clang-tools-extra/clang-doc/Representation.cpp - llvm-project - Git at Google

 ///===-- Representation.cpp - ClangDoc Representation -----------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the merging of different types of infos. The data in the
 // calling Info is preserved during a merge unless that field is empty or
 // default. In that case, the data from the parameter Info is used to replace
 // the empty or default data.
 //
 // For most fields, the first decl seen provides the data. Exceptions to this
 // include the location and description fields, which are collections of data on
 // all decls related to a given definition. All other fields are ignored in new
 // decls unless the first seen decl didn't, for whatever reason, incorporate
 // data on that field (e.g. a forward declared class wouldn't have information
 // on members on the forward declaration, but would have the class name).
 //
 //===----------------------------------------------------------------------===//
 #include "Representation.h"
 #include "llvm/Support/Error.h"
 #include "llvm/Support/Path.h"

 namespace clang {
 namespace doc {

 namespace {

 const SymbolID EmptySID = SymbolID();

 template <typename T>
 llvm::Expected<std::unique_ptr<Info>>
 reduce(std::vector<std::unique_ptr<Info>> &Values) {
   if (Values.empty())
     return llvm::createStringError(llvm::inconvertibleErrorCode(),
                                    "no value to reduce");
   std::unique_ptr<Info> Merged = std::make_unique<T>(Values[0]->USR);
   T *Tmp = static_cast<T *>(Merged.get());
   for (auto &I : Values)
     Tmp->merge(std::move(*static_cast<T *>(I.get())));
   return std::move(Merged);
 }

 // Return the index of the matching child in the vector, or -1 if merge is not
 // necessary.
 template <typename T>
 int getChildIndexIfExists(std::vector<T> &Children, T &ChildToMerge) {
   for (unsigned long I = 0; I < Children.size(); I++) {
     if (ChildToMerge.USR == Children[I].USR)
       return I;
   }
   return -1;
 }

 void reduceChildren(std::vector<Reference> &Children,
                     std::vector<Reference> &&ChildrenToMerge) {
   for (auto &ChildToMerge : ChildrenToMerge) {
     int mergeIdx = getChildIndexIfExists(Children, ChildToMerge);
     if (mergeIdx == -1) {
       Children.push_back(std::move(ChildToMerge));
       continue;
     }
     Children[mergeIdx].merge(std::move(ChildToMerge));
   }
 }

 void reduceChildren(std::vector<FunctionInfo> &Children,
                     std::vector<FunctionInfo> &&ChildrenToMerge) {
   for (auto &ChildToMerge : ChildrenToMerge) {
     int mergeIdx = getChildIndexIfExists(Children, ChildToMerge);
     if (mergeIdx == -1) {
       Children.push_back(std::move(ChildToMerge));
       continue;
     }
     Children[mergeIdx].merge(std::move(ChildToMerge));
   }
 }

 void reduceChildren(std::vector<EnumInfo> &Children,
                     std::vector<EnumInfo> &&ChildrenToMerge) {
   for (auto &ChildToMerge : ChildrenToMerge) {
     int mergeIdx = getChildIndexIfExists(Children, ChildToMerge);
     if (mergeIdx == -1) {
       Children.push_back(std::move(ChildToMerge));
       continue;
     }
     Children[mergeIdx].merge(std::move(ChildToMerge));
   }
 }

 } // namespace

 // Dispatch function.
 llvm::Expected<std::unique_ptr<Info>>
 mergeInfos(std::vector<std::unique_ptr<Info>> &Values) {
   if (Values.empty())
     return llvm::createStringError(llvm::inconvertibleErrorCode(),
                                    "no info values to merge");

   switch (Values[0]->IT) {
   case InfoType::IT_namespace:
     return reduce<NamespaceInfo>(Values);
   case InfoType::IT_record:
     return reduce<RecordInfo>(Values);
   case InfoType::IT_enum:
     return reduce<EnumInfo>(Values);
   case InfoType::IT_function:
     return reduce<FunctionInfo>(Values);
   default:
     return llvm::createStringError(llvm::inconvertibleErrorCode(),
                                    "unexpected info type");
   }
 }

 static llvm::SmallString<64>
 calculateRelativeFilePath(const InfoType &Type, const StringRef &Path,
                           const StringRef &Name, const StringRef &CurrentPath) {
   llvm::SmallString<64> FilePath;

   if (CurrentPath != Path) {
     // iterate back to the top
     for (llvm::sys::path::const_iterator I =
              llvm::sys::path::begin(CurrentPath);
          I != llvm::sys::path::end(CurrentPath); ++I)
       llvm::sys::path::append(FilePath, "..");
     llvm::sys::path::append(FilePath, Path);
   }

   // Namespace references have a Path to the parent namespace, but
   // the file is actually in the subdirectory for the namespace.
   if (Type == doc::InfoType::IT_namespace)
     llvm::sys::path::append(FilePath, Name);

   return llvm::sys::path::relative_path(FilePath);
 }

 llvm::SmallString<64>
 Reference::getRelativeFilePath(const StringRef &CurrentPath) const {
   return calculateRelativeFilePath(RefType, Path, Name, CurrentPath);
 }

 llvm::SmallString<16> Reference::getFileBaseName() const {
   if (RefType == InfoType::IT_namespace)
     return llvm::SmallString<16>("index");

   return Name;
 }

 llvm::SmallString<64>
 Info::getRelativeFilePath(const StringRef &CurrentPath) const {
   return calculateRelativeFilePath(IT, Path, extractName(), CurrentPath);
 }

 llvm::SmallString<16> Info::getFileBaseName() const {
   if (IT == InfoType::IT_namespace)
     return llvm::SmallString<16>("index");

   return extractName();
 }

 bool Reference::mergeable(const Reference &Other) {
   return RefType == Other.RefType && USR == Other.USR;
 }

 void Reference::merge(Reference &&Other) {
   assert(mergeable(Other));
   if (Name.empty())
     Name = Other.Name;
   if (Path.empty())
     Path = Other.Path;
   if (!IsInGlobalNamespace)
     IsInGlobalNamespace = Other.IsInGlobalNamespace;
 }

 void Info::mergeBase(Info &&Other) {
   assert(mergeable(Other));
   if (USR == EmptySID)
     USR = Other.USR;
   if (Name == "")
     Name = Other.Name;
   if (Path == "")
     Path = Other.Path;
   if (Namespace.empty())
     Namespace = std::move(Other.Namespace);
   // Unconditionally extend the description, since each decl may have a comment.
   std::move(Other.Description.begin(), Other.Description.end(),
             std::back_inserter(Description));
   llvm::sort(Description);
   auto Last = std::unique(Description.begin(), Description.end());
   Description.erase(Last, Description.end());
 }

 bool Info::mergeable(const Info &Other) {
   return IT == Other.IT && USR == Other.USR;
 }

 void SymbolInfo::merge(SymbolInfo &&Other) {
   assert(mergeable(Other));
   if (!DefLoc)
     DefLoc = std::move(Other.DefLoc);
   // Unconditionally extend the list of locations, since we want all of them.
   std::move(Other.Loc.begin(), Other.Loc.end(), std::back_inserter(Loc));
   llvm::sort(Loc);
   auto Last = std::unique(Loc.begin(), Loc.end());
   Loc.erase(Last, Loc.end());
   mergeBase(std::move(Other));
 }

 void NamespaceInfo::merge(NamespaceInfo &&Other) {
   assert(mergeable(Other));
   // Reduce children if necessary.
   reduceChildren(ChildNamespaces, std::move(Other.ChildNamespaces));
   reduceChildren(ChildRecords, std::move(Other.ChildRecords));
   reduceChildren(ChildFunctions, std::move(Other.ChildFunctions));
   reduceChildren(ChildEnums, std::move(Other.ChildEnums));
   mergeBase(std::move(Other));
 }

 void RecordInfo::merge(RecordInfo &&Other) {
   assert(mergeable(Other));
   if (!TagType)
     TagType = Other.TagType;
   if (Members.empty())
     Members = std::move(Other.Members);
   if (Bases.empty())
     Bases = std::move(Other.Bases);
   if (Parents.empty())
     Parents = std::move(Other.Parents);
   if (VirtualParents.empty())
     VirtualParents = std::move(Other.VirtualParents);
   // Reduce children if necessary.
   reduceChildren(ChildRecords, std::move(Other.ChildRecords));
   reduceChildren(ChildFunctions, std::move(Other.ChildFunctions));
   reduceChildren(ChildEnums, std::move(Other.ChildEnums));
   SymbolInfo::merge(std::move(Other));
 }

 void EnumInfo::merge(EnumInfo &&Other) {
   assert(mergeable(Other));
   if (!Scoped)
     Scoped = Other.Scoped;
   if (Members.empty())
     Members = std::move(Other.Members);
   SymbolInfo::merge(std::move(Other));
 }

 void FunctionInfo::merge(FunctionInfo &&Other) {
   assert(mergeable(Other));
   if (!IsMethod)
     IsMethod = Other.IsMethod;
   if (!Access)
     Access = Other.Access;
   if (ReturnType.Type.USR == EmptySID && ReturnType.Type.Name == "")
     ReturnType = std::move(Other.ReturnType);
   if (Parent.USR == EmptySID && Parent.Name == "")
     Parent = std::move(Other.Parent);
   if (Params.empty())
     Params = std::move(Other.Params);
   SymbolInfo::merge(std::move(Other));
 }

 llvm::SmallString<16> Info::extractName() const {
   if (!Name.empty())
     return Name;

   switch (IT) {
   case InfoType::IT_namespace:
     // Cover the case where the project contains a base namespace called
     // 'GlobalNamespace' (i.e. a namespace at the same level as the global
     // namespace, which would conflict with the hard-coded global namespace name
     // below.)
     if (Name == "GlobalNamespace" && Namespace.empty())
       return llvm::SmallString<16>("@GlobalNamespace");
     // The case of anonymous namespaces is taken care of in serialization,
     // so here we can safely assume an unnamed namespace is the global
     // one.
     return llvm::SmallString<16>("GlobalNamespace");
   case InfoType::IT_record:
     return llvm::SmallString<16>("@nonymous_record_" +
                                  toHex(llvm::toStringRef(USR)));
   case InfoType::IT_enum:
     return llvm::SmallString<16>("@nonymous_enum_" +
                                  toHex(llvm::toStringRef(USR)));
   case InfoType::IT_function:
     return llvm::SmallString<16>("@nonymous_function_" +
                                  toHex(llvm::toStringRef(USR)));
   case InfoType::IT_default:
     return llvm::SmallString<16>("@nonymous_" + toHex(llvm::toStringRef(USR)));
   }
   llvm_unreachable("Invalid InfoType.");
   return llvm::SmallString<16>("");
 }

 // Order is based on the Name attribute: case insensitive order
 bool Index::operator<(const Index &Other) const {
   // Loop through each character of both strings
   for (unsigned I = 0; I < Name.size() && I < Other.Name.size(); ++I) {
     // Compare them after converting both to lower case
     int D = tolower(Name[I]) - tolower(Other.Name[I]);
     if (D == 0)
       continue;
     return D < 0;
   }
   // If both strings have the size it means they would be equal if changed to
   // lower case. In here, lower case will be smaller than upper case
   // Example: string < stRing = true
   // This is the opposite of how operator < handles strings
   if (Name.size() == Other.Name.size())
     return Name > Other.Name;
   // If they are not the same size; the shorter string is smaller
   return Name.size() < Other.Name.size();
 }

 void Index::sort() {
   llvm::sort(Children);
   for (auto &C : Children)
     C.sort();
 }

 ClangDocContext::ClangDocContext(tooling::ExecutionContext *ECtx,
                                  StringRef ProjectName, bool PublicOnly,
                                  StringRef OutDirectory, StringRef SourceRoot,
                                  StringRef RepositoryUrl,
                                  std::vector<std::string> UserStylesheets,
                                  std::vector<std::string> JsScripts)
     : ECtx(ECtx), ProjectName(ProjectName), PublicOnly(PublicOnly),
       OutDirectory(OutDirectory), UserStylesheets(UserStylesheets),
       JsScripts(JsScripts) {
   llvm::SmallString<128> SourceRootDir(SourceRoot);
   if (SourceRoot.empty())
     // If no SourceRoot was provided the current path is used as the default
     llvm::sys::fs::current_path(SourceRootDir);
   this->SourceRoot = std::string(SourceRootDir.str());
   if (!RepositoryUrl.empty()) {
     this->RepositoryUrl = std::string(RepositoryUrl);
     if (!RepositoryUrl.empty() && RepositoryUrl.find("http://") != 0 &&
         RepositoryUrl.find("https://") != 0)
       this->RepositoryUrl->insert(0, "https://");
   }
 }

 } // namespace doc
 } // namespace clang
	///===-- Representation.cpp - ClangDoc Representation ------------ C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the merging of different types of infos. The data in the
	// calling Info is preserved during a merge unless that field is empty or
	// default. In that case, the data from the parameter Info is used to replace
	// the empty or default data.
	//
	// For most fields, the first decl seen provides the data. Exceptions to this
	// include the location and description fields, which are collections of data on
	// all decls related to a given definition. All other fields are ignored in new
	// decls unless the first seen decl didn't, for whatever reason, incorporate
	// data on that field (e.g. a forward declared class wouldn't have information
	// on members on the forward declaration, but would have the class name).
	//
	//===----------------------------------------------------------------------===//
	#include "Representation.h"
	#include "llvm/Support/Error.h"
	#include "llvm/Support/Path.h"

	namespace clang {
	namespace doc {

	namespace {

	const SymbolID EmptySID = SymbolID();

	template <typename T>
	llvm::Expected<std::unique_ptr<Info>>
	reduce(std::vector<std::unique_ptr<Info>> &Values) {
	if (Values.empty())
	return llvm::createStringError(llvm::inconvertibleErrorCode(),
	"no value to reduce");
	std::unique_ptr<Info> Merged = std::make_unique<T>(Values[0]->USR);
	T Tmp = static_cast<T >(Merged.get());
	for (auto &I : Values)
	Tmp->merge(std::move(static_cast<T >(I.get())));
	return std::move(Merged);
	}

	// Return the index of the matching child in the vector, or -1 if merge is not
	// necessary.
	template <typename T>
	int getChildIndexIfExists(std::vector<T> &Children, T &ChildToMerge) {
	for (unsigned long I = 0; I < Children.size(); I++) {
	if (ChildToMerge.USR == Children[I].USR)
	return I;
	}
	return -1;
	}

	void reduceChildren(std::vector<Reference> &Children,
	std::vector<Reference> &&ChildrenToMerge) {
	for (auto &ChildToMerge : ChildrenToMerge) {
	int mergeIdx = getChildIndexIfExists(Children, ChildToMerge);
	if (mergeIdx == -1) {
	Children.push_back(std::move(ChildToMerge));
	continue;
	}
	Children[mergeIdx].merge(std::move(ChildToMerge));
	}
	}

	void reduceChildren(std::vector<FunctionInfo> &Children,
	std::vector<FunctionInfo> &&ChildrenToMerge) {
	for (auto &ChildToMerge : ChildrenToMerge) {
	int mergeIdx = getChildIndexIfExists(Children, ChildToMerge);
	if (mergeIdx == -1) {
	Children.push_back(std::move(ChildToMerge));
	continue;
	}
	Children[mergeIdx].merge(std::move(ChildToMerge));
	}
	}

	void reduceChildren(std::vector<EnumInfo> &Children,
	std::vector<EnumInfo> &&ChildrenToMerge) {
	for (auto &ChildToMerge : ChildrenToMerge) {
	int mergeIdx = getChildIndexIfExists(Children, ChildToMerge);
	if (mergeIdx == -1) {
	Children.push_back(std::move(ChildToMerge));
	continue;
	}
	Children[mergeIdx].merge(std::move(ChildToMerge));
	}
	}

	} // namespace

	// Dispatch function.
	llvm::Expected<std::unique_ptr<Info>>
	mergeInfos(std::vector<std::unique_ptr<Info>> &Values) {
	if (Values.empty())
	return llvm::createStringError(llvm::inconvertibleErrorCode(),
	"no info values to merge");

	switch (Values[0]->IT) {
	case InfoType::IT_namespace:
	return reduce<NamespaceInfo>(Values);
	case InfoType::IT_record:
	return reduce<RecordInfo>(Values);
	case InfoType::IT_enum:
	return reduce<EnumInfo>(Values);
	case InfoType::IT_function:
	return reduce<FunctionInfo>(Values);
	default:
	return llvm::createStringError(llvm::inconvertibleErrorCode(),
	"unexpected info type");
	}
	}

	static llvm::SmallString<64>
	calculateRelativeFilePath(const InfoType &Type, const StringRef &Path,
	const StringRef &Name, const StringRef &CurrentPath) {
	llvm::SmallString<64> FilePath;

	if (CurrentPath != Path) {
	// iterate back to the top
	for (llvm::sys::path::const_iterator I =
	llvm::sys::path::begin(CurrentPath);
	I != llvm::sys::path::end(CurrentPath); ++I)
	llvm::sys::path::append(FilePath, "..");
	llvm::sys::path::append(FilePath, Path);
	}

	// Namespace references have a Path to the parent namespace, but
	// the file is actually in the subdirectory for the namespace.
	if (Type == doc::InfoType::IT_namespace)
	llvm::sys::path::append(FilePath, Name);

	return llvm::sys::path::relative_path(FilePath);
	}

	llvm::SmallString<64>
	Reference::getRelativeFilePath(const StringRef &CurrentPath) const {
	return calculateRelativeFilePath(RefType, Path, Name, CurrentPath);
	}

	llvm::SmallString<16> Reference::getFileBaseName() const {
	if (RefType == InfoType::IT_namespace)
	return llvm::SmallString<16>("index");

	return Name;
	}

	llvm::SmallString<64>
	Info::getRelativeFilePath(const StringRef &CurrentPath) const {
	return calculateRelativeFilePath(IT, Path, extractName(), CurrentPath);
	}

	llvm::SmallString<16> Info::getFileBaseName() const {
	if (IT == InfoType::IT_namespace)
	return llvm::SmallString<16>("index");

	return extractName();
	}

	bool Reference::mergeable(const Reference &Other) {
	return RefType == Other.RefType && USR == Other.USR;
	}

	void Reference::merge(Reference &&Other) {
	assert(mergeable(Other));
	if (Name.empty())
	Name = Other.Name;
	if (Path.empty())
	Path = Other.Path;
	if (!IsInGlobalNamespace)
	IsInGlobalNamespace = Other.IsInGlobalNamespace;
	}

	void Info::mergeBase(Info &&Other) {
	assert(mergeable(Other));
	if (USR == EmptySID)
	USR = Other.USR;
	if (Name == "")
	Name = Other.Name;
	if (Path == "")
	Path = Other.Path;
	if (Namespace.empty())
	Namespace = std::move(Other.Namespace);
	// Unconditionally extend the description, since each decl may have a comment.
	std::move(Other.Description.begin(), Other.Description.end(),
	std::back_inserter(Description));
	llvm::sort(Description);
	auto Last = std::unique(Description.begin(), Description.end());
	Description.erase(Last, Description.end());
	}

	bool Info::mergeable(const Info &Other) {
	return IT == Other.IT && USR == Other.USR;
	}

	void SymbolInfo::merge(SymbolInfo &&Other) {
	assert(mergeable(Other));
	if (!DefLoc)
	DefLoc = std::move(Other.DefLoc);
	// Unconditionally extend the list of locations, since we want all of them.
	std::move(Other.Loc.begin(), Other.Loc.end(), std::back_inserter(Loc));
	llvm::sort(Loc);
	auto Last = std::unique(Loc.begin(), Loc.end());
	Loc.erase(Last, Loc.end());
	mergeBase(std::move(Other));
	}

	void NamespaceInfo::merge(NamespaceInfo &&Other) {
	assert(mergeable(Other));
	// Reduce children if necessary.
	reduceChildren(ChildNamespaces, std::move(Other.ChildNamespaces));
	reduceChildren(ChildRecords, std::move(Other.ChildRecords));
	reduceChildren(ChildFunctions, std::move(Other.ChildFunctions));
	reduceChildren(ChildEnums, std::move(Other.ChildEnums));
	mergeBase(std::move(Other));
	}

	void RecordInfo::merge(RecordInfo &&Other) {
	assert(mergeable(Other));
	if (!TagType)
	TagType = Other.TagType;
	if (Members.empty())
	Members = std::move(Other.Members);
	if (Bases.empty())
	Bases = std::move(Other.Bases);
	if (Parents.empty())
	Parents = std::move(Other.Parents);
	if (VirtualParents.empty())
	VirtualParents = std::move(Other.VirtualParents);
	// Reduce children if necessary.
	reduceChildren(ChildRecords, std::move(Other.ChildRecords));
	reduceChildren(ChildFunctions, std::move(Other.ChildFunctions));
	reduceChildren(ChildEnums, std::move(Other.ChildEnums));
	SymbolInfo::merge(std::move(Other));
	}

	void EnumInfo::merge(EnumInfo &&Other) {
	assert(mergeable(Other));
	if (!Scoped)
	Scoped = Other.Scoped;
	if (Members.empty())
	Members = std::move(Other.Members);
	SymbolInfo::merge(std::move(Other));
	}

	void FunctionInfo::merge(FunctionInfo &&Other) {
	assert(mergeable(Other));
	if (!IsMethod)
	IsMethod = Other.IsMethod;
	if (!Access)
	Access = Other.Access;
	if (ReturnType.Type.USR == EmptySID && ReturnType.Type.Name == "")
	ReturnType = std::move(Other.ReturnType);
	if (Parent.USR == EmptySID && Parent.Name == "")
	Parent = std::move(Other.Parent);
	if (Params.empty())
	Params = std::move(Other.Params);
	SymbolInfo::merge(std::move(Other));
	}

	llvm::SmallString<16> Info::extractName() const {
	if (!Name.empty())
	return Name;

	switch (IT) {
	case InfoType::IT_namespace:
	// Cover the case where the project contains a base namespace called
	// 'GlobalNamespace' (i.e. a namespace at the same level as the global
	// namespace, which would conflict with the hard-coded global namespace name
	// below.)
	if (Name == "GlobalNamespace" && Namespace.empty())
	return llvm::SmallString<16>("@GlobalNamespace");
	// The case of anonymous namespaces is taken care of in serialization,
	// so here we can safely assume an unnamed namespace is the global
	// one.
	return llvm::SmallString<16>("GlobalNamespace");
	case InfoType::IT_record:
	return llvm::SmallString<16>("@nonymous_record_" +
	toHex(llvm::toStringRef(USR)));
	case InfoType::IT_enum:
	return llvm::SmallString<16>("@nonymous_enum_" +
	toHex(llvm::toStringRef(USR)));
	case InfoType::IT_function:
	return llvm::SmallString<16>("@nonymous_function_" +
	toHex(llvm::toStringRef(USR)));
	case InfoType::IT_default:
	return llvm::SmallString<16>("@nonymous_" + toHex(llvm::toStringRef(USR)));
	}
	llvm_unreachable("Invalid InfoType.");
	return llvm::SmallString<16>("");
	}

	// Order is based on the Name attribute: case insensitive order
	bool Index::operator<(const Index &Other) const {
	// Loop through each character of both strings
	for (unsigned I = 0; I < Name.size() && I < Other.Name.size(); ++I) {
	// Compare them after converting both to lower case
	int D = tolower(Name[I]) - tolower(Other.Name[I]);
	if (D == 0)
	continue;
	return D < 0;
	}
	// If both strings have the size it means they would be equal if changed to
	// lower case. In here, lower case will be smaller than upper case
	// Example: string < stRing = true
	// This is the opposite of how operator < handles strings
	if (Name.size() == Other.Name.size())
	return Name > Other.Name;
	// If they are not the same size; the shorter string is smaller
	return Name.size() < Other.Name.size();
	}

	void Index::sort() {
	llvm::sort(Children);
	for (auto &C : Children)
	C.sort();
	}

	ClangDocContext::ClangDocContext(tooling::ExecutionContext *ECtx,
	StringRef ProjectName, bool PublicOnly,
	StringRef OutDirectory, StringRef SourceRoot,
	StringRef RepositoryUrl,
	std::vector<std::string> UserStylesheets,
	std::vector<std::string> JsScripts)
	: ECtx(ECtx), ProjectName(ProjectName), PublicOnly(PublicOnly),
	OutDirectory(OutDirectory), UserStylesheets(UserStylesheets),
	JsScripts(JsScripts) {
	llvm::SmallString<128> SourceRootDir(SourceRoot);
	if (SourceRoot.empty())
	// If no SourceRoot was provided the current path is used as the default
	llvm::sys::fs::current_path(SourceRootDir);
	this->SourceRoot = std::string(SourceRootDir.str());
	if (!RepositoryUrl.empty()) {
	this->RepositoryUrl = std::string(RepositoryUrl);
	if (!RepositoryUrl.empty() && RepositoryUrl.find("http://") != 0 &&
	RepositoryUrl.find("https://") != 0)
	this->RepositoryUrl->insert(0, "https://");
	}
	}

	} // namespace doc
	} // namespace clang