src/third_party/woff2/src/normalize.cc - cobalt - Git at Google

 /* Copyright 2013 Google Inc. All Rights Reserved.

    Distributed under MIT license.
    See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
 */

 /* Glyph normalization */

 #include "./normalize.h"

 #include <inttypes.h>
 #include <stddef.h>

 #if !defined(STARBOARD)
 #include <cstring>
 #else
 #include "starboard/client_porting/poem/string_poem.h"
 #endif

 #include "./buffer.h"
 #include "./port.h"
 #include "./font.h"
 #include "./glyph.h"
 #include "./round.h"
 #include "./store_bytes.h"
 #include "./table_tags.h"
 #include "./woff2_common.h"

 namespace woff2 {

 namespace {

 void StoreLoca(int index_fmt, uint32_t value, size_t* offset, uint8_t* dst) {
   if (index_fmt == 0) {
     Store16(value >> 1, offset, dst);
   } else {
     StoreU32(value, offset, dst);
   }
 }

 }  // namespace

 namespace {

 bool WriteNormalizedLoca(int index_fmt, int num_glyphs, Font* font) {
   Font::Table* glyf_table = font->FindTable(kGlyfTableTag);
   Font::Table* loca_table = font->FindTable(kLocaTableTag);

   int glyph_sz = index_fmt == 0 ? 2 : 4;
   loca_table->buffer.resize(Round4(num_glyphs + 1) * glyph_sz);
   loca_table->length = (num_glyphs + 1) * glyph_sz;

   uint8_t* glyf_dst = num_glyphs ? &glyf_table->buffer[0] : NULL;
   uint8_t* loca_dst = &loca_table->buffer[0];
   uint32_t glyf_offset = 0;
   size_t loca_offset = 0;

   for (int i = 0; i < num_glyphs; ++i) {
     StoreLoca(index_fmt, glyf_offset, &loca_offset, loca_dst);
     Glyph glyph;
     const uint8_t* glyph_data;
     size_t glyph_size;
     if (!GetGlyphData(*font, i, &glyph_data, &glyph_size) ||
         (glyph_size > 0 && !ReadGlyph(glyph_data, glyph_size, &glyph))) {
       return FONT_COMPRESSION_FAILURE();
     }
     size_t glyf_dst_size = glyf_table->buffer.size() - glyf_offset;
     if (!StoreGlyph(glyph, glyf_dst + glyf_offset, &glyf_dst_size)) {
       return FONT_COMPRESSION_FAILURE();
     }
     glyf_dst_size = Round4(glyf_dst_size);
     if (glyf_dst_size > std::numeric_limits<uint32_t>::max() ||
         glyf_offset + static_cast<uint32_t>(glyf_dst_size) < glyf_offset ||
         (index_fmt == 0 && glyf_offset + glyf_dst_size >= (1UL << 17))) {
       return FONT_COMPRESSION_FAILURE();
     }
     glyf_offset += glyf_dst_size;
   }

   StoreLoca(index_fmt, glyf_offset, &loca_offset, loca_dst);

   glyf_table->buffer.resize(glyf_offset);
   glyf_table->data = glyf_offset ? &glyf_table->buffer[0] : NULL;
   glyf_table->length = glyf_offset;
   loca_table->data = loca_offset ? &loca_table->buffer[0] : NULL;

   return true;
 }

 }  // namespace

 namespace {

 bool MakeEditableBuffer(Font* font, int tableTag) {
   Font::Table* table = font->FindTable(tableTag);
   if (table == NULL) {
     return FONT_COMPRESSION_FAILURE();
   }
   if (table->IsReused()) {
     return true;
   }
   int sz = Round4(table->length);
   table->buffer.resize(sz);
   uint8_t* buf = &table->buffer[0];
   memcpy(buf, table->data, table->length);
   if (PREDICT_FALSE(sz > table->length)) {
     memset(buf + table->length, 0, sz - table->length);
   }
   table->data = buf;
   return true;
 }

 }  // namespace

 bool NormalizeGlyphs(Font* font) {
   Font::Table* head_table = font->FindTable(kHeadTableTag);
   Font::Table* glyf_table = font->FindTable(kGlyfTableTag);
   Font::Table* loca_table = font->FindTable(kLocaTableTag);
   if (head_table == NULL) {
     return FONT_COMPRESSION_FAILURE();
   }
   // If you don't have glyf/loca this transform isn't very interesting
   if (loca_table == NULL && glyf_table == NULL) {
     return true;
   }
   // It would be best if you didn't have just one of glyf/loca
   if ((glyf_table == NULL) != (loca_table == NULL)) {
     return FONT_COMPRESSION_FAILURE();
   }
   // Must share neither or both loca & glyf
   if (loca_table->IsReused() != glyf_table->IsReused()) {
     return FONT_COMPRESSION_FAILURE();
   }
   if (loca_table->IsReused()) {
     return true;
   }

   int index_fmt = head_table->data[51];
   int num_glyphs = NumGlyphs(*font);

   // We need to allocate a bit more than its original length for the normalized
   // glyf table, since it can happen that the glyphs in the original table are
   // 2-byte aligned, while in the normalized table they are 4-byte aligned.
   // That gives a maximum of 2 bytes increase per glyph. However, there is no
   // theoretical guarantee that the total size of the flags plus the coordinates
   // is the smallest possible in the normalized version, so we have to allow
   // some general overhead.
   // TODO(user) Figure out some more precise upper bound on the size of
   // the overhead.
   size_t max_normalized_glyf_size = 1.1 * glyf_table->length + 2 * num_glyphs;

   glyf_table->buffer.resize(max_normalized_glyf_size);

   // if we can't write a loca using short's (index_fmt 0)
   // try again using longs (index_fmt 1)
   if (!WriteNormalizedLoca(index_fmt, num_glyphs, font)) {
     if (index_fmt != 0) {
       return FONT_COMPRESSION_FAILURE();
     }

     // Rewrite loca with 4-byte entries & update head to match
     index_fmt = 1;
     if (!WriteNormalizedLoca(index_fmt, num_glyphs, font)) {
       return FONT_COMPRESSION_FAILURE();
     }
     head_table->buffer[51] = 1;
   }

   return true;
 }

 bool NormalizeOffsets(Font* font) {
   uint32_t offset = 12 + 16 * font->num_tables;
   for (auto tag : font->OutputOrderedTags()) {
     auto& table = font->tables[tag];
     table.offset = offset;
     offset += Round4(table.length);
   }
   return true;
 }

 namespace {

 uint32_t ComputeHeaderChecksum(const Font& font) {
   uint32_t checksum = font.flavor;
   uint16_t max_pow2 = font.num_tables ? Log2Floor(font.num_tables) : 0;
   uint16_t search_range = max_pow2 ? 1 << (max_pow2 + 4) : 0;
   uint16_t range_shift = (font.num_tables << 4) - search_range;
   checksum += (font.num_tables << 16 | search_range);
   checksum += (max_pow2 << 16 | range_shift);
   for (const auto& i : font.tables) {
     const Font::Table* table = &i.second;
     if (table->IsReused()) {
       table = table->reuse_of;
     }
     checksum += table->tag;
     checksum += table->checksum;
     checksum += table->offset;
     checksum += table->length;
   }
   return checksum;
 }

 }  // namespace

 bool FixChecksums(Font* font) {
   Font::Table* head_table = font->FindTable(kHeadTableTag);
   if (head_table == NULL) {
     return FONT_COMPRESSION_FAILURE();
   }
   if (head_table->reuse_of != NULL) {
     head_table = head_table->reuse_of;
   }
   if (head_table->length < 12) {
     return FONT_COMPRESSION_FAILURE();
   }

   uint8_t* head_buf = &head_table->buffer[0];
   size_t offset = 8;
   StoreU32(0, &offset, head_buf);
   uint32_t file_checksum = 0;
   uint32_t head_checksum = 0;
   for (auto& i : font->tables) {
     Font::Table* table = &i.second;
     if (table->IsReused()) {
       table = table->reuse_of;
     }
     table->checksum = ComputeULongSum(table->data, table->length);
     file_checksum += table->checksum;

     if (table->tag == kHeadTableTag) {
       head_checksum = table->checksum;
     }
   }

   file_checksum += ComputeHeaderChecksum(*font);
   offset = 8;
   StoreU32(0xb1b0afba - file_checksum, &offset, head_buf);

   return true;
 }

 namespace {
 bool MarkTransformed(Font* font) {
   Font::Table* head_table = font->FindTable(kHeadTableTag);
   if (head_table == NULL) {
     return FONT_COMPRESSION_FAILURE();
   }
   if (head_table->reuse_of != NULL) {
     head_table = head_table->reuse_of;
   }
   if (head_table->length < 17) {
     return FONT_COMPRESSION_FAILURE();
   }
   // set bit 11 of head table 'flags' to indicate that font has undergone
   // lossless modifying transform
   int head_flags = head_table->data[16];
   head_table->buffer[16] = head_flags | 0x08;
   return true;
 }
 }  // namespace


 bool NormalizeWithoutFixingChecksums(Font* font) {
   return (MakeEditableBuffer(font, kHeadTableTag) &&
           RemoveDigitalSignature(font) &&
           MarkTransformed(font) &&
           NormalizeGlyphs(font) &&
           NormalizeOffsets(font));
 }

 bool NormalizeFont(Font* font) {
   return (NormalizeWithoutFixingChecksums(font) &&
           FixChecksums(font));
 }

 bool NormalizeFontCollection(FontCollection* font_collection) {
   if (font_collection->fonts.size() == 1) {
     return NormalizeFont(&font_collection->fonts[0]);
   }

   uint32_t offset = CollectionHeaderSize(font_collection->header_version,
     font_collection->fonts.size());
   for (auto& font : font_collection->fonts) {
     if (!NormalizeWithoutFixingChecksums(&font)) {
 #ifdef FONT_COMPRESSION_BIN
       fprintf(stderr, "Font normalization failed.\n");
 #endif
       return FONT_COMPRESSION_FAILURE();
     }
     offset += kSfntHeaderSize + kSfntEntrySize * font.num_tables;
   }

   // Start table offsets after TTC Header and Sfnt Headers
   for (auto& font : font_collection->fonts) {
     for (auto tag : font.OutputOrderedTags()) {
       Font::Table& table = font.tables[tag];
       if (table.IsReused()) {
         table.offset = table.reuse_of->offset;
       } else {
         table.offset = offset;
         offset += Round4(table.length);
       }
     }
   }

   // Now we can fix the checksums
   for (auto& font : font_collection->fonts) {
     if (!FixChecksums(&font)) {
 #ifdef FONT_COMPRESSION_BIN
       fprintf(stderr, "Failed to fix checksums\n");
 #endif
       return FONT_COMPRESSION_FAILURE();
     }
   }

   return true;
 }

 } // namespace woff2
	/* Copyright 2013 Google Inc. All Rights Reserved.

	Distributed under MIT license.
	See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
	*/

	/* Glyph normalization */

	#include "./normalize.h"

	#include <inttypes.h>
	#include <stddef.h>

	#if !defined(STARBOARD)
	#include <cstring>
	#else
	#include "starboard/client_porting/poem/string_poem.h"
	#endif

	#include "./buffer.h"
	#include "./port.h"
	#include "./font.h"
	#include "./glyph.h"
	#include "./round.h"
	#include "./store_bytes.h"
	#include "./table_tags.h"
	#include "./woff2_common.h"

	namespace woff2 {

	namespace {

	void StoreLoca(int index_fmt, uint32_t value, size_t* offset, uint8_t* dst) {
	if (index_fmt == 0) {
	Store16(value >> 1, offset, dst);
	} else {
	StoreU32(value, offset, dst);
	}
	}

	} // namespace

	namespace {

	bool WriteNormalizedLoca(int index_fmt, int num_glyphs, Font* font) {
	Font::Table* glyf_table = font->FindTable(kGlyfTableTag);
	Font::Table* loca_table = font->FindTable(kLocaTableTag);

	int glyph_sz = index_fmt == 0 ? 2 : 4;
	loca_table->buffer.resize(Round4(num_glyphs + 1) * glyph_sz);
	loca_table->length = (num_glyphs + 1) * glyph_sz;

	uint8_t* glyf_dst = num_glyphs ? &glyf_table->buffer[0] : NULL;
	uint8_t* loca_dst = &loca_table->buffer[0];
	uint32_t glyf_offset = 0;
	size_t loca_offset = 0;

	for (int i = 0; i < num_glyphs; ++i) {
	StoreLoca(index_fmt, glyf_offset, &loca_offset, loca_dst);
	Glyph glyph;
	const uint8_t* glyph_data;
	size_t glyph_size;
	if (!GetGlyphData(*font, i, &glyph_data, &glyph_size) \|\|
	(glyph_size > 0 && !ReadGlyph(glyph_data, glyph_size, &glyph))) {
	return FONT_COMPRESSION_FAILURE();
	}
	size_t glyf_dst_size = glyf_table->buffer.size() - glyf_offset;
	if (!StoreGlyph(glyph, glyf_dst + glyf_offset, &glyf_dst_size)) {
	return FONT_COMPRESSION_FAILURE();
	}
	glyf_dst_size = Round4(glyf_dst_size);
	if (glyf_dst_size > std::numeric_limits<uint32_t>::max() \|\|
	glyf_offset + static_cast<uint32_t>(glyf_dst_size) < glyf_offset \|\|
	(index_fmt == 0 && glyf_offset + glyf_dst_size >= (1UL << 17))) {
	return FONT_COMPRESSION_FAILURE();
	}
	glyf_offset += glyf_dst_size;
	}

	StoreLoca(index_fmt, glyf_offset, &loca_offset, loca_dst);

	glyf_table->buffer.resize(glyf_offset);
	glyf_table->data = glyf_offset ? &glyf_table->buffer[0] : NULL;
	glyf_table->length = glyf_offset;
	loca_table->data = loca_offset ? &loca_table->buffer[0] : NULL;

	return true;
	}

	} // namespace

	namespace {

	bool MakeEditableBuffer(Font* font, int tableTag) {
	Font::Table* table = font->FindTable(tableTag);
	if (table == NULL) {
	return FONT_COMPRESSION_FAILURE();
	}
	if (table->IsReused()) {
	return true;
	}
	int sz = Round4(table->length);
	table->buffer.resize(sz);
	uint8_t* buf = &table->buffer[0];
	memcpy(buf, table->data, table->length);
	if (PREDICT_FALSE(sz > table->length)) {
	memset(buf + table->length, 0, sz - table->length);
	}
	table->data = buf;
	return true;
	}

	} // namespace

	bool NormalizeGlyphs(Font* font) {
	Font::Table* head_table = font->FindTable(kHeadTableTag);
	Font::Table* glyf_table = font->FindTable(kGlyfTableTag);
	Font::Table* loca_table = font->FindTable(kLocaTableTag);
	if (head_table == NULL) {
	return FONT_COMPRESSION_FAILURE();
	}
	// If you don't have glyf/loca this transform isn't very interesting
	if (loca_table == NULL && glyf_table == NULL) {
	return true;
	}
	// It would be best if you didn't have just one of glyf/loca
	if ((glyf_table == NULL) != (loca_table == NULL)) {
	return FONT_COMPRESSION_FAILURE();
	}
	// Must share neither or both loca & glyf
	if (loca_table->IsReused() != glyf_table->IsReused()) {
	return FONT_COMPRESSION_FAILURE();
	}
	if (loca_table->IsReused()) {
	return true;
	}

	int index_fmt = head_table->data[51];
	int num_glyphs = NumGlyphs(*font);

	// We need to allocate a bit more than its original length for the normalized
	// glyf table, since it can happen that the glyphs in the original table are
	// 2-byte aligned, while in the normalized table they are 4-byte aligned.
	// That gives a maximum of 2 bytes increase per glyph. However, there is no
	// theoretical guarantee that the total size of the flags plus the coordinates
	// is the smallest possible in the normalized version, so we have to allow
	// some general overhead.
	// TODO(user) Figure out some more precise upper bound on the size of
	// the overhead.
	size_t max_normalized_glyf_size = 1.1 * glyf_table->length + 2 * num_glyphs;

	glyf_table->buffer.resize(max_normalized_glyf_size);

	// if we can't write a loca using short's (index_fmt 0)
	// try again using longs (index_fmt 1)
	if (!WriteNormalizedLoca(index_fmt, num_glyphs, font)) {
	if (index_fmt != 0) {
	return FONT_COMPRESSION_FAILURE();
	}

	// Rewrite loca with 4-byte entries & update head to match
	index_fmt = 1;
	if (!WriteNormalizedLoca(index_fmt, num_glyphs, font)) {
	return FONT_COMPRESSION_FAILURE();
	}
	head_table->buffer[51] = 1;
	}

	return true;
	}

	bool NormalizeOffsets(Font* font) {
	uint32_t offset = 12 + 16 * font->num_tables;
	for (auto tag : font->OutputOrderedTags()) {
	auto& table = font->tables[tag];
	table.offset = offset;
	offset += Round4(table.length);
	}
	return true;
	}

	namespace {

	uint32_t ComputeHeaderChecksum(const Font& font) {
	uint32_t checksum = font.flavor;
	uint16_t max_pow2 = font.num_tables ? Log2Floor(font.num_tables) : 0;
	uint16_t search_range = max_pow2 ? 1 << (max_pow2 + 4) : 0;
	uint16_t range_shift = (font.num_tables << 4) - search_range;
	checksum += (font.num_tables << 16 \| search_range);
	checksum += (max_pow2 << 16 \| range_shift);
	for (const auto& i : font.tables) {
	const Font::Table* table = &i.second;
	if (table->IsReused()) {
	table = table->reuse_of;
	}
	checksum += table->tag;
	checksum += table->checksum;
	checksum += table->offset;
	checksum += table->length;
	}
	return checksum;
	}

	} // namespace

	bool FixChecksums(Font* font) {
	Font::Table* head_table = font->FindTable(kHeadTableTag);
	if (head_table == NULL) {
	return FONT_COMPRESSION_FAILURE();
	}
	if (head_table->reuse_of != NULL) {
	head_table = head_table->reuse_of;
	}
	if (head_table->length < 12) {
	return FONT_COMPRESSION_FAILURE();
	}

	uint8_t* head_buf = &head_table->buffer[0];
	size_t offset = 8;
	StoreU32(0, &offset, head_buf);
	uint32_t file_checksum = 0;
	uint32_t head_checksum = 0;
	for (auto& i : font->tables) {
	Font::Table* table = &i.second;
	if (table->IsReused()) {
	table = table->reuse_of;
	}
	table->checksum = ComputeULongSum(table->data, table->length);
	file_checksum += table->checksum;

	if (table->tag == kHeadTableTag) {
	head_checksum = table->checksum;
	}
	}

	file_checksum += ComputeHeaderChecksum(*font);
	offset = 8;
	StoreU32(0xb1b0afba - file_checksum, &offset, head_buf);

	return true;
	}

	namespace {
	bool MarkTransformed(Font* font) {
	Font::Table* head_table = font->FindTable(kHeadTableTag);
	if (head_table == NULL) {
	return FONT_COMPRESSION_FAILURE();
	}
	if (head_table->reuse_of != NULL) {
	head_table = head_table->reuse_of;
	}
	if (head_table->length < 17) {
	return FONT_COMPRESSION_FAILURE();
	}
	// set bit 11 of head table 'flags' to indicate that font has undergone
	// lossless modifying transform
	int head_flags = head_table->data[16];
	head_table->buffer[16] = head_flags \| 0x08;
	return true;
	}
	} // namespace


	bool NormalizeWithoutFixingChecksums(Font* font) {
	return (MakeEditableBuffer(font, kHeadTableTag) &&
	RemoveDigitalSignature(font) &&
	MarkTransformed(font) &&
	NormalizeGlyphs(font) &&
	NormalizeOffsets(font));
	}

	bool NormalizeFont(Font* font) {
	return (NormalizeWithoutFixingChecksums(font) &&
	FixChecksums(font));
	}

	bool NormalizeFontCollection(FontCollection* font_collection) {
	if (font_collection->fonts.size() == 1) {
	return NormalizeFont(&font_collection->fonts[0]);
	}

	uint32_t offset = CollectionHeaderSize(font_collection->header_version,
	font_collection->fonts.size());
	for (auto& font : font_collection->fonts) {
	if (!NormalizeWithoutFixingChecksums(&font)) {
	#ifdef FONT_COMPRESSION_BIN
	fprintf(stderr, "Font normalization failed.\n");
	#endif
	return FONT_COMPRESSION_FAILURE();
	}
	offset += kSfntHeaderSize + kSfntEntrySize * font.num_tables;
	}

	// Start table offsets after TTC Header and Sfnt Headers
	for (auto& font : font_collection->fonts) {
	for (auto tag : font.OutputOrderedTags()) {
	Font::Table& table = font.tables[tag];
	if (table.IsReused()) {
	table.offset = table.reuse_of->offset;
	} else {
	table.offset = offset;
	offset += Round4(table.length);
	}
	}
	}

	// Now we can fix the checksums
	for (auto& font : font_collection->fonts) {
	if (!FixChecksums(&font)) {
	#ifdef FONT_COMPRESSION_BIN
	fprintf(stderr, "Failed to fix checksums\n");
	#endif
	return FONT_COMPRESSION_FAILURE();
	}
	}

	return true;
	}

	} // namespace woff2