc-C.sc];
    sub f i by f_i;     # not considered for aalt
} smcp;

feature salt {
    sub a from [a.alt1 a.alt2 a.alt3];
    sub e [c d e]' f by [c.mid d.mid e.mid];
    sub b by b.alt;
} salt;

The aalt lookups from the above example will be registered under the default language systems of the DFLT, latn and cyrl scripts, and also under the latn/TRK language systems. The aalt created would be the same as if the font editor had specified:

feature aalt {
    sub a from [a.alt1 a.alt2 a.alt3 A.sc];
    sub b from [b.alt B.sc];
    sub c from [c.mid C.sc];
    sub d from [d.alt d.mid];
    sub e by e.mid;
} aalt;

The following example will result in the aalt lookups being created with the GSUB Extension lookup type:

feature aalt useExtension {
    feature salt;
    feature smcp;
    substitute d by d.alt;
    # ... other rules
} aalt;

8.b. The optical size feature (size)

This feature is unique in that it contains no substitution or positioning rules (the LookupCount field in its Feature table will always be 0).

The feature’s data is accessed instead through the FeatureParams value of its Feature table.

Thus, the syntax for this feature is different from all other features. The feature block must contain:

No other feature file statements, blocks or keywords are permitted. (Comments are allowed.)

This feature will be created in the GPOS table and will be registered under all language systems specified by languagesystem statements (see §4.b.i above).

For example:

feature size {
    parameters 100  # design size (decipoints)
                 3  # subfamily identifier
                80  # range start (exclusive, decipoints)
               139; # range end (inclusive, decipoints)
    sizemenuname "Win MinionPro Size Name";
    sizemenuname 1 "Mac MinionPro Size Name";
    sizemenuname 1 21 0 "Mac MinionPro Size Name";
} size;

See the OpenType feature tag registry for a description of the parameters statement fields. “decipoints” is a unit of 1/10 of a point.

These values may also be specified more directly as decimal point values, but a decimal point and following value is then required. For example, “8.0” and “80” will both result in the same value being stored in the font.

The parameter sizemenuname provides the menu name to be used for a group of fonts with the same subfamily identifier.

If the font is part of such a group, then the sizemenuname statement must be provided in order for the members of the group to be grouped together in a sub-menu under the specified menu name.

In this case, we strongly recommend providing at least the two entries for Windows and Macintosh platform Roman script name strings. You may also include any another localized name strings that may be useful.

If the font is not part of such a group, then the sizemenuname statements must be omitted, and all fields but the first (design size) for the parameter statement must be set to 0. This form may be abbreviated by setting the subfamily identifier to 0, and omitting the two remaining zeros. For example:

parameters 10.0 0;  # Indicate intended design size to be 10 pts.

This can be used to indicate the intended design size for a font, even when it is not part of an optical size group.

The syntax of the sizemenuname statement follows that of the name table name strings, as described in §9.e.

The names specified by the sizemenuname statement are actually stored in the name table, with name IDs starting at the first unused name ID at or after 256.

8.c. Descriptive names for Stylistic Set features (ss01 - ss20)

As of the OpenType specification 1.6, descriptive names are allowed for stylistic substitution features. These names are specified within a feature block for a Stylistic Set feature. The implementation will store the name strings in the name table, and will create a feature parameter data block which references them.

A single Stylistic Set feature block may contain more than one descriptive name in order to support different languages. These names are defined within a featureNames block that must be inside the stylistic set feature block, and must precede any of the rules in the feature. The syntax for a featureNames block is:

featureNames {
    name <platform ID> <script ID> <language ID> <text string>;
    # This name entry is repeated for every script and language to be supported.
};

The syntax for the individual name string entries is similar to that of the name table nameID entries (see §9.e) - the only difference is that the introductory keyword is name, and the name ID value is omitted, since the nameID value is auto-generated by the feature compiler.

Example:
feature ss01 {
    featureNames {
        name "Feature description for MS Platform, script Unicode, language English";
        # Without platform ID, script ID, or language ID specified,
        # the implementation assumes (3,1,0x409).

        name 3 1 0x411 "Feature description for MS Platform, script Unicode, language Japanese";
        name 1 "Feature description for Apple Platform, script Roman, language unspecified";
        # When only platform ID is specified, the implementation assumes script and language
        # is Latin. For Apple this is (1,0,0).

        name 1 1 12 "Feature description for Apple Platform, script Japanese, language Japanese";
    };
        # --- rules for this feature ---
} ss01;

8.d. UI Label names for Character Variant features (cv01 - cv99)

As of the OpenType specification 1.6, UI label names are allowed for Character Variant features. These names are specified within the feature block for a Character Variant feature. The implementation will store the name strings in the name table, and will create a feature parameter data block which references them.

A set of NameID entries are specified within a parameter block entry. The parameter block must precede any of the rules in the feature. There are four distinct NameID entry types. The ParamUILabelNameID entry may be omitted or repeated as often as needed. The other NameID types may be omitted, or defined only once. The NameID entries must be specified in the order listed below. A single Character Variant NameID entry may contain more than one name string entry in order to support different languages and platforms.

Following the set of NameID entries, a series of 24 bit Unicode values may be specified. These provide Unicode values for the base glyphs referenced by the feature. The developer may specify none, some, or all of the Unicode values for the base glyphs. The Unicode value may be written with either decimal or hexadecimal notation: the value must be preceded by ‘0x’ if it is a hexadecimal value. The 24 bit field means that the largest Unicode value allowed is ((1«24) -1), aka, 0xFFFFFF

The intent of the NameID entries is described in the OpenType spec document: OpenType Layout tag registry — section on feature tags, tag name cv01 - cv99.

Note: The ParamUILabelNameID entries are used when one base glyph is mapped to more than one variant; the font designer may then specify one ParamUILabelNameID for each variant, in order to uniquely describe that variant. If any ParamUILabelNameID entries are specified, the number of ParamUILabelNameID entries must match the number of variants for each base glyph. If the Character Variant feature specifies more than one base glyph, then the set of NameID entries in the parameter block will be used for each base glyph and its variants.

The syntax for a cvParameters block is:

cvParameters {
    FeatUILabelNameID {
        name <platform ID> <script ID> <language ID> <text string>;
    };
    FeatUITooltipTextNameID {
        name <platform ID> <script ID> <language ID> <text string>;
    };
    SampleTextNameID {
        name <platform ID> <script ID> <language ID> <text string>;
    };
    ParamUILabelNameID {
        name <platform ID> <script ID> <language ID> <text string>;
    };

    Character <Unicode value string>;
};

The syntax for the individual name string entries within a NameID entry is similar to that of the name table nameID entries (see §9.e) - the only difference is that the introductory keyword is name, and the name ID value is omitted, since the nameID value is auto-generated by the feature compiler.

Example:
feature cv01 {

    cvParameters {

        FeatUILabelNameID {
            name 3 1 0x0409 "uilabel simple a";  # English US
            name 1 0 0 "uilabel simple a";  # Mac English
        };

        FeatUITooltipTextNameID {
            name 3 1 0x0409 "tool tip simple a";  # English US
            name 1 0 0 "tool tip simple a";  # Mac English
        };

        SampleTextNameID {
            name 3 1 0x0409 "sample text simple a";  # English US
            name 1 0 0 "sample text simple a";  # Mac English
        };

        ParamUILabelNameID {
            name 3 1 0x0409 "param1 text simple a";  # English US
            name 1 0 0 "param1 text simple a";  # Mac English
        };

        ParamUILabelNameID {
            name 3 1 0x0409 "param2 text simple a";  # English US
            name 1 0 0 "param2 text simple a";  # Mac English
        };

        Character 10;
        Character 0x5DDE;

    };

    # --- rules for this feature ---
} cv01;

9. Specifying or overriding table values

In addition to GSUB and GPOS OpenType layout features, the feature file syntax enables specifying or overriding values in certain other tables. These are specified within the corresponding table block:

table <table tag> {
    # ...
} <table tag>;

The following table values are currently supported:

9.a. BASE table

If no BASE table entry is specified in the feature file, no BASE table is created in the OpenType font.

table BASE {
    HorizAxis.BaseTagList <baseline tag>+;
    HorizAxis.BaseScriptList <script record> (, <script record>)*;
    HorizAxis.MinMax <minmax record>;

    VertAxis.BaseTagList <baseline tag>+;
    VertAxis.BaseScriptList <script record> (, <script record>)*;
    VertAxis.MinMax <minmax record>;
} BASE;

A <script record> is of the form:

<script tag> <default baseline tag> <base coord>+

<base coord> can take several formats: [ Currently only format A is implemented ]

# Format A
<number>

# Format B
<number> <glyph> <number>

# Format C
<number> <device>

The baseline tags for each BaseTagList must be sorted in increasing ASCII order.

The number of baseline values for a particular script should be the same as the number of baseline tags in the corresponding BaseTagList.

A <minmax record> [ currently not implemented ] is of the form:

<script tag> <language tag>  # Defines the language system
    <base coord>,            # Min value for this language system
    <base coord>             # Max value for this language system
    [,
    <feature tag>            # (Optional) feature tag
    <base coord>,            # Min value for this feature tag
    <base coord>]            # Max value for this feature tag
    ;

An example of a simple BASE table is:

table BASE {
    HorizAxis.BaseTagList     ideo romn;
    HorizAxis.BaseScriptList  latn   romn   -120    0, cyrl   romn   -120    0,
                              grek   romn   -120    0, hani   ideo   -120    0,
                              kana   ideo   -120    0, hang   ideo   -120    0;
} BASE;

9.b. GDEF table

table GDEF {
    GlyphClassDef <glyphclass>*,  # base glyphs
                  <glyphclass>*,  # ligature glyphs
                  <glyphclass>*,  # mark glyphs
                  <glyphclass>;   # component glyphs
    Attach        <glyph|glyphclass> <number>+; # <number> is a contour point index

    LigatureCaretByDev # Currently not implemented
    LigatureCaretByPos <glyph|glyphclass> <caret position value>+;
    LigatureCaretByIndex <glyph|glyphclass> <caret contour point index value>+;
} GDEF;

The number of <caret value>s specified for a LigatureCaret must be: (number of ligature components) - 1.

Only one LigatureCaret rule may be specified per glyph, whether it is LigatureCaretByPos or LigatureCaretByIndex.

Here is an example of a GDEF table block:

table GDEF {
    GlyphClassDef @BASE, @LIGATURES, @MARKS, @COMPONENT;
    Attach noon.final 5;
    Attach noon.initial 4;
    LigatureCaretByPos f_f_l 400 600;
    LigatureCaretByPos [c_t c_s] 500;
    LigatureCaretByIndex f_f_i 23 46;
} GDEF;

The four class names following GlyphClassDef must be separated by commas. Any classes can be omitted, but all the commas are required. According to the OpenType specification, any glyph not included in one of the class definitions will be assigned glyph class index 0, and will not be included in any of the GlyphClassDef classes.

The MarkAttachment classes of the GDEF table may not be specified explicitly in feature file syntax. They are instead created by the implementation from use of the lookupflag MarkAttachmentType <class name> statements. The class names may be from either regular classes definitions or mark class definitions.

The MarkGlyphSets classes of the GDEF table may not be specified explicitly in feature file syntax. They are instead created by the implementation from use of the lookupflag UseMarkFilteringSet <class name> statements. The class names may be from either regular classes definitions or mark class definitions.

If any mark class has been defined, or if any of the lookup flags for skipping glyphs of a certain class have been seen, the implementation will check if the GDEF keywords for defining the GlyphClassDef has been seen. If not, the implementation will fill them from the substitution and positioning rules, and will create a GDEF table even if there is no GDEF definition in the feature file. The LIGATURE and COMPONENT classes will be filled from the glyphs used in any GSUB Lookup Type 4, Ligature Substitution. The MARKS class will be filled from all the glyphs in any of the mark classes used in positioning rules.

9.c. head table

The head table FontRevision value is used as the overall font version number, and should be incremented whenever any data in the fonts is changed. It is both specified and reported as a decimal number with three significant decimal places. The actual value stored in the font will, however, be a Fixed number (16.16 bit format). Due to the limited precision of this format, the value stored may differ by a small decimal fraction from that specified, but will always round to the same value when rounded to three fractional decimal places.

This value is also used as the source for the font version string in the name table name string ID 5 “Version”.

table head {
    FontRevision <fixed point number with three fractional decimal places>;
} head;
Example 1:
table head {
    FontRevision 1.1;
} head;

This format is supported, but will cause a warning that the specification will be converted to “1.100”. It will be stored in the font as 0x0001199A. A more exact decimal representation would be 1.10000610352, but it will be reported as “1.100”.

Example 2:
table head {
    FontRevision 1.001;
} head;

This value be stored in the font as 0x00010042. A more exact decimal representation is 1.001007, but it will be reported as “1.001”.

Example 3:
table head {
    FontRevision 1.500;
} head;

This value be stored in the font as 0x00018000, and will be reported as “1.500”. The decimal and Fixed values are equal in this case.

9.d. hhea table

table hhea {
    CaretOffset <metric>;
    Ascender <metric>;
    Descender <metric>;
    LineGap <metric>;
} hhea;

For example:

table hhea {
    CaretOffset -50;
    Ascender 800;
    Descender 200;
    LineGap 200;
} hhea;

9.e. name table

table name {
    # name records
} name;

A name record is of the form:

nameid <id> [<string attribute>] <string>;

An <id> is a number specifying the ID of the name string to be added to the name table. Note that IDs 2 and 6 (Family, Subfamily, Unique, Full, Version, and FontName) are reserved by the implementation and cannot be overridden; doing so will elicit a warning message and the record will be ignored.

An optional <string attribute> is one or three space delimited numbers that specify the platform, platform-specific, and language IDs to be stored in the name record of the name table. If only one number is specified it represents the platform ID. The platform ID may be either 1 or 3, corresponding to the Macintosh or Microsoft (hereafter called Windows) platforms, respectively. The other ID numbers must be in the range 0-65535 but are not otherwise validated.

Consult the OpenType specification to obtain Windows platform IDs, Windows language IDs, Macintosh platform IDs and Macintosh language IDs.

Decimal numbers must begin with a non-0 digit, octal numbers with a 0 digit, and hexadecimal numbers with a 0x prefix to numbers and hexadecimal letters a-f or A-F.

If some or all of the string attribute ID numbers aren’t specified their values are defaulted as follows:

platform id      3 (Windows)

Windows platform selected:

platspec id      1 (Unicode)
language id 0x0409 (Windows default English)

Macintosh platform selected:

platspec id      0 (Roman)
language id      0 (English)

Putting this all together gives the following valid nameID formats and the IDs that are assigned.

representation              id  platform id platspec id language id
--------------------------- --- ----------- ----------- -----------
nameid 1 <string>;          1   3           1           0x0409
nameid 1 3 <string>;        1   3           1           0x0409
nameid 1 3 S L <string>;    1   3           S           L
nameid 1 1 <string>;        1   1           0           0
nameid 1 1 S L <string>;    1   1           S           L

A string is composed of UTF-8 characters enclosed by ASCII double quote characters ("). Newlines embedded within the string are removed from the character sequence to be stored.

Strings are converted to UTF-16 for the Windows platform. Unicode values for the Windows platform may also be specified using a special character sequence of a backslash character (\) followed by exactly four hexadecimal numbers (of either case) which may not all be zero, e.g. \4e2d. The ASCII backslash character must be represented as the sequence \005c or \005C and the ASCII double quote character must be represented as the sequence \0022.

There is no corresponding conversion to Unicode for the Macintosh platform but character codes in the range 128-255 may be specified using a special character sequence of a backslash character (\) followed by exactly two hexadecimal numbers (of either case) which may not both be zero, e.g. \83. The ASCII backslash character must be represented as the sequence \5c or \5C and the ASCII double quote character must be represented as the sequence \22.

Example (add designer’s name that includes non-ASCII characters for Mac and Windows platforms):
table name {
    nameid 9 "Joachim Müller-Lancé";            # Windows (Unicode), UTF-8 input
} name;
table name {
    nameid 9 "Joachim M\00fcller-Lanc\00e9";    # Windows (Unicode), escaped Unicode values
    nameid 9 1 "Joachim M\9fller-Lanc\8e";      # Macintosh (Mac Roman)
} name;

9.f. OS/2 table

table OS/2 {
    FSType <number>;
    Panose <panose number>;
    UnicodeRange <Unicode range list>;
    CodePageRange <code page list>;
    TypoAscender <metric>;
    TypoDescender <metric>;
    TypoLineGap <metric>;
    winAscent <metric>;
    winDescent <metric>;
    XHeight <metric>;
    CapHeight <metric>;
    WeightClass <number>;
    WidthClass <number>;
    Vendor <string>;
    LowerOpSize <number>;
    UpperOpSize <number>;
    FamilyClass <number>;
} OS/2;

Vendor should be 4 characters long. If a shorter vendor ID is given, it is automatically padded with spaces. A longer vendor ID causes an error.

<panose number> is ten (decimal) numbers separated by spaces.

<Unicode range list> is a space-separated list of Unicode bit numbers from the OpenType specification for the ulUnicodeRange1-4 in the OS/2 table.

<code page list> is a space-separated list of Windows code page numbers from the OpenType specification for the ulCodePageRange1-2 in the OS/2 table.

LowerOpSize and UpperOpSize set the usLowerOpticalPointSize and usUpperOpticalPointSize fields. If these are set, then the OS/2 version must be set to at least 5 by the implementation. Note that the values for these fields are set in units of TWIPS, or 20 × point size.

FamilyClass is a single numeric value (decimal, hexadecimal, or octal) to set the sFamilyClass field. FamilyClass is conceptually 2 fields (class and subclass), so it’s often easier to think about and express as hexadecimal since that format nicely divides the class from subclass, i.e. 0x0805 means Class=8 (Sans Serif), Subclass=5 (Neo-grotesque Gothic). See the OpenType Specification for valid values for class/subclass. NOTE: makeotfexe does not make any attempt to validate the supplied value beyond ensuring that the supplied value fits into two bytes.

Example:
table OS/2 {
    FSType 4;
    Panose 2 15 0 0 2 2 8 2 9 4;
    TypoAscender 800;
    TypoDescender -200; # Note that TypoDescender is negative for descent below the baseline.
    winAscent 832;
    winDescent 321; # Note that winDescent is positive for descent below the baseline.
    UnicodeRange
        0   # Basic Latin
        1   # Latin-1 Supplement
        9   # Cyrillic
        55  # CJK Compatibility
        59  # CJK Unified Ideographs
        60  # Private Use Area
        ;
    CodePageRange
        1252    # Latin 1
        1251    # Cyrillic
        932     # JIS/Japan
        ;
    XHeight 400;
    CapHeight 600;
    WeightClass 800;
    WidthClass 3;
    Vendor "ADBE";
    FamilyClass 0x0805;  # Class 8 (Sans-serif), Subclass 5 (Neo-grotesque Gothic)
} OS/2;

Note that for the codepage ranges, the list numbers may be separated by any amount of white space. Note that the terminal semicolon cannot follow a comment character on a line, as all text on a line following the comment character is removed before processing.

9.g. vhea table

table vhea {
    VertTypoAscender <number>;
    VertTypoDescender <number>;
    VertTypoLineGap <number>;
} vhea;

For example:

table vhea {
    VertTypoAscender 500;
    VertTypoDescender -500;
    VertTypoLineGap 1000;
} vhea;

9.h. vmtx table

In OpenType, each glyph may have a unique vertical origin y coordinate and a unique vertical advance width. By default, for each glyph the vertical origin y coordinate is set to the value of the OS/2.TypoAscender field, and the vertical advance width is set to the distance between the values of the of OS/2.TypoAscender and the OS/2.TypoDescender. However, other values may be assigned to a glyph as follows:

table vmtx {
    VertOriginY <glyph> <number1>;
    VertAdvanceY <glyph> <number2>;
} vmtx;

This would result in the glyph’s vertical origin y coordinate and the glyph’s vertical advance width being set as shown. The value set here for the vertical origin y coordinate will also set the topSideBearing value in the vmtx table and the vertical origin y value in the VORG table for the named glyph.

For example:

table vmtx {
    VertOriginY \711 864;
    VertOriginY \712 867;
    VertOriginY \713 866;
} vmtx;

A special case for the vertical advance width is the set of glyphs referenced by the vrt2 feature. The default vertical advance for these glyphs is the horizontal advance of their corresponding target (upright) glyphs. These values will also be overridden by VertAdvanceY values.

9.i. STAT table

The STAT table is organized as follows:

table STAT {
    # Elided fallback name
    # Design axes
    # Axis values
} STAT;

Elided fallback name

Elided fallback name must be defined and at most once. It can be defined using full name entries or an existing name ID.

ElidedFallbackName {
    name <name spec>;+
};

The syntax for the individual name string entries is similar to that of the name table nameID entries (see §9.e) - the only difference is that the introductory keyword is name, and the name ID value is omitted, since the name ID value is auto-generated by the feature compiler.

Alternatively, if the name string matches one of the pre-existing names in the name table, the name ID can be specified directly and it must be be present in the name table.

ElidedFallbackNameID <name ID>;

Design axes

All of the design axes defined in the fvar table must be present in the STAT table as well, but the order is not required to be the same. The STAT table may also contain additional design axes not defined in the fvar.

DesignAxis <axisTag> <axisOrdering> {
    name <name spec>;+
};+

axisTag is a four-letter tag. axisOrdering is a signed number.

The syntax for individual name string entries is the same as above.

Axis values

There can be one or more axis values specified in the STAT table.

AxisValue {
    flag <FLAG>+ ;
    name <name string>;+
    location ...;+
};+

flag is optional, and defaults to 0 when omitted. Possible flags are ElidableAxisValueName and OlderSiblingFontAttribute, and more than one flag can be specified, for example:

flag ElidableAxisValueName OlderSiblingFontAttribute;

The location statement takes several formats:

location format A (used in Axis value table Format 1 and Format 4)
location <axisTag> <value>;+

axisTag is a 4-letter tag and must correspond to one of the defined design axes in the table. value is a signed number specified as decimal (with optional fractional part) in the range -32767.0 to +32767.99998.

With a single location statement the AxisValue will be format 1. If there are more than one location statements the AxisValue will be format 4.

location format B (used in Axis value table Format 2)
location <axisTag> <nominalValue> <rangeMinValue> <rangeMaxValue>;

Format for axisTag and the other values as above. To specify an open ended range use -32767 to mean negative infinity and 32767.99998 to mean positive infinity. For example, the following AxisValue definitions mean that “Regular” on the wght axis is defined with a nominal value of 400 and a range covering all possible values below 400 up to and including 649. “Bold” is defined with a nominal value of 700 and a range covering all values from 650 and above.

   AxisValue {
      location wght 400 -32768 650;
      name "Regular";
   AxisValue {
      location wght 700 650 32767.99998;
      name "Bold";
   };

There can be only one location statement when this format is used (the axis value will be STAT format 2 AxisValue).

location format C (used in Axis value table Format 3)
location <axisTag> <value> <linkedValue>;

Format for axisTag and the other values as above.

In the following example the linkedValue is used to style-link “Regular” and “Bold”.

   AxisValue {
      location wght 400 700;
      name "Regular";
   AxisValue {
      location wght 700;
      name "Bold";
   };

There can be only one location statement when this format is used (the axis value will be STAT format 3 AxisValue).

Example 1:

These examples are for illustrative purposes only; they won’t all be in a single STAT table. See Example 2 for a fully defined STAT table.

table STAT {
    ElidedFallbackName { name "Regular"; };

    DesignAxis wght 0 { name "Weight"; };
    DesignAxis ital 1 { name "Italic"; };

    # format 1
    AxisValue {
        location wght 400;
        name "Regular";
        name 3 1 0x411 "\5B9A\671F\7684";
        flag ElidableAxisValueName;
    };

    # format 2
    AxisValue {
        location wght 400 300 500;
        name "Regular";
        flag ElidableAxisValueName;
    };

    # format 3
    AxisValue {
        location wght 400 700;
        name "Regular";
        flag ElidableAxisValueName;
    };

    # format 3
    AxisValue {
        location ital 0 1;
        name "Regular";
        flag ElidableAxisValueName;
    };

    # format 4
    AxisValue {
        location wght 500;
        location ital 1;
        name "MediumItalic";
        flag ElidableAxisValueName;
    };
} STAT;

Example 2:

This example shows two fully defined STAT tables with three axes in format 2. These link an Upright variable font and an Italic variable font with the ital axis.

For Upright:

table STAT {

   ElidedFallbackName { name "Regular"; };

   DesignAxis opsz 0 { name "Optical Size"; };
   DesignAxis wght 1 { name "Weight"; };
   DesignAxis ital 2 { name "Italic"; };

    AxisValue {
        location wght 200 200 250;
        name "ExtraLight";
    };

    AxisValue {
        location wght 300 250 350;
        name "Light";
    };

    AxisValue {
        location wght 400 350 450;
        name "Regular";
        flag ElidableAxisValueName;
    };

    AxisValue {
        location wght 500 450 550;
        name "Medium";
        flag ElidableAxisValueName;
    };

    AxisValue {
        location wght 600 550 650;
        name "Semibold";
    };

    AxisValue {
        location wght 700 650 750;
        name "Bold";
    };

    AxisValue {
        location wght 800 750 850;
        name "ExtraBold";
    };
    
    AxisValue {
        location wght 900 850 900;
        name "Black";
    };

    AxisValue {
        location opsz 6 5 8;
        name "Caption";
    };
    
    AxisValue {
        location opsz 10 8 24;
        name "Text";
        flag ElidableAxisValueName;
    };
    
    AxisValue {
        location opsz 60 24 100;
        name "Display";
    };
    
    AxisValue {
        location ital 0 1;
        name "Roman";
        flag ElidableAxisValueName;
    };

} STAT;

For Italic:

table STAT {

   ElidedFallbackName { name "Italic"; };

   DesignAxis opsz 0 { name "Optical Size"; };
   DesignAxis wght 1 { name "Weight"; };
   DesignAxis ital 2 { name "Italic"; };

    AxisValue {
        location wght 200 200 250;
        name "ExtraLight";
    };

    AxisValue {
        location wght 300 250 350;
        name "Light";
    };

    AxisValue {
        location wght 400 350 450;
        name "Regular";
        flag ElidableAxisValueName;
    };

    AxisValue {
        location wght 500 450 550;
        name "Medium";
        flag ElidableAxisValueName;
    };

    AxisValue {
        location wght 600 550 650;
        name "Semibold";
    };

    AxisValue {
        location wght 700 650 750;
        name "Bold";
    };

    AxisValue {
        location wght 800 750 850;
        name "ExtraBold";
    };
    
    AxisValue {
        location wght 900 850 900;
        name "Black";
    };

    AxisValue {
        location opsz 6 5 8;
        name "Caption";
    };
    
    AxisValue {
        location opsz 10 8 24;
        name "Text";
        flag ElidableAxisValueName;
    };
    
    AxisValue {
        location opsz 60 24 100;
        name "Display";
    };
    
    AxisValue {
        location ital 1 0;
        name "Italic";
        flag ElidableAxisValueName;
    };

} STAT;

10. Specifying anonymous data blocks

The feature file can contain anonymous tagged blocks of data that must be passed back to the client of the implementation software. These blocks of data typically contain information needed to specify custom or unsupported tables. The parser will not attempt to parse the data. Each such block is specified as follows:

anonymous <tag> {
    # ...
} <tag>;

Note: The keyword anonymous can be abbreviated as anon. For example:

anon sbit {
    /* sbit table specifications */
    72  % dpi
    sizes {
        10, 12, 14 source {
            all "Generic/JGeneric"
        }
    }
} sbit;

The closing brace, tag, and semicolon must all be on the same line to indicate the end of the anonymous block to the parser. White space may be used between tokens on this line, and a comment may follow the semicolon. The include directive will not be recognized within the block, starting from anonymous and ending at the end of the closing line, so the entire block must exist within the same file.

The data that is passed back to the client starts at the beginning of the line after the opening brace and ends at (and includes) the newline before the closing brace. In the example above, the client is passed back the following data:

/* sbit table specifications */
72  % dpi
sizes {
   10, 12, 14 source {
      all "Generic/JGeneric"
   }
}

along with the tag sbit.

11. Document revisions

v1.26 [7 June 2021]:

v1.25.1 [5 July 2020]:

v1.25.0 [22 May 2020]:

v1.24 [21 Mar 2019]:

v1.23 [1 Oct 2018]:

v1.22 [20 July 2018]:

v1.21.1 [24 Jun 2018]:

v1.21 [7 Nov 2017]:

v1.20 [6 Feb 2017]:

v1.19 [26 April 2016]:

v1.18 [16 Mar 2016]:

v1.17 [6 Jan 2016]:

v1.16 [9 Dec 2015]:

v1.15 [12 June 2015]:

v1.14 [16 April 2015]:

v1.13 [28 July 2014]:

v1.12 [21 March 2014]:

v1.11 [4 Sept 2012]:

v1.10 [31 March 2010]:

v1.9 [4 May 2009]:

v1.8 [16 Dec 2008]:

v1.7 [25 Oct 2006]:

v1.6 [28 March 2006]:

v1.5 [23 November 2005]:

v1.4 [23 January 2003; supported by HOT library v01.00.36]:

v1.3 [23 May 2002]:

v1.2 [7 March 2001; HOT library v01.00.29]:

Note: Of the above changes, only value record format B in a Single Pos statement is actually implemented. For example, pos a 80 0 -160 0; was changed to pos a <80 0 -160 0>;. Previous syntax will still be handled correctly, but a message will be emitted encouraging users to update the syntax.

v1.1 [1 December 2000; HOT library v01.00.28]:

v1.0 [29 September 2000; HOT library v01.00.24]:

v0.9 [25 April 2000; HOT library v01.00.23]:

v0.8 [24 February 2000; HOT library v01.00.23]:

v0.7 [11 October 1999; HOT library v01.00.22]:

v0.6 [22 March 1999; HOT library v119]:

v0.5 [29 January 1999]:

v0.4 [20 January 1999]:

v0.3 [9 October 1998]:

v0.2 [18 March 1998]:

v0.1 [6 February 1998]: First version