/* * Copyright 2016 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkPDFMakeCIDGlyphWidthsArray.h" #include "SkBitSet.h" #include "SkGlyphCache.h" #include "SkPaint.h" #include "SkTo.h" // TODO(halcanary): Write unit tests for SkPDFMakeCIDGlyphWidthsArray(). // TODO(halcanary): The logic in this file originated in several // disparate places. I feel sure that someone could simplify this // down to a single easy-to-read function. namespace { struct AdvanceMetric { enum MetricType { kDefault, // Default advance: fAdvance.count = 1 kRange, // Advances for a range: fAdvance.count = fEndID-fStartID kRun // fStartID-fEndID have same advance: fAdvance.count = 1 }; MetricType fType; uint16_t fStartId; uint16_t fEndId; SkTDArray fAdvance; AdvanceMetric(uint16_t startId) : fStartId(startId) {} AdvanceMetric(AdvanceMetric&&) = default; AdvanceMetric& operator=(AdvanceMetric&& other) = default; AdvanceMetric(const AdvanceMetric&) = delete; AdvanceMetric& operator=(const AdvanceMetric&) = delete; }; const int16_t kInvalidAdvance = SK_MinS16; const int16_t kDontCareAdvance = SK_MinS16 + 1; } // namespace // scale from em-units to base-1000, returning as a SkScalar static SkScalar from_font_units(SkScalar scaled, uint16_t emSize) { if (emSize == 1000) { return scaled; } else { return scaled * 1000 / emSize; } } static SkScalar scale_from_font_units(int16_t val, uint16_t emSize) { return from_font_units(SkIntToScalar(val), emSize); } static void strip_uninteresting_trailing_advances_from_range( AdvanceMetric* range) { SkASSERT(range); int expectedAdvanceCount = range->fEndId - range->fStartId + 1; if (range->fAdvance.count() < expectedAdvanceCount) { return; } for (int i = expectedAdvanceCount - 1; i >= 0; --i) { if (range->fAdvance[i] != kDontCareAdvance && range->fAdvance[i] != kInvalidAdvance && range->fAdvance[i] != 0) { range->fEndId = range->fStartId + i; break; } } } static void zero_wildcards_in_range(AdvanceMetric* range) { SkASSERT(range); if (range->fType != AdvanceMetric::kRange) { return; } SkASSERT(range->fAdvance.count() == range->fEndId - range->fStartId + 1); // Zero out wildcards. for (int i = 0; i < range->fAdvance.count(); ++i) { if (range->fAdvance[i] == kDontCareAdvance) { range->fAdvance[i] = 0; } } } static void finish_range( AdvanceMetric* range, int endId, AdvanceMetric::MetricType type) { range->fEndId = endId; range->fType = type; strip_uninteresting_trailing_advances_from_range(range); int newLength; if (type == AdvanceMetric::kRange) { newLength = range->fEndId - range->fStartId + 1; } else { if (range->fEndId == range->fStartId) { range->fType = AdvanceMetric::kRange; } newLength = 1; } SkASSERT(range->fAdvance.count() >= newLength); range->fAdvance.setCount(newLength); zero_wildcards_in_range(range); } static void compose_advance_data(const AdvanceMetric& range, uint16_t emSize, int16_t* defaultAdvance, SkPDFArray* result) { switch (range.fType) { case AdvanceMetric::kDefault: { SkASSERT(range.fAdvance.count() == 1); *defaultAdvance = range.fAdvance[0]; break; } case AdvanceMetric::kRange: { auto advanceArray = sk_make_sp(); for (int j = 0; j < range.fAdvance.count(); j++) advanceArray->appendScalar( scale_from_font_units(range.fAdvance[j], emSize)); result->appendInt(range.fStartId); result->appendObject(std::move(advanceArray)); break; } case AdvanceMetric::kRun: { SkASSERT(range.fAdvance.count() == 1); result->appendInt(range.fStartId); result->appendInt(range.fEndId); result->appendScalar( scale_from_font_units(range.fAdvance[0], emSize)); break; } } } /** Retrieve advance data for glyphs. Used by the PDF backend. */ // TODO(halcanary): this function is complex enough to need its logic // tested with unit tests. sk_sp SkPDFMakeCIDGlyphWidthsArray(SkGlyphCache* cache, const SkBitSet* subset, uint16_t emSize, int16_t* defaultAdvance) { // Assuming that on average, the ASCII representation of an advance plus // a space is 8 characters and the ASCII representation of a glyph id is 3 // characters, then the following cut offs for using different range types // apply: // The cost of stopping and starting the range is 7 characers // a. Removing 4 0's or don't care's is a win // The cost of stopping and starting the range plus a run is 22 // characters // b. Removing 3 repeating advances is a win // c. Removing 2 repeating advances and 3 don't cares is a win // When not currently in a range the cost of a run over a range is 16 // characaters, so: // d. Removing a leading 0/don't cares is a win because it is omitted // e. Removing 2 repeating advances is a win auto result = sk_make_sp(); int num_glyphs = SkToInt(cache->getGlyphCount()); bool prevRange = false; int16_t lastAdvance = kInvalidAdvance; int repeatedAdvances = 0; int wildCardsInRun = 0; int trailingWildCards = 0; // Limit the loop count to glyph id ranges provided. int lastIndex = num_glyphs; if (subset) { while (!subset->has(lastIndex - 1) && lastIndex > 0) { --lastIndex; } } AdvanceMetric curRange(0); for (int gId = 0; gId <= lastIndex; gId++) { int16_t advance = kInvalidAdvance; if (gId < lastIndex) { if (!subset || 0 == gId || subset->has(gId)) { advance = (int16_t)cache->getGlyphIDAdvance(gId).fAdvanceX; } else { advance = kDontCareAdvance; } } if (advance == lastAdvance) { repeatedAdvances++; trailingWildCards = 0; } else if (advance == kDontCareAdvance) { wildCardsInRun++; trailingWildCards++; } else if (curRange.fAdvance.count() == repeatedAdvances + 1 + wildCardsInRun) { // All in run. if (lastAdvance == 0) { curRange.fStartId = gId; // reset curRange.fAdvance.setCount(0); trailingWildCards = 0; } else if (repeatedAdvances + 1 >= 2 || trailingWildCards >= 4) { finish_range(&curRange, gId - 1, AdvanceMetric::kRun); compose_advance_data(curRange, emSize, defaultAdvance, result.get()); prevRange = true; curRange = AdvanceMetric(gId); trailingWildCards = 0; } repeatedAdvances = 0; wildCardsInRun = trailingWildCards; trailingWildCards = 0; } else { if (lastAdvance == 0 && repeatedAdvances + 1 + wildCardsInRun >= 4) { finish_range(&curRange, gId - repeatedAdvances - wildCardsInRun - 2, AdvanceMetric::kRange); compose_advance_data(curRange, emSize, defaultAdvance, result.get()); prevRange = true; curRange = AdvanceMetric(gId); trailingWildCards = 0; } else if (trailingWildCards >= 4 && repeatedAdvances + 1 < 2) { finish_range(&curRange, gId - trailingWildCards - 1, AdvanceMetric::kRange); compose_advance_data(curRange, emSize, defaultAdvance, result.get()); prevRange = true; curRange = AdvanceMetric(gId); trailingWildCards = 0; } else if (lastAdvance != 0 && (repeatedAdvances + 1 >= 3 || (repeatedAdvances + 1 >= 2 && wildCardsInRun >= 3))) { finish_range(&curRange, gId - repeatedAdvances - wildCardsInRun - 2, AdvanceMetric::kRange); compose_advance_data(curRange, emSize, defaultAdvance, result.get()); curRange = AdvanceMetric(gId - repeatedAdvances - wildCardsInRun - 1); curRange.fAdvance.append(1, &lastAdvance); finish_range(&curRange, gId - 1, AdvanceMetric::kRun); compose_advance_data(curRange, emSize, defaultAdvance, result.get()); prevRange = true; curRange = AdvanceMetric(gId); trailingWildCards = 0; } repeatedAdvances = 0; wildCardsInRun = trailingWildCards; trailingWildCards = 0; } curRange.fAdvance.append(1, &advance); if (advance != kDontCareAdvance) { lastAdvance = advance; } } if (curRange.fStartId == lastIndex) { if (!prevRange) { return nullptr; // https://crbug.com/567031 } } else { finish_range(&curRange, lastIndex - 1, AdvanceMetric::kRange); compose_advance_data(curRange, emSize, defaultAdvance, result.get()); } return result; }