""" Partially instantiate a variable font. The module exports an `instantiateVariableFont` function and CLI that allow to create full instances (i.e. static fonts) from variable fonts, as well as "partial" variable fonts that only contain a subset of the original variation space. For example, if you wish to pin the width axis to a given location while also restricting the weight axis to 400..700 range, you can do: $ fonttools varLib.instancer ./NotoSans-VF.ttf wdth=85 wght=400:700 See `fonttools varLib.instancer --help` for more info on the CLI options. The module's entry point is the `instantiateVariableFont` function, which takes a TTFont object and a dict specifying either axis coodinates or (min, max) ranges, and returns a new TTFont representing either a partial VF, or full instance if all the VF axes were given an explicit coordinate. E.g. here's how to pin the wght axis at a given location in a wght+wdth variable font, keeping only the deltas associated with the wdth axis: | >>> from fontTools import ttLib | >>> from fontTools.varLib import instancer | >>> varfont = ttLib.TTFont("path/to/MyVariableFont.ttf") | >>> [a.axisTag for a in varfont["fvar"].axes] # the varfont's current axes | ['wght', 'wdth'] | >>> partial = instancer.instantiateVariableFont(varfont, {"wght": 300}) | >>> [a.axisTag for a in partial["fvar"].axes] # axes left after pinning 'wght' | ['wdth'] If the input location specifies all the axes, the resulting instance is no longer 'variable' (same as using fontools varLib.mutator): | >>> instance = instancer.instantiateVariableFont( | ... varfont, {"wght": 700, "wdth": 67.5} | ... ) | >>> "fvar" not in instance | True If one just want to drop an axis at the default location, without knowing in advance what the default value for that axis is, one can pass a `None` value: | >>> instance = instancer.instantiateVariableFont(varfont, {"wght": None}) | >>> len(varfont["fvar"].axes) | 1 From the console script, this is equivalent to passing `wght=drop` as input. This module is similar to fontTools.varLib.mutator, which it's intended to supersede. Note that, unlike varLib.mutator, when an axis is not mentioned in the input location, the varLib.instancer will keep the axis and the corresponding deltas, whereas mutator implicitly drops the axis at its default coordinate. The module currently supports only the first three "levels" of partial instancing, with the rest planned to be implemented in the future, namely: L1) dropping one or more axes while leaving the default tables unmodified; L2) dropping one or more axes while pinning them at non-default locations; L3) restricting the range of variation of one or more axes, by setting either a new minimum or maximum, potentially -- though not necessarily -- dropping entire regions of variations that fall completely outside this new range. L4) moving the default location of an axis. Currently only TrueType-flavored variable fonts (i.e. containing 'glyf' table) are supported, but support for CFF2 variable fonts will be added soon. The discussion and implementation of these features are tracked at https://github.com/fonttools/fonttools/issues/1537 """ from fontTools.misc.fixedTools import ( floatToFixedToFloat, strToFixedToFloat, otRound, MAX_F2DOT14, ) from fontTools.varLib.models import supportScalar, normalizeValue, piecewiseLinearMap from fontTools.ttLib import TTFont from fontTools.ttLib.tables.TupleVariation import TupleVariation from fontTools.ttLib.tables import _g_l_y_f from fontTools import varLib # we import the `subset` module because we use the `prune_lookups` method on the GSUB # table class, and that method is only defined dynamically upon importing `subset` from fontTools import subset # noqa: F401 from fontTools.varLib import builder from fontTools.varLib.mvar import MVAR_ENTRIES from fontTools.varLib.merger import MutatorMerger from fontTools.varLib.instancer import names from contextlib import contextmanager import collections from copy import deepcopy from enum import IntEnum import logging from itertools import islice import os import re log = logging.getLogger("fontTools.varLib.instancer") class AxisRange(collections.namedtuple("AxisRange", "minimum maximum")): def __new__(cls, *args, **kwargs): self = super().__new__(cls, *args, **kwargs) if self.minimum > self.maximum: raise ValueError( f"Range minimum ({self.minimum:g}) must be <= maximum ({self.maximum:g})" ) return self def __repr__(self): return f"{type(self).__name__}({self.minimum:g}, {self.maximum:g})" class NormalizedAxisRange(AxisRange): def __new__(cls, *args, **kwargs): self = super().__new__(cls, *args, **kwargs) if self.minimum < -1.0 or self.maximum > 1.0: raise ValueError("Axis range values must be normalized to -1..+1 range") if self.minimum > 0: raise ValueError(f"Expected axis range minimum <= 0; got {self.minimum}") if self.maximum < 0: raise ValueError(f"Expected axis range maximum >= 0; got {self.maximum}") return self class OverlapMode(IntEnum): KEEP_AND_DONT_SET_FLAGS = 0 KEEP_AND_SET_FLAGS = 1 REMOVE = 2 def instantiateTupleVariationStore( variations, axisLimits, origCoords=None, endPts=None ): """Instantiate TupleVariation list at the given location, or limit axes' min/max. The 'variations' list of TupleVariation objects is modified in-place. The 'axisLimits' (dict) maps axis tags (str) to either a single coordinate along the axis (float), or to minimum/maximum coordinates (NormalizedAxisRange). A 'full' instance (i.e. static font) is produced when all the axes are pinned to single coordinates; a 'partial' instance (i.e. a less variable font) is produced when some of the axes are omitted, or restricted with a new range. Tuples that do not participate are kept as they are. Those that have 0 influence at the given location are removed from the variation store. Those that are fully instantiated (i.e. all their axes are being pinned) are also removed from the variation store, their scaled deltas accummulated and returned, so that they can be added by the caller to the default instance's coordinates. Tuples that are only partially instantiated (i.e. not all the axes that they participate in are being pinned) are kept in the store, and their deltas multiplied by the scalar support of the axes to be pinned at the desired location. Args: variations: List[TupleVariation] from either 'gvar' or 'cvar'. axisLimits: Dict[str, Union[float, NormalizedAxisRange]]: axes' coordinates for the full or partial instance, or ranges for restricting an axis' min/max. origCoords: GlyphCoordinates: default instance's coordinates for computing 'gvar' inferred points (cf. table__g_l_y_f.getCoordinatesAndControls). endPts: List[int]: indices of contour end points, for inferring 'gvar' deltas. Returns: List[float]: the overall delta adjustment after applicable deltas were summed. """ pinnedLocation, axisRanges = splitAxisLocationAndRanges( axisLimits, rangeType=NormalizedAxisRange ) newVariations = variations if pinnedLocation: newVariations = pinTupleVariationAxes(variations, pinnedLocation) if axisRanges: newVariations = limitTupleVariationAxisRanges(newVariations, axisRanges) mergedVariations = collections.OrderedDict() for var in newVariations: # compute inferred deltas only for gvar ('origCoords' is None for cvar) if origCoords is not None: var.calcInferredDeltas(origCoords, endPts) # merge TupleVariations with overlapping "tents" axes = frozenset(var.axes.items()) if axes in mergedVariations: mergedVariations[axes] += var else: mergedVariations[axes] = var # drop TupleVariation if all axes have been pinned (var.axes.items() is empty); # its deltas will be added to the default instance's coordinates defaultVar = mergedVariations.pop(frozenset(), None) for var in mergedVariations.values(): var.roundDeltas() variations[:] = list(mergedVariations.values()) return defaultVar.coordinates if defaultVar is not None else [] def pinTupleVariationAxes(variations, location): newVariations = [] for var in variations: # Compute the scalar support of the axes to be pinned at the desired location, # excluding any axes that we are not pinning. # If a TupleVariation doesn't mention an axis, it implies that the axis peak # is 0 (i.e. the axis does not participate). support = {axis: var.axes.pop(axis, (-1, 0, +1)) for axis in location} scalar = supportScalar(location, support) if scalar == 0.0: # no influence, drop the TupleVariation continue var.scaleDeltas(scalar) newVariations.append(var) return newVariations def limitTupleVariationAxisRanges(variations, axisRanges): for axisTag, axisRange in sorted(axisRanges.items()): newVariations = [] for var in variations: newVariations.extend(limitTupleVariationAxisRange(var, axisTag, axisRange)) variations = newVariations return variations def _negate(*values): yield from (-1 * v for v in values) def limitTupleVariationAxisRange(var, axisTag, axisRange): if not isinstance(axisRange, NormalizedAxisRange): axisRange = NormalizedAxisRange(*axisRange) # skip when current axis is missing (i.e. doesn't participate), or when the # 'tent' isn't fully on either the negative or positive side lower, peak, upper = var.axes.get(axisTag, (-1, 0, 1)) if peak == 0 or lower > peak or peak > upper or (lower < 0 and upper > 0): return [var] negative = lower < 0 if negative: if axisRange.minimum == -1.0: return [var] elif axisRange.minimum == 0.0: return [] else: if axisRange.maximum == 1.0: return [var] elif axisRange.maximum == 0.0: return [] limit = axisRange.minimum if negative else axisRange.maximum # Rebase axis bounds onto the new limit, which then becomes the new -1.0 or +1.0. # The results are always positive, because both dividend and divisor are either # all positive or all negative. newLower = lower / limit newPeak = peak / limit newUpper = upper / limit # for negative TupleVariation, swap lower and upper to simplify procedure if negative: newLower, newUpper = newUpper, newLower # special case when innermost bound == peak == limit if newLower == newPeak == 1.0: var.axes[axisTag] = (-1.0, -1.0, -1.0) if negative else (1.0, 1.0, 1.0) return [var] # case 1: the whole deltaset falls outside the new limit; we can drop it elif newLower >= 1.0: return [] # case 2: only the peak and outermost bound fall outside the new limit; # we keep the deltaset, update peak and outermost bound and and scale deltas # by the scalar value for the restricted axis at the new limit. elif newPeak >= 1.0: scalar = supportScalar({axisTag: limit}, {axisTag: (lower, peak, upper)}) var.scaleDeltas(scalar) newPeak = 1.0 newUpper = 1.0 if negative: newLower, newPeak, newUpper = _negate(newUpper, newPeak, newLower) var.axes[axisTag] = (newLower, newPeak, newUpper) return [var] # case 3: peak falls inside but outermost limit still fits within F2Dot14 bounds; # we keep deltas as is and only scale the axes bounds. Deltas beyond -1.0 # or +1.0 will never be applied as implementations must clamp to that range. elif newUpper <= 2.0: if negative: newLower, newPeak, newUpper = _negate(newUpper, newPeak, newLower) elif MAX_F2DOT14 < newUpper <= 2.0: # we clamp +2.0 to the max F2Dot14 (~1.99994) for convenience newUpper = MAX_F2DOT14 var.axes[axisTag] = (newLower, newPeak, newUpper) return [var] # case 4: new limit doesn't fit; we need to chop the deltaset into two 'tents', # because the shape of a triangle with part of one side cut off cannot be # represented as a triangle itself. It can be represented as sum of two triangles. # NOTE: This increases the file size! else: # duplicate the tent, then adjust lower/peak/upper so that the outermost limit # of the original tent is +/-2.0, whereas the new tent's starts as the old # one peaks and maxes out at +/-1.0. newVar = TupleVariation(var.axes, var.coordinates) if negative: var.axes[axisTag] = (-2.0, -1 * newPeak, -1 * newLower) newVar.axes[axisTag] = (-1.0, -1.0, -1 * newPeak) else: var.axes[axisTag] = (newLower, newPeak, MAX_F2DOT14) newVar.axes[axisTag] = (newPeak, 1.0, 1.0) # the new tent's deltas are scaled by the difference between the scalar value # for the old tent at the desired limit... scalar1 = supportScalar({axisTag: limit}, {axisTag: (lower, peak, upper)}) # ... and the scalar value for the clamped tent (with outer limit +/-2.0), # which can be simplified like this: scalar2 = 1 / (2 - newPeak) newVar.scaleDeltas(scalar1 - scalar2) return [var, newVar] def instantiateGvarGlyph(varfont, glyphname, axisLimits, optimize=True): glyf = varfont["glyf"] coordinates, ctrl = glyf.getCoordinatesAndControls(glyphname, varfont) endPts = ctrl.endPts gvar = varfont["gvar"] # when exporting to TTX, a glyph with no variations is omitted; thus when loading # a TTFont from TTX, a glyph that's present in glyf table may be missing from gvar. tupleVarStore = gvar.variations.get(glyphname) if tupleVarStore: defaultDeltas = instantiateTupleVariationStore( tupleVarStore, axisLimits, coordinates, endPts ) if defaultDeltas: coordinates += _g_l_y_f.GlyphCoordinates(defaultDeltas) # setCoordinates also sets the hmtx/vmtx advance widths and sidebearings from # the four phantom points and glyph bounding boxes. # We call it unconditionally even if a glyph has no variations or no deltas are # applied at this location, in case the glyph's xMin and in turn its sidebearing # have changed. E.g. a composite glyph has no deltas for the component's (x, y) # offset nor for the 4 phantom points (e.g. it's monospaced). Thus its entry in # gvar table is empty; however, the composite's base glyph may have deltas # applied, hence the composite's bbox and left/top sidebearings may need updating # in the instanced font. glyf.setCoordinates(glyphname, coordinates, varfont) if not tupleVarStore: if glyphname in gvar.variations: del gvar.variations[glyphname] return if optimize: isComposite = glyf[glyphname].isComposite() for var in tupleVarStore: var.optimize(coordinates, endPts, isComposite) def instantiateGvar(varfont, axisLimits, optimize=True): log.info("Instantiating glyf/gvar tables") gvar = varfont["gvar"] glyf = varfont["glyf"] # Get list of glyph names sorted by component depth. # If a composite glyph is processed before its base glyph, the bounds may # be calculated incorrectly because deltas haven't been applied to the # base glyph yet. glyphnames = sorted( glyf.glyphOrder, key=lambda name: ( glyf[name].getCompositeMaxpValues(glyf).maxComponentDepth if glyf[name].isComposite() else 0, name, ), ) for glyphname in glyphnames: instantiateGvarGlyph(varfont, glyphname, axisLimits, optimize=optimize) if not gvar.variations: del varfont["gvar"] def setCvarDeltas(cvt, deltas): for i, delta in enumerate(deltas): if delta: cvt[i] += otRound(delta) def instantiateCvar(varfont, axisLimits): log.info("Instantiating cvt/cvar tables") cvar = varfont["cvar"] defaultDeltas = instantiateTupleVariationStore(cvar.variations, axisLimits) if defaultDeltas: setCvarDeltas(varfont["cvt "], defaultDeltas) if not cvar.variations: del varfont["cvar"] def setMvarDeltas(varfont, deltas): mvar = varfont["MVAR"].table records = mvar.ValueRecord for rec in records: mvarTag = rec.ValueTag if mvarTag not in MVAR_ENTRIES: continue tableTag, itemName = MVAR_ENTRIES[mvarTag] delta = deltas[rec.VarIdx] if delta != 0: setattr( varfont[tableTag], itemName, getattr(varfont[tableTag], itemName) + otRound(delta), ) def instantiateMVAR(varfont, axisLimits): log.info("Instantiating MVAR table") mvar = varfont["MVAR"].table fvarAxes = varfont["fvar"].axes varStore = mvar.VarStore defaultDeltas = instantiateItemVariationStore(varStore, fvarAxes, axisLimits) setMvarDeltas(varfont, defaultDeltas) if varStore.VarRegionList.Region: varIndexMapping = varStore.optimize() for rec in mvar.ValueRecord: rec.VarIdx = varIndexMapping[rec.VarIdx] else: del varfont["MVAR"] def _remapVarIdxMap(table, attrName, varIndexMapping, glyphOrder): oldMapping = getattr(table, attrName).mapping newMapping = [varIndexMapping[oldMapping[glyphName]] for glyphName in glyphOrder] setattr(table, attrName, builder.buildVarIdxMap(newMapping, glyphOrder)) # TODO(anthrotype) Add support for HVAR/VVAR in CFF2 def _instantiateVHVAR(varfont, axisLimits, tableFields): tableTag = tableFields.tableTag fvarAxes = varfont["fvar"].axes # Deltas from gvar table have already been applied to the hmtx/vmtx. For full # instances (i.e. all axes pinned), we can simply drop HVAR/VVAR and return if set( axisTag for axisTag, value in axisLimits.items() if not isinstance(value, tuple) ).issuperset(axis.axisTag for axis in fvarAxes): log.info("Dropping %s table", tableTag) del varfont[tableTag] return log.info("Instantiating %s table", tableTag) vhvar = varfont[tableTag].table varStore = vhvar.VarStore # since deltas were already applied, the return value here is ignored instantiateItemVariationStore(varStore, fvarAxes, axisLimits) if varStore.VarRegionList.Region: # Only re-optimize VarStore if the HVAR/VVAR already uses indirect AdvWidthMap # or AdvHeightMap. If a direct, implicit glyphID->VariationIndex mapping is # used for advances, skip re-optimizing and maintain original VariationIndex. if getattr(vhvar, tableFields.advMapping): varIndexMapping = varStore.optimize() glyphOrder = varfont.getGlyphOrder() _remapVarIdxMap(vhvar, tableFields.advMapping, varIndexMapping, glyphOrder) if getattr(vhvar, tableFields.sb1): # left or top sidebearings _remapVarIdxMap(vhvar, tableFields.sb1, varIndexMapping, glyphOrder) if getattr(vhvar, tableFields.sb2): # right or bottom sidebearings _remapVarIdxMap(vhvar, tableFields.sb2, varIndexMapping, glyphOrder) if tableTag == "VVAR" and getattr(vhvar, tableFields.vOrigMapping): _remapVarIdxMap( vhvar, tableFields.vOrigMapping, varIndexMapping, glyphOrder ) def instantiateHVAR(varfont, axisLimits): return _instantiateVHVAR(varfont, axisLimits, varLib.HVAR_FIELDS) def instantiateVVAR(varfont, axisLimits): return _instantiateVHVAR(varfont, axisLimits, varLib.VVAR_FIELDS) class _TupleVarStoreAdapter(object): def __init__(self, regions, axisOrder, tupleVarData, itemCounts): self.regions = regions self.axisOrder = axisOrder self.tupleVarData = tupleVarData self.itemCounts = itemCounts @classmethod def fromItemVarStore(cls, itemVarStore, fvarAxes): axisOrder = [axis.axisTag for axis in fvarAxes] regions = [ region.get_support(fvarAxes) for region in itemVarStore.VarRegionList.Region ] tupleVarData = [] itemCounts = [] for varData in itemVarStore.VarData: variations = [] varDataRegions = (regions[i] for i in varData.VarRegionIndex) for axes, coordinates in zip(varDataRegions, zip(*varData.Item)): variations.append(TupleVariation(axes, list(coordinates))) tupleVarData.append(variations) itemCounts.append(varData.ItemCount) return cls(regions, axisOrder, tupleVarData, itemCounts) def rebuildRegions(self): # Collect the set of all unique region axes from the current TupleVariations. # We use an OrderedDict to de-duplicate regions while keeping the order. uniqueRegions = collections.OrderedDict.fromkeys( ( frozenset(var.axes.items()) for variations in self.tupleVarData for var in variations ) ) # Maintain the original order for the regions that pre-existed, appending # the new regions at the end of the region list. newRegions = [] for region in self.regions: regionAxes = frozenset(region.items()) if regionAxes in uniqueRegions: newRegions.append(region) del uniqueRegions[regionAxes] if uniqueRegions: newRegions.extend(dict(region) for region in uniqueRegions) self.regions = newRegions def instantiate(self, axisLimits): defaultDeltaArray = [] for variations, itemCount in zip(self.tupleVarData, self.itemCounts): defaultDeltas = instantiateTupleVariationStore(variations, axisLimits) if not defaultDeltas: defaultDeltas = [0] * itemCount defaultDeltaArray.append(defaultDeltas) # rebuild regions whose axes were dropped or limited self.rebuildRegions() pinnedAxes = { axisTag for axisTag, value in axisLimits.items() if not isinstance(value, tuple) } self.axisOrder = [ axisTag for axisTag in self.axisOrder if axisTag not in pinnedAxes ] return defaultDeltaArray def asItemVarStore(self): regionOrder = [frozenset(axes.items()) for axes in self.regions] varDatas = [] for variations, itemCount in zip(self.tupleVarData, self.itemCounts): if variations: assert len(variations[0].coordinates) == itemCount varRegionIndices = [ regionOrder.index(frozenset(var.axes.items())) for var in variations ] varDataItems = list(zip(*(var.coordinates for var in variations))) varDatas.append( builder.buildVarData(varRegionIndices, varDataItems, optimize=False) ) else: varDatas.append( builder.buildVarData([], [[] for _ in range(itemCount)]) ) regionList = builder.buildVarRegionList(self.regions, self.axisOrder) itemVarStore = builder.buildVarStore(regionList, varDatas) # remove unused regions from VarRegionList itemVarStore.prune_regions() return itemVarStore def instantiateItemVariationStore(itemVarStore, fvarAxes, axisLimits): """Compute deltas at partial location, and update varStore in-place. Remove regions in which all axes were instanced, or fall outside the new axis limits. Scale the deltas of the remaining regions where only some of the axes were instanced. The number of VarData subtables, and the number of items within each, are not modified, in order to keep the existing VariationIndex valid. One may call VarStore.optimize() method after this to further optimize those. Args: varStore: An otTables.VarStore object (Item Variation Store) fvarAxes: list of fvar's Axis objects axisLimits: Dict[str, float] mapping axis tags to normalized axis coordinates (float) or ranges for restricting an axis' min/max (NormalizedAxisRange). May not specify coordinates/ranges for all the fvar axes. Returns: defaultDeltas: to be added to the default instance, of type dict of floats keyed by VariationIndex compound values: i.e. (outer << 16) + inner. """ tupleVarStore = _TupleVarStoreAdapter.fromItemVarStore(itemVarStore, fvarAxes) defaultDeltaArray = tupleVarStore.instantiate(axisLimits) newItemVarStore = tupleVarStore.asItemVarStore() itemVarStore.VarRegionList = newItemVarStore.VarRegionList assert itemVarStore.VarDataCount == newItemVarStore.VarDataCount itemVarStore.VarData = newItemVarStore.VarData defaultDeltas = { ((major << 16) + minor): delta for major, deltas in enumerate(defaultDeltaArray) for minor, delta in enumerate(deltas) } return defaultDeltas def instantiateOTL(varfont, axisLimits): # TODO(anthrotype) Support partial instancing of JSTF and BASE tables if ( "GDEF" not in varfont or varfont["GDEF"].table.Version < 0x00010003 or not varfont["GDEF"].table.VarStore ): return if "GPOS" in varfont: msg = "Instantiating GDEF and GPOS tables" else: msg = "Instantiating GDEF table" log.info(msg) gdef = varfont["GDEF"].table varStore = gdef.VarStore fvarAxes = varfont["fvar"].axes defaultDeltas = instantiateItemVariationStore(varStore, fvarAxes, axisLimits) # When VF are built, big lookups may overflow and be broken into multiple # subtables. MutatorMerger (which inherits from AligningMerger) reattaches # them upon instancing, in case they can now fit a single subtable (if not, # they will be split again upon compilation). # This 'merger' also works as a 'visitor' that traverses the OTL tables and # calls specific methods when instances of a given type are found. # Specifically, it adds default deltas to GPOS Anchors/ValueRecords and GDEF # LigatureCarets, and optionally deletes all VariationIndex tables if the # VarStore is fully instanced. merger = MutatorMerger( varfont, defaultDeltas, deleteVariations=(not varStore.VarRegionList.Region) ) merger.mergeTables(varfont, [varfont], ["GDEF", "GPOS"]) if varStore.VarRegionList.Region: varIndexMapping = varStore.optimize() gdef.remap_device_varidxes(varIndexMapping) if "GPOS" in varfont: varfont["GPOS"].table.remap_device_varidxes(varIndexMapping) else: # Downgrade GDEF. del gdef.VarStore gdef.Version = 0x00010002 if gdef.MarkGlyphSetsDef is None: del gdef.MarkGlyphSetsDef gdef.Version = 0x00010000 if not ( gdef.LigCaretList or gdef.MarkAttachClassDef or gdef.GlyphClassDef or gdef.AttachList or (gdef.Version >= 0x00010002 and gdef.MarkGlyphSetsDef) ): del varfont["GDEF"] def instantiateFeatureVariations(varfont, axisLimits): for tableTag in ("GPOS", "GSUB"): if tableTag not in varfont or not getattr( varfont[tableTag].table, "FeatureVariations", None ): continue log.info("Instantiating FeatureVariations of %s table", tableTag) _instantiateFeatureVariations( varfont[tableTag].table, varfont["fvar"].axes, axisLimits ) # remove unreferenced lookups varfont[tableTag].prune_lookups() def _featureVariationRecordIsUnique(rec, seen): conditionSet = [] for cond in rec.ConditionSet.ConditionTable: if cond.Format != 1: # can't tell whether this is duplicate, assume is unique return True conditionSet.append( (cond.AxisIndex, cond.FilterRangeMinValue, cond.FilterRangeMaxValue) ) # besides the set of conditions, we also include the FeatureTableSubstitution # version to identify unique FeatureVariationRecords, even though only one # version is currently defined. It's theoretically possible that multiple # records with same conditions but different substitution table version be # present in the same font for backward compatibility. recordKey = frozenset([rec.FeatureTableSubstitution.Version] + conditionSet) if recordKey in seen: return False else: seen.add(recordKey) # side effect return True def _limitFeatureVariationConditionRange(condition, axisRange): minValue = condition.FilterRangeMinValue maxValue = condition.FilterRangeMaxValue if ( minValue > maxValue or minValue > axisRange.maximum or maxValue < axisRange.minimum ): # condition invalid or out of range return values = [minValue, maxValue] for i, value in enumerate(values): if value < 0: if axisRange.minimum == 0: newValue = 0 else: newValue = value / abs(axisRange.minimum) if newValue <= -1.0: newValue = -1.0 elif value > 0: if axisRange.maximum == 0: newValue = 0 else: newValue = value / axisRange.maximum if newValue >= 1.0: newValue = 1.0 else: newValue = 0 values[i] = newValue return AxisRange(*values) def _instantiateFeatureVariationRecord( record, recIdx, location, fvarAxes, axisIndexMap ): applies = True newConditions = [] for i, condition in enumerate(record.ConditionSet.ConditionTable): if condition.Format == 1: axisIdx = condition.AxisIndex axisTag = fvarAxes[axisIdx].axisTag if axisTag in location: minValue = condition.FilterRangeMinValue maxValue = condition.FilterRangeMaxValue v = location[axisTag] if not (minValue <= v <= maxValue): # condition not met so remove entire record applies = False newConditions = None break else: # axis not pinned, keep condition with remapped axis index applies = False condition.AxisIndex = axisIndexMap[axisTag] newConditions.append(condition) else: log.warning( "Condition table {0} of FeatureVariationRecord {1} has " "unsupported format ({2}); ignored".format(i, recIdx, condition.Format) ) applies = False newConditions.append(condition) if newConditions: record.ConditionSet.ConditionTable = newConditions shouldKeep = True else: shouldKeep = False return applies, shouldKeep def _limitFeatureVariationRecord(record, axisRanges, fvarAxes): newConditions = [] for i, condition in enumerate(record.ConditionSet.ConditionTable): if condition.Format == 1: axisIdx = condition.AxisIndex axisTag = fvarAxes[axisIdx].axisTag if axisTag in axisRanges: axisRange = axisRanges[axisTag] newRange = _limitFeatureVariationConditionRange(condition, axisRange) if newRange: # keep condition with updated limits and remapped axis index condition.FilterRangeMinValue = newRange.minimum condition.FilterRangeMaxValue = newRange.maximum newConditions.append(condition) else: # condition out of range, remove entire record newConditions = None break else: newConditions.append(condition) else: newConditions.append(condition) if newConditions: record.ConditionSet.ConditionTable = newConditions shouldKeep = True else: shouldKeep = False return shouldKeep def _instantiateFeatureVariations(table, fvarAxes, axisLimits): location, axisRanges = splitAxisLocationAndRanges( axisLimits, rangeType=NormalizedAxisRange ) pinnedAxes = set(location.keys()) axisOrder = [axis.axisTag for axis in fvarAxes if axis.axisTag not in pinnedAxes] axisIndexMap = {axisTag: axisOrder.index(axisTag) for axisTag in axisOrder} featureVariationApplied = False uniqueRecords = set() newRecords = [] for i, record in enumerate(table.FeatureVariations.FeatureVariationRecord): applies, shouldKeep = _instantiateFeatureVariationRecord( record, i, location, fvarAxes, axisIndexMap ) if shouldKeep: shouldKeep = _limitFeatureVariationRecord(record, axisRanges, fvarAxes) if shouldKeep and _featureVariationRecordIsUnique(record, uniqueRecords): newRecords.append(record) if applies and not featureVariationApplied: assert record.FeatureTableSubstitution.Version == 0x00010000 for rec in record.FeatureTableSubstitution.SubstitutionRecord: table.FeatureList.FeatureRecord[rec.FeatureIndex].Feature = rec.Feature # Set variations only once featureVariationApplied = True if newRecords: table.FeatureVariations.FeatureVariationRecord = newRecords table.FeatureVariations.FeatureVariationCount = len(newRecords) else: del table.FeatureVariations def _isValidAvarSegmentMap(axisTag, segmentMap): if not segmentMap: return True if not {(-1.0, -1.0), (0, 0), (1.0, 1.0)}.issubset(segmentMap.items()): log.warning( f"Invalid avar SegmentMap record for axis '{axisTag}': does not " "include all required value maps {-1.0: -1.0, 0: 0, 1.0: 1.0}" ) return False previousValue = None for fromCoord, toCoord in sorted(segmentMap.items()): if previousValue is not None and previousValue > toCoord: log.warning( f"Invalid avar AxisValueMap({fromCoord}, {toCoord}) record " f"for axis '{axisTag}': the toCoordinate value must be >= to " f"the toCoordinate value of the preceding record ({previousValue})." ) return False previousValue = toCoord return True def instantiateAvar(varfont, axisLimits): # 'axisLimits' dict must contain user-space (non-normalized) coordinates. location, axisRanges = splitAxisLocationAndRanges(axisLimits) segments = varfont["avar"].segments # drop table if we instantiate all the axes pinnedAxes = set(location.keys()) if pinnedAxes.issuperset(segments): log.info("Dropping avar table") del varfont["avar"] return log.info("Instantiating avar table") for axis in pinnedAxes: if axis in segments: del segments[axis] # First compute the default normalization for axisRanges coordinates: i.e. # min = -1.0, default = 0, max = +1.0, and in between values interpolated linearly, # without using the avar table's mappings. # Then, for each SegmentMap, if we are restricting its axis, compute the new # mappings by dividing the key/value pairs by the desired new min/max values, # dropping any mappings that fall outside the restricted range. # The keys ('fromCoord') are specified in default normalized coordinate space, # whereas the values ('toCoord') are "mapped forward" using the SegmentMap. normalizedRanges = normalizeAxisLimits(varfont, axisRanges, usingAvar=False) newSegments = {} for axisTag, mapping in segments.items(): if not _isValidAvarSegmentMap(axisTag, mapping): continue if mapping and axisTag in normalizedRanges: axisRange = normalizedRanges[axisTag] mappedMin = floatToFixedToFloat( piecewiseLinearMap(axisRange.minimum, mapping), 14 ) mappedMax = floatToFixedToFloat( piecewiseLinearMap(axisRange.maximum, mapping), 14 ) newMapping = {} for fromCoord, toCoord in mapping.items(): if fromCoord < 0: if axisRange.minimum == 0 or fromCoord < axisRange.minimum: continue else: fromCoord /= abs(axisRange.minimum) elif fromCoord > 0: if axisRange.maximum == 0 or fromCoord > axisRange.maximum: continue else: fromCoord /= axisRange.maximum if toCoord < 0: assert mappedMin != 0 assert toCoord >= mappedMin toCoord /= abs(mappedMin) elif toCoord > 0: assert mappedMax != 0 assert toCoord <= mappedMax toCoord /= mappedMax fromCoord = floatToFixedToFloat(fromCoord, 14) toCoord = floatToFixedToFloat(toCoord, 14) newMapping[fromCoord] = toCoord newMapping.update({-1.0: -1.0, 1.0: 1.0}) newSegments[axisTag] = newMapping else: newSegments[axisTag] = mapping varfont["avar"].segments = newSegments def isInstanceWithinAxisRanges(location, axisRanges): for axisTag, coord in location.items(): if axisTag in axisRanges: axisRange = axisRanges[axisTag] if coord < axisRange.minimum or coord > axisRange.maximum: return False return True def instantiateFvar(varfont, axisLimits): # 'axisLimits' dict must contain user-space (non-normalized) coordinates location, axisRanges = splitAxisLocationAndRanges(axisLimits, rangeType=AxisRange) fvar = varfont["fvar"] # drop table if we instantiate all the axes if set(location).issuperset(axis.axisTag for axis in fvar.axes): log.info("Dropping fvar table") del varfont["fvar"] return log.info("Instantiating fvar table") axes = [] for axis in fvar.axes: axisTag = axis.axisTag if axisTag in location: continue if axisTag in axisRanges: axis.minValue, axis.maxValue = axisRanges[axisTag] axes.append(axis) fvar.axes = axes # only keep NamedInstances whose coordinates == pinned axis location instances = [] for instance in fvar.instances: if any(instance.coordinates[axis] != value for axis, value in location.items()): continue for axisTag in location: del instance.coordinates[axisTag] if not isInstanceWithinAxisRanges(instance.coordinates, axisRanges): continue instances.append(instance) fvar.instances = instances def instantiateSTAT(varfont, axisLimits): # 'axisLimits' dict must contain user-space (non-normalized) coordinates stat = varfont["STAT"].table if not stat.DesignAxisRecord or not ( stat.AxisValueArray and stat.AxisValueArray.AxisValue ): return # STAT table empty, nothing to do log.info("Instantiating STAT table") newAxisValueTables = axisValuesFromAxisLimits(stat, axisLimits) stat.AxisValueArray.AxisValue = newAxisValueTables stat.AxisValueCount = len(stat.AxisValueArray.AxisValue) def axisValuesFromAxisLimits(stat, axisLimits): location, axisRanges = splitAxisLocationAndRanges(axisLimits, rangeType=AxisRange) def isAxisValueOutsideLimits(axisTag, axisValue): if axisTag in location and axisValue != location[axisTag]: return True elif axisTag in axisRanges: axisRange = axisRanges[axisTag] if axisValue < axisRange.minimum or axisValue > axisRange.maximum: return True return False # only keep AxisValues whose axis is not pinned nor restricted, or is pinned at the # exact (nominal) value, or is restricted but the value is within the new range designAxes = stat.DesignAxisRecord.Axis newAxisValueTables = [] for axisValueTable in stat.AxisValueArray.AxisValue: axisValueFormat = axisValueTable.Format if axisValueFormat in (1, 2, 3): axisTag = designAxes[axisValueTable.AxisIndex].AxisTag if axisValueFormat == 2: axisValue = axisValueTable.NominalValue else: axisValue = axisValueTable.Value if isAxisValueOutsideLimits(axisTag, axisValue): continue elif axisValueFormat == 4: # drop 'non-analytic' AxisValue if _any_ AxisValueRecord doesn't match # the pinned location or is outside range dropAxisValueTable = False for rec in axisValueTable.AxisValueRecord: axisTag = designAxes[rec.AxisIndex].AxisTag axisValue = rec.Value if isAxisValueOutsideLimits(axisTag, axisValue): dropAxisValueTable = True break if dropAxisValueTable: continue else: log.warning("Unknown AxisValue table format (%s); ignored", axisValueFormat) newAxisValueTables.append(axisValueTable) return newAxisValueTables def setMacOverlapFlags(glyfTable): flagOverlapCompound = _g_l_y_f.OVERLAP_COMPOUND flagOverlapSimple = _g_l_y_f.flagOverlapSimple for glyphName in glyfTable.keys(): glyph = glyfTable[glyphName] # Set OVERLAP_COMPOUND bit for compound glyphs if glyph.isComposite(): glyph.components[0].flags |= flagOverlapCompound # Set OVERLAP_SIMPLE bit for simple glyphs elif glyph.numberOfContours > 0: glyph.flags[0] |= flagOverlapSimple def normalize(value, triple, avarMapping): value = normalizeValue(value, triple) if avarMapping: value = piecewiseLinearMap(value, avarMapping) # Quantize to F2Dot14, to avoid surprise interpolations. return floatToFixedToFloat(value, 14) def normalizeAxisLimits(varfont, axisLimits, usingAvar=True): fvar = varfont["fvar"] badLimits = set(axisLimits.keys()).difference(a.axisTag for a in fvar.axes) if badLimits: raise ValueError("Cannot limit: {} not present in fvar".format(badLimits)) axes = { a.axisTag: (a.minValue, a.defaultValue, a.maxValue) for a in fvar.axes if a.axisTag in axisLimits } avarSegments = {} if usingAvar and "avar" in varfont: avarSegments = varfont["avar"].segments for axis_tag, (_, default, _) in axes.items(): value = axisLimits[axis_tag] if isinstance(value, tuple): minV, maxV = value if minV > default or maxV < default: raise NotImplementedError( f"Unsupported range {axis_tag}={minV:g}:{maxV:g}; " f"can't change default position ({axis_tag}={default:g})" ) normalizedLimits = {} for axis_tag, triple in axes.items(): avarMapping = avarSegments.get(axis_tag, None) value = axisLimits[axis_tag] if isinstance(value, tuple): normalizedLimits[axis_tag] = NormalizedAxisRange( *(normalize(v, triple, avarMapping) for v in value) ) else: normalizedLimits[axis_tag] = normalize(value, triple, avarMapping) return normalizedLimits def sanityCheckVariableTables(varfont): if "fvar" not in varfont: raise ValueError("Missing required table fvar") if "gvar" in varfont: if "glyf" not in varfont: raise ValueError("Can't have gvar without glyf") # TODO(anthrotype) Remove once we do support partial instancing CFF2 if "CFF2" in varfont: raise NotImplementedError("Instancing CFF2 variable fonts is not supported yet") def populateAxisDefaults(varfont, axisLimits): if any(value is None for value in axisLimits.values()): fvar = varfont["fvar"] defaultValues = {a.axisTag: a.defaultValue for a in fvar.axes} return { axisTag: defaultValues[axisTag] if value is None else value for axisTag, value in axisLimits.items() } return axisLimits def instantiateVariableFont( varfont, axisLimits, inplace=False, optimize=True, overlap=OverlapMode.KEEP_AND_SET_FLAGS, updateFontNames=False, ): """Instantiate variable font, either fully or partially. Depending on whether the `axisLimits` dictionary references all or some of the input varfont's axes, the output font will either be a full instance (static font) or a variable font with possibly less variation data. Args: varfont: a TTFont instance, which must contain at least an 'fvar' table. Note that variable fonts with 'CFF2' table are not supported yet. axisLimits: a dict keyed by axis tags (str) containing the coordinates (float) along one or more axes where the desired instance will be located. If the value is `None`, the default coordinate as per 'fvar' table for that axis is used. The limit values can also be (min, max) tuples for restricting an axis's variation range, but this is not implemented yet. inplace (bool): whether to modify input TTFont object in-place instead of returning a distinct object. optimize (bool): if False, do not perform IUP-delta optimization on the remaining 'gvar' table's deltas. Possibly faster, and might work around rendering issues in some buggy environments, at the cost of a slightly larger file size. overlap (OverlapMode): variable fonts usually contain overlapping contours, and some font rendering engines on Apple platforms require that the `OVERLAP_SIMPLE` and `OVERLAP_COMPOUND` flags in the 'glyf' table be set to force rendering using a non-zero fill rule. Thus we always set these flags on all glyphs to maximise cross-compatibility of the generated instance. You can disable this by passing OverlapMode.KEEP_AND_DONT_SET_FLAGS. If you want to remove the overlaps altogether and merge overlapping contours and components, you can pass OverlapMode.REMOVE. Note that this requires the skia-pathops package (available to pip install). The overlap parameter only has effect when generating full static instances. updateFontNames (bool): if True, update the instantiated font's name table using the Axis Value Tables from the STAT table. The name table will be updated so it conforms to the R/I/B/BI model. If the STAT table is missing or an Axis Value table is missing for a given axis coordinate, a ValueError will be raised. """ # 'overlap' used to be bool and is now enum; for backward compat keep accepting bool overlap = OverlapMode(int(overlap)) sanityCheckVariableTables(varfont) axisLimits = populateAxisDefaults(varfont, axisLimits) normalizedLimits = normalizeAxisLimits(varfont, axisLimits) log.info("Normalized limits: %s", normalizedLimits) if not inplace: varfont = deepcopy(varfont) if updateFontNames: log.info("Updating name table") names.updateNameTable(varfont, axisLimits) if "gvar" in varfont: instantiateGvar(varfont, normalizedLimits, optimize=optimize) if "cvar" in varfont: instantiateCvar(varfont, normalizedLimits) if "MVAR" in varfont: instantiateMVAR(varfont, normalizedLimits) if "HVAR" in varfont: instantiateHVAR(varfont, normalizedLimits) if "VVAR" in varfont: instantiateVVAR(varfont, normalizedLimits) instantiateOTL(varfont, normalizedLimits) instantiateFeatureVariations(varfont, normalizedLimits) if "avar" in varfont: instantiateAvar(varfont, axisLimits) with names.pruningUnusedNames(varfont): if "STAT" in varfont: instantiateSTAT(varfont, axisLimits) instantiateFvar(varfont, axisLimits) if "fvar" not in varfont: if "glyf" in varfont: if overlap == OverlapMode.KEEP_AND_SET_FLAGS: setMacOverlapFlags(varfont["glyf"]) elif overlap == OverlapMode.REMOVE: from fontTools.ttLib.removeOverlaps import removeOverlaps log.info("Removing overlaps from glyf table") removeOverlaps(varfont) varLib.set_default_weight_width_slant( varfont, location={ axisTag: limit for axisTag, limit in axisLimits.items() if not isinstance(limit, tuple) }, ) return varfont def splitAxisLocationAndRanges(axisLimits, rangeType=AxisRange): location, axisRanges = {}, {} for axisTag, value in axisLimits.items(): if isinstance(value, rangeType): axisRanges[axisTag] = value elif isinstance(value, (int, float)): location[axisTag] = value elif isinstance(value, tuple): axisRanges[axisTag] = rangeType(*value) else: raise TypeError( f"Expected number or {rangeType.__name__}, " f"got {type(value).__name__}: {value!r}" ) return location, axisRanges def parseLimits(limits): result = {} for limitString in limits: match = re.match(r"^(\w{1,4})=(?:(drop)|(?:([^:]+)(?:[:](.+))?))$", limitString) if not match: raise ValueError("invalid location format: %r" % limitString) tag = match.group(1).ljust(4) if match.group(2): # 'drop' lbound = None else: lbound = strToFixedToFloat(match.group(3), precisionBits=16) ubound = lbound if match.group(4): ubound = strToFixedToFloat(match.group(4), precisionBits=16) if lbound != ubound: result[tag] = AxisRange(lbound, ubound) else: result[tag] = lbound return result def parseArgs(args): """Parse argv. Returns: 3-tuple (infile, axisLimits, options) axisLimits is either a Dict[str, Optional[float]], for pinning variation axes to specific coordinates along those axes (with `None` as a placeholder for an axis' default value); or a Dict[str, Tuple(float, float)], meaning limit this axis to min/max range. Axes locations are in user-space coordinates, as defined in the "fvar" table. """ from fontTools import configLogger import argparse parser = argparse.ArgumentParser( "fonttools varLib.instancer", description="Partially instantiate a variable font", ) parser.add_argument("input", metavar="INPUT.ttf", help="Input variable TTF file.") parser.add_argument( "locargs", metavar="AXIS=LOC", nargs="*", help="List of space separated locations. A location consists of " "the tag of a variation axis, followed by '=' and one of number, " "number:number or the literal string 'drop'. " "E.g.: wdth=100 or wght=75.0:125.0 or wght=drop", ) parser.add_argument( "-o", "--output", metavar="OUTPUT.ttf", default=None, help="Output instance TTF file (default: INPUT-instance.ttf).", ) parser.add_argument( "--no-optimize", dest="optimize", action="store_false", help="Don't perform IUP optimization on the remaining gvar TupleVariations", ) parser.add_argument( "--no-overlap-flag", dest="overlap", action="store_false", help="Don't set OVERLAP_SIMPLE/OVERLAP_COMPOUND glyf flags (only applicable " "when generating a full instance)", ) parser.add_argument( "--remove-overlaps", dest="remove_overlaps", action="store_true", help="Merge overlapping contours and components (only applicable " "when generating a full instance). Requires skia-pathops", ) parser.add_argument( "--update-name-table", action="store_true", help="Update the instantiated font's `name` table. Input font must have " "a STAT table with Axis Value Tables", ) loggingGroup = parser.add_mutually_exclusive_group(required=False) loggingGroup.add_argument( "-v", "--verbose", action="store_true", help="Run more verbosely." ) loggingGroup.add_argument( "-q", "--quiet", action="store_true", help="Turn verbosity off." ) options = parser.parse_args(args) if options.remove_overlaps: options.overlap = OverlapMode.REMOVE else: options.overlap = OverlapMode(int(options.overlap)) infile = options.input if not os.path.isfile(infile): parser.error("No such file '{}'".format(infile)) configLogger( level=("DEBUG" if options.verbose else "ERROR" if options.quiet else "INFO") ) try: axisLimits = parseLimits(options.locargs) except ValueError as e: parser.error(str(e)) if len(axisLimits) != len(options.locargs): parser.error("Specified multiple limits for the same axis") return (infile, axisLimits, options) def main(args=None): """Partially instantiate a variable font.""" infile, axisLimits, options = parseArgs(args) log.info("Restricting axes: %s", axisLimits) log.info("Loading variable font") varfont = TTFont(infile) isFullInstance = { axisTag for axisTag, limit in axisLimits.items() if not isinstance(limit, tuple) }.issuperset(axis.axisTag for axis in varfont["fvar"].axes) instantiateVariableFont( varfont, axisLimits, inplace=True, optimize=options.optimize, overlap=options.overlap, updateFontNames=options.update_name_table, ) outfile = ( os.path.splitext(infile)[0] + "-{}.ttf".format("instance" if isFullInstance else "partial") if not options.output else options.output ) log.info( "Saving %s font %s", "instance" if isFullInstance else "partial variable", outfile, ) varfont.save(outfile)