The axis variations table (avar
) is an optional table used in variable fonts. Version 1 of avar
modifies aspects of how a design varies for different instances along a particular design-variation axis. It does this by piecewise linear remapping on a per-axis basis, with certain restrictions. See the OpenType specification for details.
Version 2, as proposed here, enables flexible axis remapping where each design-variation axis is modified according to the coordinates of multiple design-variation axes. In order to combine the effects of multiple input values, avar
version 2 uses the OpenType variation mechanism itself to determine interpolated delta values and add them to design-variation axis coordinates.
The efficiency of avar
version 2 enables fonts that:
- are significantly smaller;
- are easier for users to control;
- simplify source maintenance by avoiding redundant data.
Use cases include:
- warped variable font designspaces to reflect a typeface designer’s intention accurately;
- parametric fonts with intuitive control methods and a much reduced data footprint;
- offering simpler methods of control for specialized variable fonts.
Type | Name | Description |
---|---|---|
uint16 |
majorVersion |
Major version number of the axis variations table — set to 2. |
uint16 |
minorVersion |
Minor version number of the axis variations table — set to 0. |
uint16 |
<reserved> |
Permanently reserved; set to zero. |
uint16 |
axisSegmentMapCount |
The number of axisSegmentMaps for this font. If this is not 0, it must be the same as axisCount in the 'fvar' table. |
SegmentMaps |
axisSegmentMaps[axisSegmentMapCount] |
The segment maps array — one segment map for each axis, in the order of axes specified in the 'fvar' table. |
Offset32To<DeltaSetIndexMap> |
axisIndexMapOffset |
Offset from beginning of the table to axisIndexMap . |
Offset32To<ItemVariationStore> |
varStoreOffset |
Offset from beginning of the table to varStore . |
The table format for avar
version 2 is the same as avar
version 1, appended with offsets to two extra structures, axisIndexMap
and varStore
, and with the data for those structures.
axisIndexMap
is a DeltaSetIndexMap structure that maps the axis indices implied in fvar
to indices used in varStore
. The outer index identifies an ItemVariationData structure in varStore
. The inner index identifies a deltaSet within an ItemVariationData.
varStore
is an ItemVariationStore structure that points to a VariationRegions array and a list of ItemVariationData structures. Each ItemVariationData specifies a subset of VariationRegions and an array of deltaSets. Each deltaSet specifies a delta value for each region.
Delta values are typically in (but not limited to) the range [-1.0, 1.0].
Delta values are stored as if they were signed integers by multiplying their true value by 16384. Thus 1.0 is stored as 16384; -1.0 is stored as -16384.
The DeltaSetIndexMap and ItemVariationStore formats are given in OpenType Font Variations Common Table Formats.
Processing of axis values in an avar
version 2 table happens in 3 stages for a given instance:
- Initial normalization to convert user coordinates of each axis to initial normalized coordinates in the range [-1.0, 1.0].
- Remap initial normalized coordinates of each axis via the axisSegmentMaps of
avar
version 1, providing intermediate coordinates also in the range [-1.0, 1.0]. - Calculate interpolated deltas for each axis via
avar
version 2 and add them to intermediate coordinates, providing final coordinates that are clamped to the range [-1,1].
In more detail, step 3 proceeds as follows. Considering the coordinates provided by step 2, a scalar is determined for each variationRegion by the usual variation interpolation algorithm. Then, the deltaSets of each ItemVariationData are processed such that each delta value is multiplied by its associated scalar. Summing those products gives an interpolated delta to add to a particular axis coordinate, the axis index being defined in axisIndexMap
. After the summing operations for all ItemVariationData structures is complete, axis values are clamped to to the range [-1.0, 1.0], giving final axis coordinates.
The final axis coordinates obtained by step 3 are subsequently used in the standard variation process described in Algorithm for Interpolation of Instance Values, applying to all gvar
data and all ItemVariationStore
data elsewhere in the font.
The following algorithm implements step 3 above, producing the final normalized axis coordinates:
// let coords be the vector of current normalized coordinates.
std::vector<int> out;
for (unsigned i = 0; i < coords.size(); i++)
{
int v = coords[i];
uint32_t varidx = i;
if (axisIdxMap != 0)
varidx = (this+axisIdxMap).map(varidx);
float delta = 0;
if (varStore != 0)
delta = (this+varStore).get_delta (varidx, coords);
v += std::roundf (delta);
v = std::clamp (v, -(1<<14), +(1<<14));
out.push_back (v);
}
for (unsigned i = 0; i < coords.size(); i++)
coords[i] = out[i];
The way ItemVariationStore
s are built is typically by using a variation modeler, that takes a series of master values at certain locations in the design-space, and produces VariationRegion
s and deltaSets
to be stored in one or more ItemVariationData
structures. This usage is identical, except that delta values apply to normalized axis coordinates rather than distances measured in font units. To build the avar
version 2 mapping tables, the designer will need to produce a mapping of input axis locations and their respective output axis locations. This data then will constitute the set of masters to be fed to the variation modeler and populate the ItemVariationStore
that will go into the avar
version 2 table. The variation index for each axis will be stored in axisIndexMap
.
In the OpenType variations specification, registered axes offer a standard way to offer users control of a variable font on reasonably well defined scales. For example, users learn that the Regular version of a font has Weight=400, Width=100, while the Bold has wght=700, wdth=100. A typical 2-axis variable font with wght
and wdth
axes might have the following nine Named Instances:
wdth=75 | wdth=100 | wdth=125 | |
---|---|---|---|
wght=300 | Light Condensed | Light | Light Extended |
wght=400 | Condensed | Regular | Extended |
wght=700 | Bold Condensed | Bold | Bold Extended |
However, in fonts with more than one design axis, this approach lacks the flexibility of older methods of interpolation, where the type designer used a font design application to specify freely the axis values for, say, the Bold Condensed. Notably, the wght
coordinate of Bold Condensed did not need to match the wght
coordinate of Bold, nor did the wdth
coordinate of Bold Condensed need to match the wdth
coordinate of Condensed. A Bold Condensed with wght
,wdth
of (677,81) rather than (700,75) was perfectly reasonable. Our grid of instances in such as case would look something like this:
Condensed | Regular | Expanded | |
---|---|---|---|
Light | 300,75 | 300,100 | 300,115 |
Regular | 400,75 | 400,100 | 400,120 |
Bold | 677,81 | 695,100 | 700,125 |
While with OpenType 1.8 it is possible to set up a designspace like this, it has the significant drawback that many applications and systems expect all Bold weights to be at wght
=700 and all Condensed weights to be at wdth
=75, whatever the values of other axes. In practice, many OpenType 1.8 fonts encode numerous additional masters that ensure the design is as intended at all designspace locations. This not only increases the data footprint significantly, but also adds to the maintenance burden of the font.
Furthermore, there are many cases where a type designer does not intend to offer instances in certain regions of the design space. For example, a Black Condensed instance is often difficult to design, and many type families omit it. Desired behaviour, in case a user requests wght
=900, wdth
=75, may be for the font to provide the same instance for the Black Condensed as it does for the Bold Condensed. Luc(as) de Groot analyses the issue in his Typo Labs 2018 talk, where he calls for “virtual masters”.
By applying deltas to axis values anywhere in the designspace, the avar
table version 2 “warps” the designspace and so resolves the issues described.
As with variation deltas in general, we also benefit from interpolation when axis values are influenced by a delta but are not exactly at the location of the delta. Each delta value is encoded as F2DOT14. Its interpolated value is determined by the standard OpenType variations algorithm, then added to the value obtained from the standard normalization process. Thus, assuming the Bold Condensed instance at (700,75) has normalized coordinates (1,-1) and assuming the designspace location (677,81) has normalized coordinates ((677-400)/(700-400), -1 + (81-75)/(100-75)) = (0.9233,-0.76), then the ItemVariationStore
needs a delta set with peaks at (-1,1), thus with region ((-1,-1,0),(0,1,1)) and the following delta values:
wght
-0.0767wdth
+0.24
In practice there may be other delta sets required at the partial default locations (-1,0) and (0,1), which then influence the delta values required at (-1,1), in line with normal variations math.
The result of implementing designspace warping this way is that we preserve the original axis values where applications and systems expect them, namely all Bold instances at wght
=700 and all Condensed weights at wdth
=75, while at the same time minimizing the data footprint.
Certain variable fonts encode delta sets in such a way that, when multiple axes are synchronized, outline points move in curves rather than in straight lines. This technique was invented by Underware and presented in 2018 under the name HOI (higher order interpolation). The details of the non-linear encoding need not concern us here, but a practical drawback under OpenType 1.8 is that it requires users to set multiple design axes to identical values in order to obtain valid instances. When axes are not synchronized, the resulting glyphs are severely distorted and useless. Synchronization using JavaScript has been proposed as a solution. A clever exploit of the CFF2 format, allowing a single axis to perform all the necessary non-linear adjustment of outline points, has also been demonstrated (but this method cannot be adapted to adjust delta values in an ItemVariationStore non-linearly).
The avar
version 2 table provides a solution to the synchonization problem, such that a user adjusts one “primary” axis and that value is cloned to other subordinate axes. Ideally the subordinate axes have the Hidden flag set in fvar
to discourage manual operation. For a font with 3 axes requiring identical values, if the first axis is considered primary, then the other two can encode delta sets in avar
’s ItemVariationStore to clone the value of the first axis. Assuming the subordinate axes have the same minimum, default and maximum values as the primary axis, each subordinate axis requires either one or two delta sets to clone the negative and positive regions of the normalized value of the primary axis:
-
If the axes use only the normalized region [0,1] then one delta set per subordinate axis is needed, referring to the region (0,1,1) of the primary axis and having the delta value of 1. This is the common case.
-
If the axes use only the normalized region [-1,0] then one delta set per subordinate axis is needed, referring to the region (-1,-1,0) of the primary axis and having the delta value of -1.
-
If the axes use both the normalized regions [-1,0] and [0,1] then two delta sets per subordinate axis are needed, one referring to the region (0,1,1) of the primary axis and having the delta value of 1, the other referring to the region (-1,-1,0) of the primary axis and having the delta value of -1.
Parametric fonts, explored by Donald Knuth and others, offer fine-tuned control of specific font-wide aspects of their design. Such aspects typically include the thickness of vertical strokes, thickness of horizontal strokes, the overall width of the font, and direct control over vertical zones including cap-height, ascender height, x-height and descender height.
In an OpenType variable font these parameters can be encoded as design-variation axes. The Type Network Variations Proposal of 2017 provides the basis for parametric OpenType fonts Amstelvar, Roboto Flex and others, demonstrating the potential for usable parametric fonts with large character sets. That flexibility comes from a designspace of many axes – sometimes 10 or more – which raises issues of control. Faced with 10 sliders, users are unlikely to be able to find the instance they want and are likely to get “lost” in a unusable region of the designspace.
In OpenType 1.8, the solution to getting “lost” is to include “blended” axes that combine the deltas of parametric axes in such a way that they function in exactly the same way as they would in a non-parametric font. The blended axes are exposed using the registered axes of wght
, wdth
, opsz
, etc., or well specified custom axes, and they are encoded in the standard OpenType 1.8 manner using gvar
and related data. The major problem with such fonts is their large data footprint, as the blended axes effectively replicate much of what the parametric axes do. For a font containing both parametric and blended axes, the problem is particularly acute, so the parametric axes may be omitted to save space — thereby removing core functionality. In such cases the parametric nature of the font is thus reduced to a convenience of sources.
The avar
table version 2 provides a method to deploy a purely parametric font with user-friendly axes, while avoiding the data bloat of blended axes. The user axes, for example wght
and wdth
, on their own do nothing (i.e. they have no gvar
or similar data), but they control the parametric axes by means of avar
. The blending of parametric values into user-facing values effectively happens live in the font engine. The parametric axes are expected to have the Hidden flag set in fvar
to discourage (but not block) manual operation.
Normally it is not possible for an application to obtain normalized axis values directly, these remaining private to the font engine. In fonts with an avar
version 2 table, however, it can be useful to know the axis values that would invoke a given instance if the font engine did not support avar
version 2. Use cases include:
- informing users of the effective settings of parametric axes;
- providing a polyfill for
avar
version 2.
The solution is for the application itself to implement the avar
algorithms, both version 1 and version 2. This requires not only access to the binary avar
table, but also knowledge of the font’s axis extents as defined in the fvar
table. Once an application has a complete set of final normalized values as defined above, the inverse of the avar
version 1 algorithm can be applied to obtain user coordinates for all axes. (Care must be taken to avoid a divide-by-zero error in implementing an inverse avar
version 1 mapping, in the case where consecutive toCoordinate
values are identical.)
Almost all fonts can provide a valid set of user axis coordinates for a given set of final normalized axis coordinates in this way. Exceptions are those fonts that encode deltas in a region that is not accessible without avar
version 2, namely those fonts where the fvar
definition of an axis normally precludes an active negative region or a active positive region by having its default equal to its minimum or its maximum respectively. Such cases are expected to be rare.
Hidden axes
Since many avar
version 2 fonts have axes not not intended for manual adjustment, it is recommended that such axes set the “hidden” flag in VariationAxisRecord
of the fvar
table.
In order to reduce proliferation of zero deltas, it is recommended to store in axisIndexMap
only those axes that are remapped by avar
version 2. For the same reason, if there are multiple different types of axis mapping affecting different sets of axes, consider using multiple ItemVariationData
structures.
-
The set of axes involved in adjusting the coordinate for a given axis may include the axis itself.
-
It is expected that implementations that handle only
avar
version 1 will ignore the entire table by rejecting themajorVersion
value.