src/pdf/SkPDFMetadata.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkPDFMetadata.h"

 #include "SkMD5.h"
 #include "SkMilestone.h"
 #include "SkPDFTypes.h"
 #include "SkTo.h"
 #include "SkUtils.h"

 #include <utility>

 #define SKPDF_STRING(X) SKPDF_STRING_IMPL(X)
 #define SKPDF_STRING_IMPL(X) #X
 #define SKPDF_PRODUCER "Skia/PDF m" SKPDF_STRING(SK_MILESTONE)
 #define SKPDF_CUSTOM_PRODUCER_KEY "ProductionLibrary"

 static SkString pdf_date(const SkTime::DateTime& dt) {
     int timeZoneMinutes = SkToInt(dt.fTimeZoneMinutes);
     char timezoneSign = timeZoneMinutes >= 0 ? '+' : '-';
     int timeZoneHours = SkTAbs(timeZoneMinutes) / 60;
     timeZoneMinutes = SkTAbs(timeZoneMinutes) % 60;
     return SkStringPrintf(
             "D:%04u%02u%02u%02u%02u%02u%c%02d'%02d'",
             static_cast<unsigned>(dt.fYear), static_cast<unsigned>(dt.fMonth),
             static_cast<unsigned>(dt.fDay), static_cast<unsigned>(dt.fHour),
             static_cast<unsigned>(dt.fMinute),
             static_cast<unsigned>(dt.fSecond), timezoneSign, timeZoneHours,
             timeZoneMinutes);
 }

 static bool utf8_is_pdfdocencoding(const char* src, size_t len) {
     const uint8_t* end = (const uint8_t*)src + len;
     for (const uint8_t* ptr = (const uint8_t*)src; ptr < end; ++ptr) {
         uint8_t v = *ptr;
         // See Table D.2 (PDFDocEncoding Character Set) in the PDF3200_2008 spec.
         if ((v > 23 && v < 32) || v > 126) {
             return false;
         }
     }
     return true;
 }

 void write_utf16be(char** ptr, uint16_t value) {
     *(*ptr)++ = (value >> 8);
     *(*ptr)++ = (value & 0xFF);
 }

 // Please Note:  This "abuses" the SkString, which "should" only hold UTF8.
 // But the SkString is written as if it is really just a ref-counted array of
 // chars, so this works, as long as we handle endiness and conversions ourselves.
 //
 // Input:  UTF-8
 // Output  UTF-16-BE
 static SkString to_utf16be(const char* src, size_t len) {
     SkString ret;
     const char* const end = src + len;
     size_t n = 1;  // BOM
     for (const char* ptr = src; ptr < end;) {
         SkUnichar u = SkUTF::NextUTF8(&ptr, end);
         if (u < 0) {
             break;
         }
         n += SkUTF::ToUTF16(u);
     }
     ret.resize(2 * n);
     char* out = ret.writable_str();
     write_utf16be(&out, 0xFEFF);  // BOM
     for (const char* ptr = src; ptr < end;) {
         SkUnichar u = SkUTF::NextUTF8(&ptr, end);
         if (u < 0) {
             break;
         }
         uint16_t utf16[2];
         size_t l = SkUTF::ToUTF16(u, utf16);
         write_utf16be(&out, utf16[0]);
         if (l == 2) {
             write_utf16be(&out, utf16[1]);
         }
     }
     SkASSERT(out == ret.writable_str() + 2 * n);
     return ret;
 }

 // Input:  UTF-8
 // Output  UTF-16-BE OR PDFDocEncoding (if that encoding is identical to ASCII encoding).
 //
 // See sections 14.3.3 (Document Information Dictionary) and 7.9.2.2 (Text String Type)
 // of the PDF32000_2008 spec.
 static SkString convert(const SkString& s) {
     return utf8_is_pdfdocencoding(s.c_str(), s.size()) ? s : to_utf16be(s.c_str(), s.size());
 }
 static SkString convert(const char* src) {
     size_t len = strlen(src);
     return utf8_is_pdfdocencoding(src, len) ? SkString(src, len) : to_utf16be(src, len);
 }

 namespace {
 static const struct {
     const char* const key;
     SkString SkDocument::PDFMetadata::*const valuePtr;
 } gMetadataKeys[] = {
         {"Title", &SkDocument::PDFMetadata::fTitle},
         {"Author", &SkDocument::PDFMetadata::fAuthor},
         {"Subject", &SkDocument::PDFMetadata::fSubject},
         {"Keywords", &SkDocument::PDFMetadata::fKeywords},
         {"Creator", &SkDocument::PDFMetadata::fCreator},
 };
 }  // namespace

 sk_sp<SkPDFObject> SkPDFMetadata::MakeDocumentInformationDict(
         const SkDocument::PDFMetadata& metadata) {
     auto dict = sk_make_sp<SkPDFDict>();
     for (const auto keyValuePtr : gMetadataKeys) {
         const SkString& value = metadata.*(keyValuePtr.valuePtr);
         if (value.size() > 0) {
             dict->insertString(keyValuePtr.key, convert(value));
         }
     }
     if (metadata.fProducer.isEmpty()) {
         dict->insertString("Producer", convert(SKPDF_PRODUCER));
     } else {
         dict->insertString("Producer", convert(metadata.fProducer));
         dict->insertString(SKPDF_CUSTOM_PRODUCER_KEY, convert(SKPDF_PRODUCER));
     }
     if (metadata.fCreation.fEnabled) {
         dict->insertString("CreationDate", pdf_date(metadata.fCreation.fDateTime));
     }
     if (metadata.fModified.fEnabled) {
         dict->insertString("ModDate", pdf_date(metadata.fModified.fDateTime));
     }
     return std::move(dict);
 }

 SkPDFMetadata::UUID SkPDFMetadata::CreateUUID(
         const SkDocument::PDFMetadata& metadata) {
     // The main requirement is for the UUID to be unique; the exact
     // format of the data that will be hashed is not important.
     SkMD5 md5;
     const char uuidNamespace[] = "org.skia.pdf\n";
     md5.writeText(uuidNamespace);
     double msec = SkTime::GetMSecs();
     md5.write(&msec, sizeof(msec));
     SkTime::DateTime dateTime;
     SkTime::GetDateTime(&dateTime);
     md5.write(&dateTime, sizeof(dateTime));
     if (metadata.fCreation.fEnabled) {
         md5.write(&metadata.fCreation.fDateTime,
                   sizeof(metadata.fCreation.fDateTime));
     }
     if (metadata.fModified.fEnabled) {
         md5.write(&metadata.fModified.fDateTime,
                   sizeof(metadata.fModified.fDateTime));
     }

     for (const auto keyValuePtr : gMetadataKeys) {
         md5.writeText(keyValuePtr.key);
         md5.write("\037", 1);
         const SkString& value = metadata.*(keyValuePtr.valuePtr);
         md5.write(value.c_str(), value.size());
         md5.write("\036", 1);
     }
     SkMD5::Digest digest;
     md5.finish(digest);
     // See RFC 4122, page 6-7.
     digest.data[6] = (digest.data[6] & 0x0F) | 0x30;
     digest.data[8] = (digest.data[6] & 0x3F) | 0x80;
     static_assert(sizeof(digest) == sizeof(UUID), "uuid_size");
     SkPDFMetadata::UUID uuid;
     memcpy(&uuid, &digest, sizeof(digest));
     return uuid;
 }

 sk_sp<SkPDFObject> SkPDFMetadata::MakePdfId(const UUID& doc,
                                             const UUID& instance) {
     // /ID [ <81b14aafa313db63dbd6f981e49f94f4>
     //       <81b14aafa313db63dbd6f981e49f94f4> ]
     auto array = sk_make_sp<SkPDFArray>();
     static_assert(sizeof(SkPDFMetadata::UUID) == 16, "uuid_size");
     array->appendString(
             SkString(reinterpret_cast<const char*>(&doc), sizeof(UUID)));
     array->appendString(
             SkString(reinterpret_cast<const char*>(&instance), sizeof(UUID)));
     return std::move(array);
 }

 // Convert a block of memory to hexadecimal.  Input and output pointers will be
 // moved to end of the range.
 static void hexify(const uint8_t** inputPtr, char** outputPtr, int count) {
     SkASSERT(inputPtr && *inputPtr);
     SkASSERT(outputPtr && *outputPtr);
     while (count-- > 0) {
         uint8_t value = *(*inputPtr)++;
         *(*outputPtr)++ = SkHexadecimalDigits::gLower[value >> 4];
         *(*outputPtr)++ = SkHexadecimalDigits::gLower[value & 0xF];
     }
 }

 static SkString uuid_to_string(const SkPDFMetadata::UUID& uuid) {
     //  8-4-4-4-12
     char buffer[36];  // [32 + 4]
     char* ptr = buffer;
     const uint8_t* data = uuid.fData;
     hexify(&data, &ptr, 4);
     *ptr++ = '-';
     hexify(&data, &ptr, 2);
     *ptr++ = '-';
     hexify(&data, &ptr, 2);
     *ptr++ = '-';
     hexify(&data, &ptr, 2);
     *ptr++ = '-';
     hexify(&data, &ptr, 6);
     SkASSERT(ptr == buffer + 36);
     SkASSERT(data == uuid.fData + 16);
     return SkString(buffer, 36);
 }

 namespace {
 class PDFXMLObject final : public SkPDFObject {
 public:
     PDFXMLObject(SkString xml) : fXML(std::move(xml)) {}
     void emitObject(SkWStream* stream,
                     const SkPDFObjNumMap& omap) const override {
         SkPDFDict dict("Metadata");
         dict.insertName("Subtype", "XML");
         dict.insertInt("Length", fXML.size());
         dict.emitObject(stream, omap);
         static const char streamBegin[] = " stream\n";
         stream->writeText(streamBegin);
         // Do not compress this.  The standard requires that a
         // program that does not understand PDF can grep for
         // "<?xpacket" and extract the entire XML.
         stream->write(fXML.c_str(), fXML.size());
         static const char streamEnd[] = "\nendstream";
         stream->writeText(streamEnd);
     }

 private:
     const SkString fXML;
 };
 }  // namespace

 static int count_xml_escape_size(const SkString& input) {
     int extra = 0;
     for (size_t i = 0; i < input.size(); ++i) {
         if (input[i] == '&') {
             extra += 4;  // strlen("&amp;") - strlen("&")
         } else if (input[i] == '<') {
             extra += 3;  // strlen("&lt;") - strlen("<")
         }
     }
     return extra;
 }

 const SkString escape_xml(const SkString& input,
                           const char* before = nullptr,
                           const char* after = nullptr) {
     if (input.size() == 0) {
         return input;
     }
     // "&" --> "&amp;" and  "<" --> "&lt;"
     // text is assumed to be in UTF-8
     // all strings are xml content, not attribute values.
     size_t beforeLen = before ? strlen(before) : 0;
     size_t afterLen = after ? strlen(after) : 0;
     int extra = count_xml_escape_size(input);
     SkString output(input.size() + extra + beforeLen + afterLen);
     char* out = output.writable_str();
     if (before) {
         strncpy(out, before, beforeLen);
         out += beforeLen;
     }
     static const char kAmp[] = "&amp;";
     static const char kLt[] = "&lt;";
     for (size_t i = 0; i < input.size(); ++i) {
         if (input[i] == '&') {
             strncpy(out, kAmp, strlen(kAmp));
             out += strlen(kAmp);
         } else if (input[i] == '<') {
             strncpy(out, kLt, strlen(kLt));
             out += strlen(kLt);
         } else {
             *out++ = input[i];
         }
     }
     if (after) {
         strncpy(out, after, afterLen);
         out += afterLen;
     }
     // Validate that we haven't written outside of our string.
     SkASSERT(out == &output.writable_str()[output.size()]);
     *out = '\0';
     return output;
 }

 sk_sp<SkPDFObject> SkPDFMetadata::MakeXMPObject(
         const SkDocument::PDFMetadata& metadata,
         const UUID& doc,
         const UUID& instance) {
     static const char templateString[] =
             "<?xpacket begin=\"\" id=\"W5M0MpCehiHzreSzNTczkc9d\"?>\n"
             "<x:xmpmeta xmlns:x=\"adobe:ns:meta/\"\n"
             " x:xmptk=\"Adobe XMP Core 5.4-c005 78.147326, "
             "2012/08/23-13:03:03\">\n"
             "<rdf:RDF "
             "xmlns:rdf=\"http://www.w3.org/1999/02/22-rdf-syntax-ns#\">\n"
             "<rdf:Description rdf:about=\"\"\n"
             " xmlns:xmp=\"http://ns.adobe.com/xap/1.0/\"\n"
             " xmlns:dc=\"http://purl.org/dc/elements/1.1/\"\n"
             " xmlns:xmpMM=\"http://ns.adobe.com/xap/1.0/mm/\"\n"
             " xmlns:pdf=\"http://ns.adobe.com/pdf/1.3/\"\n"
             " xmlns:pdfaid=\"http://www.aiim.org/pdfa/ns/id/\">\n"
             "<pdfaid:part>2</pdfaid:part>\n"
             "<pdfaid:conformance>B</pdfaid:conformance>\n"
             "%s"  // ModifyDate
             "%s"  // CreateDate
             "%s"  // xmp:CreatorTool
             "<dc:format>application/pdf</dc:format>\n"
             "%s"  // dc:title
             "%s"  // dc:description
             "%s"  // author
             "%s"  // keywords
             "<xmpMM:DocumentID>uuid:%s</xmpMM:DocumentID>\n"
             "<xmpMM:InstanceID>uuid:%s</xmpMM:InstanceID>\n"
             "%s"  // pdf:Producer
             "%s"  // pdf:Keywords
             "</rdf:Description>\n"
             "</rdf:RDF>\n"
             "</x:xmpmeta>\n"  // Note:  the standard suggests 4k of padding.
             "<?xpacket end=\"w\"?>\n";

     SkString creationDate;
     SkString modificationDate;
     if (metadata.fCreation.fEnabled) {
         SkString tmp;
         metadata.fCreation.fDateTime.toISO8601(&tmp);
         SkASSERT(0 == count_xml_escape_size(tmp));
         // YYYY-mm-ddTHH:MM:SS[+|-]ZZ:ZZ; no need to escape
         creationDate = SkStringPrintf("<xmp:CreateDate>%s</xmp:CreateDate>\n",
                                       tmp.c_str());
     }
     if (metadata.fModified.fEnabled) {
         SkString tmp;
         metadata.fModified.fDateTime.toISO8601(&tmp);
         SkASSERT(0 == count_xml_escape_size(tmp));
         modificationDate = SkStringPrintf(
                 "<xmp:ModifyDate>%s</xmp:ModifyDate>\n", tmp.c_str());
     }
     SkString title =
             escape_xml(metadata.fTitle,
                        "<dc:title><rdf:Alt><rdf:li xml:lang=\"x-default\">",
                        "</rdf:li></rdf:Alt></dc:title>\n");
     SkString author =
             escape_xml(metadata.fAuthor, "<dc:creator><rdf:Bag><rdf:li>",
                        "</rdf:li></rdf:Bag></dc:creator>\n");
     // TODO: in theory, XMP can support multiple authors.  Split on a delimiter?
     SkString subject = escape_xml(
             metadata.fSubject,
             "<dc:description><rdf:Alt><rdf:li xml:lang=\"x-default\">",
             "</rdf:li></rdf:Alt></dc:description>\n");
     SkString keywords1 =
             escape_xml(metadata.fKeywords, "<dc:subject><rdf:Bag><rdf:li>",
                        "</rdf:li></rdf:Bag></dc:subject>\n");
     SkString keywords2 = escape_xml(metadata.fKeywords, "<pdf:Keywords>",
                                     "</pdf:Keywords>\n");
     // TODO: in theory, keywords can be a list too.

     SkString producer("<pdf:Producer>" SKPDF_PRODUCER "</pdf:Producer>\n");
     if (!metadata.fProducer.isEmpty()) {
         // TODO: register a developer prefix to make
         // <skia:SKPDF_CUSTOM_PRODUCER_KEY> a real XML tag.
         producer = escape_xml(
                 metadata.fProducer, "<pdf:Producer>",
                 "</pdf:Producer>\n<!-- <skia:" SKPDF_CUSTOM_PRODUCER_KEY ">"
                 SKPDF_PRODUCER "</skia:" SKPDF_CUSTOM_PRODUCER_KEY "> -->\n");
     }

     SkString creator = escape_xml(metadata.fCreator, "<xmp:CreatorTool>",
                                   "</xmp:CreatorTool>\n");
     SkString documentID = uuid_to_string(doc);  // no need to escape
     SkASSERT(0 == count_xml_escape_size(documentID));
     SkString instanceID = uuid_to_string(instance);
     SkASSERT(0 == count_xml_escape_size(instanceID));
     return sk_make_sp<PDFXMLObject>(SkStringPrintf(
             templateString, modificationDate.c_str(), creationDate.c_str(),
             creator.c_str(), title.c_str(), subject.c_str(), author.c_str(),
             keywords1.c_str(), documentID.c_str(), instanceID.c_str(),
             producer.c_str(), keywords2.c_str()));
 }

 #undef SKPDF_CUSTOM_PRODUCER_KEY
 #undef SKPDF_PRODUCER
 #undef SKPDF_STRING
 #undef SKPDF_STRING_IMPL
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkPDFMetadata.h"

	#include "SkMD5.h"
	#include "SkMilestone.h"
	#include "SkPDFTypes.h"
	#include "SkTo.h"
	#include "SkUtils.h"

	#include <utility>

	#define SKPDF_STRING(X) SKPDF_STRING_IMPL(X)
	#define SKPDF_STRING_IMPL(X) #X
	#define SKPDF_PRODUCER "Skia/PDF m" SKPDF_STRING(SK_MILESTONE)
	#define SKPDF_CUSTOM_PRODUCER_KEY "ProductionLibrary"

	static SkString pdf_date(const SkTime::DateTime& dt) {
	int timeZoneMinutes = SkToInt(dt.fTimeZoneMinutes);
	char timezoneSign = timeZoneMinutes >= 0 ? '+' : '-';
	int timeZoneHours = SkTAbs(timeZoneMinutes) / 60;
	timeZoneMinutes = SkTAbs(timeZoneMinutes) % 60;
	return SkStringPrintf(
	"D:%04u%02u%02u%02u%02u%02u%c%02d'%02d'",
	static_cast<unsigned>(dt.fYear), static_cast<unsigned>(dt.fMonth),
	static_cast<unsigned>(dt.fDay), static_cast<unsigned>(dt.fHour),
	static_cast<unsigned>(dt.fMinute),
	static_cast<unsigned>(dt.fSecond), timezoneSign, timeZoneHours,
	timeZoneMinutes);
	}

	static bool utf8_is_pdfdocencoding(const char* src, size_t len) {
	const uint8_t* end = (const uint8_t*)src + len;
	for (const uint8_t* ptr = (const uint8_t*)src; ptr < end; ++ptr) {
	uint8_t v = *ptr;
	// See Table D.2 (PDFDocEncoding Character Set) in the PDF3200_2008 spec.
	if ((v > 23 && v < 32) \|\| v > 126) {
	return false;
	}
	}
	return true;
	}

	void write_utf16be(char** ptr, uint16_t value) {
	(ptr)++ = (value >> 8);
	(ptr)++ = (value & 0xFF);
	}

	// Please Note: This "abuses" the SkString, which "should" only hold UTF8.
	// But the SkString is written as if it is really just a ref-counted array of
	// chars, so this works, as long as we handle endiness and conversions ourselves.
	//
	// Input: UTF-8
	// Output UTF-16-BE
	static SkString to_utf16be(const char* src, size_t len) {
	SkString ret;
	const char* const end = src + len;
	size_t n = 1; // BOM
	for (const char* ptr = src; ptr < end;) {
	SkUnichar u = SkUTF::NextUTF8(&ptr, end);
	if (u < 0) {
	break;
	}
	n += SkUTF::ToUTF16(u);
	}
	ret.resize(2 * n);
	char* out = ret.writable_str();
	write_utf16be(&out, 0xFEFF); // BOM
	for (const char* ptr = src; ptr < end;) {
	SkUnichar u = SkUTF::NextUTF8(&ptr, end);
	if (u < 0) {
	break;
	}
	uint16_t utf16[2];
	size_t l = SkUTF::ToUTF16(u, utf16);
	write_utf16be(&out, utf16[0]);
	if (l == 2) {
	write_utf16be(&out, utf16[1]);
	}
	}
	SkASSERT(out == ret.writable_str() + 2 * n);
	return ret;
	}

	// Input: UTF-8
	// Output UTF-16-BE OR PDFDocEncoding (if that encoding is identical to ASCII encoding).
	//
	// See sections 14.3.3 (Document Information Dictionary) and 7.9.2.2 (Text String Type)
	// of the PDF32000_2008 spec.
	static SkString convert(const SkString& s) {
	return utf8_is_pdfdocencoding(s.c_str(), s.size()) ? s : to_utf16be(s.c_str(), s.size());
	}
	static SkString convert(const char* src) {
	size_t len = strlen(src);
	return utf8_is_pdfdocencoding(src, len) ? SkString(src, len) : to_utf16be(src, len);
	}

	namespace {
	static const struct {
	const char* const key;
	SkString SkDocument::PDFMetadata::*const valuePtr;
	} gMetadataKeys[] = {
	{"Title", &SkDocument::PDFMetadata::fTitle},
	{"Author", &SkDocument::PDFMetadata::fAuthor},
	{"Subject", &SkDocument::PDFMetadata::fSubject},
	{"Keywords", &SkDocument::PDFMetadata::fKeywords},
	{"Creator", &SkDocument::PDFMetadata::fCreator},
	};
	} // namespace

	sk_sp<SkPDFObject> SkPDFMetadata::MakeDocumentInformationDict(
	const SkDocument::PDFMetadata& metadata) {
	auto dict = sk_make_sp<SkPDFDict>();
	for (const auto keyValuePtr : gMetadataKeys) {
	const SkString& value = metadata.*(keyValuePtr.valuePtr);
	if (value.size() > 0) {
	dict->insertString(keyValuePtr.key, convert(value));
	}
	}
	if (metadata.fProducer.isEmpty()) {
	dict->insertString("Producer", convert(SKPDF_PRODUCER));
	} else {
	dict->insertString("Producer", convert(metadata.fProducer));
	dict->insertString(SKPDF_CUSTOM_PRODUCER_KEY, convert(SKPDF_PRODUCER));
	}
	if (metadata.fCreation.fEnabled) {
	dict->insertString("CreationDate", pdf_date(metadata.fCreation.fDateTime));
	}
	if (metadata.fModified.fEnabled) {
	dict->insertString("ModDate", pdf_date(metadata.fModified.fDateTime));
	}
	return std::move(dict);
	}

	SkPDFMetadata::UUID SkPDFMetadata::CreateUUID(
	const SkDocument::PDFMetadata& metadata) {
	// The main requirement is for the UUID to be unique; the exact
	// format of the data that will be hashed is not important.
	SkMD5 md5;
	const char uuidNamespace[] = "org.skia.pdf\n";
	md5.writeText(uuidNamespace);
	double msec = SkTime::GetMSecs();
	md5.write(&msec, sizeof(msec));
	SkTime::DateTime dateTime;
	SkTime::GetDateTime(&dateTime);
	md5.write(&dateTime, sizeof(dateTime));
	if (metadata.fCreation.fEnabled) {
	md5.write(&metadata.fCreation.fDateTime,
	sizeof(metadata.fCreation.fDateTime));
	}
	if (metadata.fModified.fEnabled) {
	md5.write(&metadata.fModified.fDateTime,
	sizeof(metadata.fModified.fDateTime));
	}

	for (const auto keyValuePtr : gMetadataKeys) {
	md5.writeText(keyValuePtr.key);
	md5.write("\037", 1);
	const SkString& value = metadata.*(keyValuePtr.valuePtr);
	md5.write(value.c_str(), value.size());
	md5.write("\036", 1);
	}
	SkMD5::Digest digest;
	md5.finish(digest);
	// See RFC 4122, page 6-7.
	digest.data[6] = (digest.data[6] & 0x0F) \| 0x30;
	digest.data[8] = (digest.data[6] & 0x3F) \| 0x80;
	static_assert(sizeof(digest) == sizeof(UUID), "uuid_size");
	SkPDFMetadata::UUID uuid;
	memcpy(&uuid, &digest, sizeof(digest));
	return uuid;
	}

	sk_sp<SkPDFObject> SkPDFMetadata::MakePdfId(const UUID& doc,
	const UUID& instance) {
	// /ID [ <81b14aafa313db63dbd6f981e49f94f4>
	// <81b14aafa313db63dbd6f981e49f94f4> ]
	auto array = sk_make_sp<SkPDFArray>();
	static_assert(sizeof(SkPDFMetadata::UUID) == 16, "uuid_size");
	array->appendString(
	SkString(reinterpret_cast<const char*>(&doc), sizeof(UUID)));
	array->appendString(
	SkString(reinterpret_cast<const char*>(&instance), sizeof(UUID)));
	return std::move(array);
	}

	// Convert a block of memory to hexadecimal. Input and output pointers will be
	// moved to end of the range.
	static void hexify(const uint8_t inputPtr, char outputPtr, int count) {
	SkASSERT(inputPtr && *inputPtr);
	SkASSERT(outputPtr && *outputPtr);
	while (count-- > 0) {
	uint8_t value = (inputPtr)++;
	(outputPtr)++ = SkHexadecimalDigits::gLower[value >> 4];
	(outputPtr)++ = SkHexadecimalDigits::gLower[value & 0xF];
	}
	}

	static SkString uuid_to_string(const SkPDFMetadata::UUID& uuid) {
	// 8-4-4-4-12
	char buffer[36]; // [32 + 4]
	char* ptr = buffer;
	const uint8_t* data = uuid.fData;
	hexify(&data, &ptr, 4);
	*ptr++ = '-';
	hexify(&data, &ptr, 2);
	*ptr++ = '-';
	hexify(&data, &ptr, 2);
	*ptr++ = '-';
	hexify(&data, &ptr, 2);
	*ptr++ = '-';
	hexify(&data, &ptr, 6);
	SkASSERT(ptr == buffer + 36);
	SkASSERT(data == uuid.fData + 16);
	return SkString(buffer, 36);
	}

	namespace {
	class PDFXMLObject final : public SkPDFObject {
	public:
	PDFXMLObject(SkString xml) : fXML(std::move(xml)) {}
	void emitObject(SkWStream* stream,
	const SkPDFObjNumMap& omap) const override {
	SkPDFDict dict("Metadata");
	dict.insertName("Subtype", "XML");
	dict.insertInt("Length", fXML.size());
	dict.emitObject(stream, omap);
	static const char streamBegin[] = " stream\n";
	stream->writeText(streamBegin);
	// Do not compress this. The standard requires that a
	// program that does not understand PDF can grep for
	// "<?xpacket" and extract the entire XML.
	stream->write(fXML.c_str(), fXML.size());
	static const char streamEnd[] = "\nendstream";
	stream->writeText(streamEnd);
	}

	private:
	const SkString fXML;
	};
	} // namespace

	static int count_xml_escape_size(const SkString& input) {
	int extra = 0;
	for (size_t i = 0; i < input.size(); ++i) {
	if (input[i] == '&') {
	extra += 4; // strlen("&") - strlen("&")
	} else if (input[i] == '<') {
	extra += 3; // strlen("<") - strlen("<")
	}
	}
	return extra;
	}

	const SkString escape_xml(const SkString& input,
	const char* before = nullptr,
	const char* after = nullptr) {
	if (input.size() == 0) {
	return input;
	}
	// "&" --> "&" and "<" --> "<"
	// text is assumed to be in UTF-8
	// all strings are xml content, not attribute values.
	size_t beforeLen = before ? strlen(before) : 0;
	size_t afterLen = after ? strlen(after) : 0;
	int extra = count_xml_escape_size(input);
	SkString output(input.size() + extra + beforeLen + afterLen);
	char* out = output.writable_str();
	if (before) {
	strncpy(out, before, beforeLen);
	out += beforeLen;
	}
	static const char kAmp[] = "&";
	static const char kLt[] = "<";
	for (size_t i = 0; i < input.size(); ++i) {
	if (input[i] == '&') {
	strncpy(out, kAmp, strlen(kAmp));
	out += strlen(kAmp);
	} else if (input[i] == '<') {
	strncpy(out, kLt, strlen(kLt));
	out += strlen(kLt);
	} else {
	*out++ = input[i];
	}
	}
	if (after) {
	strncpy(out, after, afterLen);
	out += afterLen;
	}
	// Validate that we haven't written outside of our string.
	SkASSERT(out == &output.writable_str()[output.size()]);
	*out = '\0';
	return output;
	}

	sk_sp<SkPDFObject> SkPDFMetadata::MakeXMPObject(
	const SkDocument::PDFMetadata& metadata,
	const UUID& doc,
	const UUID& instance) {
	static const char templateString[] =
	"<?xpacket begin=\"\" id=\"W5M0MpCehiHzreSzNTczkc9d\"?>\n"
	"<x:xmpmeta xmlns:x=\"adobe:ns:meta/\"\n"
	" x:xmptk=\"Adobe XMP Core 5.4-c005 78.147326, "
	"2012/08/23-13:03:03\">\n"
	"<rdf:RDF "
	"xmlns:rdf=\"http://www.w3.org/1999/02/22-rdf-syntax-ns#\">\n"
	"<rdf:Description rdf:about=\"\"\n"
	" xmlns:xmp=\"http://ns.adobe.com/xap/1.0/\"\n"
	" xmlns:dc=\"http://purl.org/dc/elements/1.1/\"\n"
	" xmlns:xmpMM=\"http://ns.adobe.com/xap/1.0/mm/\"\n"
	" xmlns:pdf=\"http://ns.adobe.com/pdf/1.3/\"\n"
	" xmlns:pdfaid=\"http://www.aiim.org/pdfa/ns/id/\">\n"
	"<pdfaid:part>2</pdfaid:part>\n"
	"<pdfaid:conformance>B</pdfaid:conformance>\n"
	"%s" // ModifyDate
	"%s" // CreateDate
	"%s" // xmp:CreatorTool
	"<dc:format>application/pdf</dc:format>\n"
	"%s" // dc:title
	"%s" // dc:description
	"%s" // author
	"%s" // keywords
	"<xmpMM:DocumentID>uuid:%s</xmpMM:DocumentID>\n"
	"<xmpMM:InstanceID>uuid:%s</xmpMM:InstanceID>\n"
	"%s" // pdf:Producer
	"%s" // pdf:Keywords
	"</rdf:Description>\n"
	"</rdf:RDF>\n"
	"</x:xmpmeta>\n" // Note: the standard suggests 4k of padding.
	"<?xpacket end=\"w\"?>\n";

	SkString creationDate;
	SkString modificationDate;
	if (metadata.fCreation.fEnabled) {
	SkString tmp;
	metadata.fCreation.fDateTime.toISO8601(&tmp);
	SkASSERT(0 == count_xml_escape_size(tmp));
	// YYYY-mm-ddTHH:MM:SS[+\|-]ZZ:ZZ; no need to escape
	creationDate = SkStringPrintf("<xmp:CreateDate>%s</xmp:CreateDate>\n",
	tmp.c_str());
	}
	if (metadata.fModified.fEnabled) {
	SkString tmp;
	metadata.fModified.fDateTime.toISO8601(&tmp);
	SkASSERT(0 == count_xml_escape_size(tmp));
	modificationDate = SkStringPrintf(
	"<xmp:ModifyDate>%s</xmp:ModifyDate>\n", tmp.c_str());
	}
	SkString title =
	escape_xml(metadata.fTitle,
	"<dc:title><rdf:Alt><rdf:li xml:lang=\"x-default\">",
	"</rdf:li></rdf:Alt></dc:title>\n");
	SkString author =
	escape_xml(metadata.fAuthor, "<dc:creator><rdf:Bag><rdf:li>",
	"</rdf:li></rdf:Bag></dc:creator>\n");
	// TODO: in theory, XMP can support multiple authors. Split on a delimiter?
	SkString subject = escape_xml(
	metadata.fSubject,
	"<dc:description><rdf:Alt><rdf:li xml:lang=\"x-default\">",
	"</rdf:li></rdf:Alt></dc:description>\n");
	SkString keywords1 =
	escape_xml(metadata.fKeywords, "<dc:subject><rdf:Bag><rdf:li>",
	"</rdf:li></rdf:Bag></dc:subject>\n");
	SkString keywords2 = escape_xml(metadata.fKeywords, "<pdf:Keywords>",
	"</pdf:Keywords>\n");
	// TODO: in theory, keywords can be a list too.

	SkString producer("<pdf:Producer>" SKPDF_PRODUCER "</pdf:Producer>\n");
	if (!metadata.fProducer.isEmpty()) {
	// TODO: register a developer prefix to make
	// <skia:SKPDF_CUSTOM_PRODUCER_KEY> a real XML tag.
	producer = escape_xml(
	metadata.fProducer, "<pdf:Producer>",
	"</pdf:Producer>\n<!-- <skia:" SKPDF_CUSTOM_PRODUCER_KEY ">"
	SKPDF_PRODUCER "</skia:" SKPDF_CUSTOM_PRODUCER_KEY "> -->\n");
	}

	SkString creator = escape_xml(metadata.fCreator, "<xmp:CreatorTool>",
	"</xmp:CreatorTool>\n");
	SkString documentID = uuid_to_string(doc); // no need to escape
	SkASSERT(0 == count_xml_escape_size(documentID));
	SkString instanceID = uuid_to_string(instance);
	SkASSERT(0 == count_xml_escape_size(instanceID));
	return sk_make_sp<PDFXMLObject>(SkStringPrintf(
	templateString, modificationDate.c_str(), creationDate.c_str(),
	creator.c_str(), title.c_str(), subject.c_str(), author.c_str(),
	keywords1.c_str(), documentID.c_str(), instanceID.c_str(),
	producer.c_str(), keywords2.c_str()));
	}

	#undef SKPDF_CUSTOM_PRODUCER_KEY
	#undef SKPDF_PRODUCER
	#undef SKPDF_STRING
	#undef SKPDF_STRING_IMPL