// 2 november 2017 #import "uipriv_darwin.h" #import "attrstr.h" // This is the part of the font style matching and normalization code // that handles fonts that use the fvar table. // // Matching stupidity: Core Text **doesn't even bother** matching // these, even if you tell it to do so explicitly. It'll always return // all variations for a given font. // // Normalization stupidity: Core Text doesn't normalize the fvar // table values for us, so we'll have to do it ourselves. Furthermore, // Core Text doesn't provide an API for accessing the avar table, if // any, so we must do so ourselves. (TODO does Core Text even // follow the avar table if a font has it?) // // Thankfully, normalization is well-defined in both TrueType and // OpenType and seems identical in both, so we can just normalize // the values and then convert them linearly to libui values for // matching. // // References: // - https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6fvar.html // - https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6avar.html // - https://www.microsoft.com/typography/otspec/fvar.htm // - https://www.microsoft.com/typography/otspec/otvaroverview.htm#CSN // - https://www.microsoft.com/typography/otspec/otff.htm // - https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6.html#Types // - https://www.microsoft.com/typography/otspec/avar.htm #define fvarWeight 0x77676874 #define fvarWidth 0x77647468 // TODO explain why these are signed typedef int32_t fixed1616; typedef int16_t fixed214; // note that Microsoft's data type list implies that *all* fixed-point types have the same format; it only gives specific examples for the 2.14 format, which confused me because I thought 16.16 worked differently, but eh static fixed1616 doubleToFixed1616(double d) { double ipart, fpart; long flong; int16_t i16; uint32_t ret; fpart = modf(d, &ipart); // fpart must be unsigned; modf() gives us fpart with the same sign as d (so we have to adjust both ipart and fpart appropriately) if (fpart < 0) { ipart -= 1; fpart = 1 + fpart; } fpart *= 65536; flong = lround(fpart); i16 = (int16_t) ipart; ret = (uint32_t) ((uint16_t) i16); ret <<= 16; ret |= (uint16_t) (flong & 0xFFFF); return (fixed1616) ret; } // see also https://stackoverflow.com/questions/8506317/fixed-point-unsigned-division-in-c and freetype's FT_DivFix() // TODO figure out the specifics of freetype's more complex implementation that shifts b and juggles signs static fixed1616 fixed1616Divide(fixed1616 a, fixed1616 b) { uint32_t u; int64_t a64; u = (uint32_t) a; a64 = (int64_t) (((uint64_t) u) << 16); return (fixed1616) (a64 / b); } static fixed214 fixed1616ToFixed214(fixed1616 f) { uint32_t t; uint32_t topbit; t = (uint32_t) (f + 0x00000002); topbit = t & 0x80000000; t >>= 2; if (topbit != 0) t |= 0xC000000; return (fixed214) (t & 0xFFFF); } static double fixed214ToDouble(fixed214 f) { uint16_t u; double base; double frac; u = (uint16_t) f; switch ((u >> 14) & 0x3) { case 0: base = 0; break; case 1: base = 1; break; case 2: base = -2; break; case 3: base = -1; } frac = ((double) (u & 0x3FFF)) / 16384; return base + frac; } static fixed1616 fixed214ToFixed1616(fixed214 f) { int32_t t; t = (int32_t) ((int16_t) f); t <<= 2; return (fixed1616) (t - 0x00000002); } static const fixed1616 fixed1616Negative1 = (int32_t) ((uint32_t) 0xFFFF0000); static const fixed1616 fixed1616Zero = 0x00000000; static const fixed1616 fixed1616Positive1 = 0x00010000; static fixed1616 fixed1616Normalize(fixed1616 val, fixed1616 min, fixed1616 max, fixed1616 def) { if (val < min) val = min; if (val > max) val = max; if (val < def) return fixed1616Divide(-(def - val), (def - min)); if (val > def) return fixed1616Divide((val - def), (max - def)); return fixed1616Zero; } static fixed214 normalizedTo214(fixed1616 val, const fixed1616 *avarMappings, size_t avarCount) { if (val < fixed1616Negative1) val = fixed1616Negative1; if (val > fixed1616Positive1) val = fixed1616Positive1; if (avarCount != 0) { size_t start, end; fixed1616 startFrom, endFrom; fixed1616 startTo, endTo; for (end = 0; end < avarCount; end += 2) { endFrom = avarMappings[end]; endTo = avarMappings[end + 1]; if (endFrom >= val) break; } if (endFrom == val) val = endTo; else { start = end - 2; startFrom = avarMappings[start]; startTo = avarMappings[start + 1]; val = fixed1616Divide((val - startFrom), (endFrom - startFrom)); // TODO find a font with an avar table and make sure this works, or if we need to use special code for this too val *= (endTo - startTo); val += startTo; } } return fixed1616ToFixed214(val); } static fixed1616 *avarExtract(CFDataRef table, CFIndex index, size_t *n) { const UInt8 *b; size_t off; size_t i, nEntries; fixed1616 *entries; fixed1616 *p; b = CFDataGetBytePtr(table); off = 8; #define nextuint16be() ((((uint16_t) (b[off])) << 8) | ((uint16_t) (b[off + 1]))) for (; index > 0; index--) { nEntries = (size_t) nextuint16be(); off += 2; off += 4 * nEntries; } nEntries = nextuint16be(); *n = nEntries * 2; entries = (fixed1616 *) uiAlloc(*n * sizeof (fixed1616), "fixed1616[]"); p = entries; for (i = 0; i < *n; i++) { *p++ = fixed214ToFixed1616((fixed214) nextuint16be()); off += 2; } return entries; } static BOOL extractAxisDictValue(CFDictionaryRef dict, CFStringRef key, fixed1616 *out) { CFNumberRef num; double v; num = (CFNumberRef) CFDictionaryGetValue(dict, key); if (CFNumberGetValue(num, kCFNumberDoubleType, &v) == false) return NO; *out = doubleToFixed1616(v); return YES; } // TODO here and elsewhere: make sure all Objective-C classes and possibly also custom method names have uipriv prefixes @interface fvarAxis : NSObject { fixed1616 min; fixed1616 max; fixed1616 def; fixed1616 *avarMappings; size_t avarCount; } - (id)initWithIndex:(CFIndex)i dict:(CFDictionaryRef)dict avarTable:(CFDataRef)table; - (double)normalize:(double)v; @end @implementation fvarAxis - (id)initWithIndex:(CFIndex)i dict:(CFDictionaryRef)dict avarTable:(CFDataRef)table { self = [super init]; if (self) { self->avarMappings = NULL; self->avarCount = 0; if (!extractAxisDictValue(dict, kCTFontVariationAxisMinimumValueKey, &(self->min))) goto fail; if (!extractAxisDictValue(dict, kCTFontVariationAxisMaximumValueKey, &(self->max))) goto fail; if (!extractAxisDictValue(dict, kCTFontVariationAxisDefaultValueKey, &(self->def))) goto fail; if (table != NULL) self->avarMappings = avarExtract(table, i, &(self->avarCount)); } return self; fail: [self release]; return nil; } - (void)dealloc { if (self->avarMappings != NULL) { uiFree(self->avarMappings); self->avarMappings = NULL; } [super dealloc]; } - (double)normalize:(double)d { fixed1616 n; fixed214 n2; n = doubleToFixed1616(d); n = fixed1616Normalize(n, self->min, self->max, self->def); n2 = normalizedTo214(n, self->avarMappings, self->avarCount); return fixed214ToDouble(n2); } @end NSDictionary *uiprivMakeVariationAxisDict(CFArrayRef axes, CFDataRef avarTable) { CFDictionaryRef axis; CFIndex i, n; NSMutableDictionary *out; n = CFArrayGetCount(axes); out = [NSMutableDictionary new]; for (i = 0; i < n; i++) { CFNumberRef key; axis = (CFDictionaryRef) CFArrayGetValueAtIndex(axes, i); key = (CFNumberRef) CFDictionaryGetValue(axis, kCTFontVariationAxisIdentifierKey); [out setObject:[[fvarAxis alloc] initWithIndex:i dict:axis avarTable:avarTable] forKey:((NSNumber *) key)]; } if (avarTable != NULL) CFRelease(avarTable); return out; } #define fvarAxisKey(n) [NSNumber numberWithUnsignedInteger:n] static BOOL tryAxis(NSDictionary *axisDict, CFDictionaryRef var, NSNumber *key, double *out) { fvarAxis *axis; CFNumberRef num; axis = (fvarAxis *) [axisDict objectForKey:key]; if (axis == nil) return NO; num = (CFNumberRef) CFDictionaryGetValue(var, (CFNumberRef) key); if (num == nil) return NO; if (CFNumberGetValue(num, kCFNumberDoubleType, out) == false) { // TODO return NO; } *out = [axis normalize:*out]; return YES; } void uiprivProcessFontVariation(uiprivFontStyleData *d, NSDictionary *axisDict, uiDrawFontDescriptor *out) { CFDictionaryRef var; double v; out->Weight = uiDrawTextWeightNormal; out->Stretch = uiDrawTextStretchNormal; var = [d variation]; if (tryAxis(axisDict, var, fvarAxisKey(fvarWeight), &v)) { // v is now a value between -1 and 1 scaled linearly between discrete points // we want a linear value between 0 and 1000 with 400 being normal if (v < 0) { v += 1; out->Weight = (uiDrawTextWeight) (v * 400); } else if (v > 0) out->Weight += (uiDrawTextWeight) (v * 600); } if (tryAxis(axisDict, var, fvarAxisKey(fvarWidth), &v)) { // likewise, but with stretches, we go from 0 to 8 with 4 being directly between the two, so this is sufficient v += 1; out->Stretch = (uiDrawTextStretch) (v * 4); } }