Source/cmOrderDirectories.cxx - third_party/cmake - Git at Google

 /* Distributed under the OSI-approved BSD 3-Clause License.  See accompanying
    file Copyright.txt or https://cmake.org/licensing for details.  */
 #include "cmOrderDirectories.h"

 #include "cmAlgorithms.h"
 #include "cmGeneratorTarget.h"
 #include "cmGlobalGenerator.h"
 #include "cmSystemTools.h"
 #include "cmake.h"

 #include <algorithm>
 #include <assert.h>
 #include <functional>
 #include <sstream>

 /*
 Directory ordering computation.
   - Useful to compute a safe runtime library path order
   - Need runtime path for supporting INSTALL_RPATH_USE_LINK_PATH
   - Need runtime path at link time to pickup transitive link dependencies
     for shared libraries.
 */

 class cmOrderDirectoriesConstraint
 {
 public:
   cmOrderDirectoriesConstraint(cmOrderDirectories* od, std::string const& file)
     : OD(od)
     , GlobalGenerator(od->GlobalGenerator)
   {
     this->FullPath = file;

     if (file.rfind(".framework") != std::string::npos) {
       static cmsys::RegularExpression splitFramework(
         "^(.*)/(.*).framework/(.*)$");
       if (splitFramework.find(file) &&
           (std::string::npos !=
            splitFramework.match(3).find(splitFramework.match(2)))) {
         this->Directory = splitFramework.match(1);
         this->FileName =
           std::string(file.begin() + this->Directory.size() + 1, file.end());
       }
     }

     if (this->FileName.empty()) {
       this->Directory = cmSystemTools::GetFilenamePath(file);
       this->FileName = cmSystemTools::GetFilenameName(file);
     }
   }
   virtual ~cmOrderDirectoriesConstraint() {}

   void AddDirectory()
   {
     this->DirectoryIndex = this->OD->AddOriginalDirectory(this->Directory);
   }

   virtual void Report(std::ostream& e) = 0;

   void FindConflicts(unsigned int index)
   {
     for (unsigned int i = 0; i < this->OD->OriginalDirectories.size(); ++i) {
       // Check if this directory conflicts with the entry.
       std::string const& dir = this->OD->OriginalDirectories[i];
       if (!this->OD->IsSameDirectory(dir, this->Directory) &&
           this->FindConflict(dir)) {
         // The library will be found in this directory but this is not
         // the directory named for it.  Add an entry to make sure the
         // desired directory comes before this one.
         cmOrderDirectories::ConflictPair p(this->DirectoryIndex, index);
         this->OD->ConflictGraph[i].push_back(p);
       }
     }
   }

   void FindImplicitConflicts(std::ostringstream& w)
   {
     bool first = true;
     for (std::string const& dir : this->OD->OriginalDirectories) {
       // Check if this directory conflicts with the entry.
       if (dir != this->Directory &&
           cmSystemTools::GetRealPath(dir) !=
             cmSystemTools::GetRealPath(this->Directory) &&
           this->FindConflict(dir)) {
         // The library will be found in this directory but it is
         // supposed to be found in an implicit search directory.
         if (first) {
           first = false;
           w << "  ";
           this->Report(w);
           w << " in " << this->Directory << " may be hidden by files in:\n";
         }
         w << "    " << dir << "\n";
       }
     }
   }

 protected:
   virtual bool FindConflict(std::string const& dir) = 0;

   bool FileMayConflict(std::string const& dir, std::string const& name);

   cmOrderDirectories* OD;
   cmGlobalGenerator* GlobalGenerator;

   // The location in which the item is supposed to be found.
   std::string FullPath;
   std::string Directory;
   std::string FileName;

   // The index assigned to the directory.
   int DirectoryIndex;
 };

 bool cmOrderDirectoriesConstraint::FileMayConflict(std::string const& dir,
                                                    std::string const& name)
 {
   // Check if the file exists on disk.
   std::string file = dir;
   file += "/";
   file += name;
   if (cmSystemTools::FileExists(file, true)) {
     // The file conflicts only if it is not the same as the original
     // file due to a symlink or hardlink.
     return !cmSystemTools::SameFile(this->FullPath, file);
   }

   // Check if the file will be built by cmake.
   std::set<std::string> const& files =
     (this->GlobalGenerator->GetDirectoryContent(dir, false));
   std::set<std::string>::const_iterator fi = files.find(name);
   return fi != files.end();
 }

 class cmOrderDirectoriesConstraintSOName : public cmOrderDirectoriesConstraint
 {
 public:
   cmOrderDirectoriesConstraintSOName(cmOrderDirectories* od,
                                      std::string const& file,
                                      const char* soname)
     : cmOrderDirectoriesConstraint(od, file)
     , SOName(soname ? soname : "")
   {
     if (this->SOName.empty()) {
       // Try to guess the soname.
       std::string soguess;
       if (cmSystemTools::GuessLibrarySOName(file, soguess)) {
         this->SOName = soguess;
       }
     }
   }

   void Report(std::ostream& e) override
   {
     e << "runtime library [";
     if (this->SOName.empty()) {
       e << this->FileName;
     } else {
       e << this->SOName;
     }
     e << "]";
   }

   bool FindConflict(std::string const& dir) override;

 private:
   // The soname of the shared library if it is known.
   std::string SOName;
 };

 bool cmOrderDirectoriesConstraintSOName::FindConflict(std::string const& dir)
 {
   // Determine which type of check to do.
   if (!this->SOName.empty()) {
     // We have the library soname.  Check if it will be found.
     if (this->FileMayConflict(dir, this->SOName)) {
       return true;
     }
   } else {
     // We do not have the soname.  Look for files in the directory
     // that may conflict.
     std::set<std::string> const& files =
       (this->GlobalGenerator->GetDirectoryContent(dir, true));

     // Get the set of files that might conflict.  Since we do not
     // know the soname just look at all files that start with the
     // file name.  Usually the soname starts with the library name.
     std::string base = this->FileName;
     std::set<std::string>::const_iterator first = files.lower_bound(base);
     ++base[base.size() - 1];
     std::set<std::string>::const_iterator last = files.upper_bound(base);
     if (first != last) {
       return true;
     }
   }
   return false;
 }

 class cmOrderDirectoriesConstraintLibrary : public cmOrderDirectoriesConstraint
 {
 public:
   cmOrderDirectoriesConstraintLibrary(cmOrderDirectories* od,
                                       std::string const& file)
     : cmOrderDirectoriesConstraint(od, file)
   {
   }

   void Report(std::ostream& e) override
   {
     e << "link library [" << this->FileName << "]";
   }

   bool FindConflict(std::string const& dir) override;
 };

 bool cmOrderDirectoriesConstraintLibrary::FindConflict(std::string const& dir)
 {
   // We have the library file name.  Check if it will be found.
   if (this->FileMayConflict(dir, this->FileName)) {
     return true;
   }

   // Now check if the file exists with other extensions the linker
   // might consider.
   if (!this->OD->LinkExtensions.empty() &&
       this->OD->RemoveLibraryExtension.find(this->FileName)) {
     std::string lib = this->OD->RemoveLibraryExtension.match(1);
     std::string ext = this->OD->RemoveLibraryExtension.match(2);
     for (std::string const& LinkExtension : this->OD->LinkExtensions) {
       if (LinkExtension != ext) {
         std::string fname = lib;
         fname += LinkExtension;
         if (this->FileMayConflict(dir, fname)) {
           return true;
         }
       }
     }
   }
   return false;
 }

 cmOrderDirectories::cmOrderDirectories(cmGlobalGenerator* gg,
                                        const cmGeneratorTarget* target,
                                        const char* purpose)
 {
   this->GlobalGenerator = gg;
   this->Target = target;
   this->Purpose = purpose;
   this->Computed = false;
 }

 cmOrderDirectories::~cmOrderDirectories()
 {
   cmDeleteAll(this->ConstraintEntries);
   cmDeleteAll(this->ImplicitDirEntries);
 }

 std::vector<std::string> const& cmOrderDirectories::GetOrderedDirectories()
 {
   if (!this->Computed) {
     this->Computed = true;
     this->CollectOriginalDirectories();
     this->FindConflicts();
     this->OrderDirectories();
   }
   return this->OrderedDirectories;
 }

 void cmOrderDirectories::AddRuntimeLibrary(std::string const& fullPath,
                                            const char* soname)
 {
   // Add the runtime library at most once.
   if (this->EmmittedConstraintSOName.insert(fullPath).second) {
     // Implicit link directories need special handling.
     if (!this->ImplicitDirectories.empty()) {
       std::string dir = cmSystemTools::GetFilenamePath(fullPath);

       if (fullPath.rfind(".framework") != std::string::npos) {
         static cmsys::RegularExpression splitFramework(
           "^(.*)/(.*).framework/(.*)$");
         if (splitFramework.find(fullPath) &&
             (std::string::npos !=
              splitFramework.match(3).find(splitFramework.match(2)))) {
           dir = splitFramework.match(1);
         }
       }

       if (this->IsImplicitDirectory(dir)) {
         this->ImplicitDirEntries.push_back(
           new cmOrderDirectoriesConstraintSOName(this, fullPath, soname));
         return;
       }
     }

     // Construct the runtime information entry for this library.
     this->ConstraintEntries.push_back(
       new cmOrderDirectoriesConstraintSOName(this, fullPath, soname));
   } else {
     // This can happen if the same library is linked multiple times.
     // In that case the runtime information check need be done only
     // once anyway.  For shared libs we could add a check in AddItem
     // to not repeat them.
   }
 }

 void cmOrderDirectories::AddLinkLibrary(std::string const& fullPath)
 {
   // Link extension info is required for library constraints.
   assert(!this->LinkExtensions.empty());

   // Add the link library at most once.
   if (this->EmmittedConstraintLibrary.insert(fullPath).second) {
     // Implicit link directories need special handling.
     if (!this->ImplicitDirectories.empty()) {
       std::string dir = cmSystemTools::GetFilenamePath(fullPath);
       if (this->IsImplicitDirectory(dir)) {
         this->ImplicitDirEntries.push_back(
           new cmOrderDirectoriesConstraintLibrary(this, fullPath));
         return;
       }
     }

     // Construct the link library entry.
     this->ConstraintEntries.push_back(
       new cmOrderDirectoriesConstraintLibrary(this, fullPath));
   }
 }

 void cmOrderDirectories::AddUserDirectories(
   std::vector<std::string> const& extra)
 {
   this->UserDirectories.insert(this->UserDirectories.end(), extra.begin(),
                                extra.end());
 }

 void cmOrderDirectories::AddLanguageDirectories(
   std::vector<std::string> const& dirs)
 {
   this->LanguageDirectories.insert(this->LanguageDirectories.end(),
                                    dirs.begin(), dirs.end());
 }

 void cmOrderDirectories::SetImplicitDirectories(
   std::set<std::string> const& implicitDirs)
 {
   this->ImplicitDirectories.clear();
   for (std::string const& implicitDir : implicitDirs) {
     this->ImplicitDirectories.insert(this->GetRealPath(implicitDir));
   }
 }

 bool cmOrderDirectories::IsImplicitDirectory(std::string const& dir)
 {
   std::string const& real = this->GetRealPath(dir);
   return this->ImplicitDirectories.find(real) !=
     this->ImplicitDirectories.end();
 }

 void cmOrderDirectories::SetLinkExtensionInfo(
   std::vector<std::string> const& linkExtensions,
   std::string const& removeExtRegex)
 {
   this->LinkExtensions = linkExtensions;
   this->RemoveLibraryExtension.compile(removeExtRegex.c_str());
 }

 void cmOrderDirectories::CollectOriginalDirectories()
 {
   // Add user directories specified for inclusion.  These should be
   // indexed first so their original order is preserved as much as
   // possible subject to the constraints.
   this->AddOriginalDirectories(this->UserDirectories);

   // Add directories containing constraints.
   for (cmOrderDirectoriesConstraint* entry : this->ConstraintEntries) {
     entry->AddDirectory();
   }

   // Add language runtime directories last.
   this->AddOriginalDirectories(this->LanguageDirectories);
 }

 int cmOrderDirectories::AddOriginalDirectory(std::string const& dir)
 {
   // Add the runtime directory with a unique index.
   std::map<std::string, int>::iterator i = this->DirectoryIndex.find(dir);
   if (i == this->DirectoryIndex.end()) {
     std::map<std::string, int>::value_type entry(
       dir, static_cast<int>(this->OriginalDirectories.size()));
     i = this->DirectoryIndex.insert(entry).first;
     this->OriginalDirectories.push_back(dir);
   }

   return i->second;
 }

 void cmOrderDirectories::AddOriginalDirectories(
   std::vector<std::string> const& dirs)
 {
   for (std::string const& dir : dirs) {
     // We never explicitly specify implicit link directories.
     if (this->IsImplicitDirectory(dir)) {
       continue;
     }

     // Skip the empty string.
     if (dir.empty()) {
       continue;
     }

     // Add this directory.
     this->AddOriginalDirectory(dir);
   }
 }

 struct cmOrderDirectoriesCompare
 {
   typedef std::pair<int, int> ConflictPair;

   // The conflict pair is unique based on just the directory
   // (first).  The second element is only used for displaying
   // information about why the entry is present.
   bool operator()(ConflictPair l, ConflictPair r)
   {
     return l.first == r.first;
   }
 };

 void cmOrderDirectories::FindConflicts()
 {
   // Allocate the conflict graph.
   this->ConflictGraph.resize(this->OriginalDirectories.size());
   this->DirectoryVisited.resize(this->OriginalDirectories.size(), 0);

   // Find directories conflicting with each entry.
   for (unsigned int i = 0; i < this->ConstraintEntries.size(); ++i) {
     this->ConstraintEntries[i]->FindConflicts(i);
   }

   // Clean up the conflict graph representation.
   for (ConflictList& cl : this->ConflictGraph) {
     // Sort the outgoing edges for each graph node so that the
     // original order will be preserved as much as possible.
     std::sort(cl.begin(), cl.end());

     // Make the edge list unique so cycle detection will be reliable.
     ConflictList::iterator last =
       std::unique(cl.begin(), cl.end(), cmOrderDirectoriesCompare());
     cl.erase(last, cl.end());
   }

   // Check items in implicit link directories.
   this->FindImplicitConflicts();
 }

 void cmOrderDirectories::FindImplicitConflicts()
 {
   // Check for items in implicit link directories that have conflicts
   // in the explicit directories.
   std::ostringstream conflicts;
   for (cmOrderDirectoriesConstraint* entry : this->ImplicitDirEntries) {
     entry->FindImplicitConflicts(conflicts);
   }

   // Skip warning if there were no conflicts.
   std::string const text = conflicts.str();
   if (text.empty()) {
     return;
   }

   // Warn about the conflicts.
   std::ostringstream w;
   w << "Cannot generate a safe " << this->Purpose << " for target "
     << this->Target->GetName()
     << " because files in some directories may conflict with "
     << " libraries in implicit directories:\n"
     << text << "Some of these libraries may not be found correctly.";
   this->GlobalGenerator->GetCMakeInstance()->IssueMessage(
     cmake::WARNING, w.str(), this->Target->GetBacktrace());
 }

 void cmOrderDirectories::OrderDirectories()
 {
   // Allow a cycle to be diagnosed once.
   this->CycleDiagnosed = false;
   this->WalkId = 0;

   // Iterate through the directories in the original order.
   for (unsigned int i = 0; i < this->OriginalDirectories.size(); ++i) {
     // Start a new DFS from this node.
     ++this->WalkId;
     this->VisitDirectory(i);
   }
 }

 void cmOrderDirectories::VisitDirectory(unsigned int i)
 {
   // Skip nodes already visited.
   if (this->DirectoryVisited[i]) {
     if (this->DirectoryVisited[i] == this->WalkId) {
       // We have reached a node previously visited on this DFS.
       // There is a cycle.
       this->DiagnoseCycle();
     }
     return;
   }

   // We are now visiting this node so mark it.
   this->DirectoryVisited[i] = this->WalkId;

   // Visit the neighbors of the node first.
   ConflictList const& clist = this->ConflictGraph[i];
   for (ConflictPair const& j : clist) {
     this->VisitDirectory(j.first);
   }

   // Now that all directories required to come before this one have
   // been emmitted, emit this directory.
   this->OrderedDirectories.push_back(this->OriginalDirectories[i]);
 }

 void cmOrderDirectories::DiagnoseCycle()
 {
   // Report the cycle at most once.
   if (this->CycleDiagnosed) {
     return;
   }
   this->CycleDiagnosed = true;

   // Construct the message.
   std::ostringstream e;
   e << "Cannot generate a safe " << this->Purpose << " for target "
     << this->Target->GetName()
     << " because there is a cycle in the constraint graph:\n";

   // Display the conflict graph.
   for (unsigned int i = 0; i < this->ConflictGraph.size(); ++i) {
     ConflictList const& clist = this->ConflictGraph[i];
     e << "  dir " << i << " is [" << this->OriginalDirectories[i] << "]\n";
     for (ConflictPair const& j : clist) {
       e << "    dir " << j.first << " must precede it due to ";
       this->ConstraintEntries[j.second]->Report(e);
       e << "\n";
     }
   }
   e << "Some of these libraries may not be found correctly.";
   this->GlobalGenerator->GetCMakeInstance()->IssueMessage(
     cmake::WARNING, e.str(), this->Target->GetBacktrace());
 }

 bool cmOrderDirectories::IsSameDirectory(std::string const& l,
                                          std::string const& r)
 {
   return this->GetRealPath(l) == this->GetRealPath(r);
 }

 std::string const& cmOrderDirectories::GetRealPath(std::string const& dir)
 {
   std::map<std::string, std::string>::iterator i =
     this->RealPaths.lower_bound(dir);
   if (i == this->RealPaths.end() ||
       this->RealPaths.key_comp()(dir, i->first)) {
     typedef std::map<std::string, std::string>::value_type value_type;
     i = this->RealPaths.insert(
       i, value_type(dir, cmSystemTools::GetRealPath(dir)));
   }
   return i->second;
 }
	/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
	file Copyright.txt or https://cmake.org/licensing for details. */
	#include "cmOrderDirectories.h"

	#include "cmAlgorithms.h"
	#include "cmGeneratorTarget.h"
	#include "cmGlobalGenerator.h"
	#include "cmSystemTools.h"
	#include "cmake.h"

	#include <algorithm>
	#include <assert.h>
	#include <functional>
	#include <sstream>

	/*
	Directory ordering computation.
	- Useful to compute a safe runtime library path order
	- Need runtime path for supporting INSTALL_RPATH_USE_LINK_PATH
	- Need runtime path at link time to pickup transitive link dependencies
	for shared libraries.
	*/

	class cmOrderDirectoriesConstraint
	{
	public:
	cmOrderDirectoriesConstraint(cmOrderDirectories* od, std::string const& file)
	: OD(od)
	, GlobalGenerator(od->GlobalGenerator)
	{
	this->FullPath = file;

	if (file.rfind(".framework") != std::string::npos) {
	static cmsys::RegularExpression splitFramework(
	"^(.)/(.).framework/(.*)$");
	if (splitFramework.find(file) &&
	(std::string::npos !=
	splitFramework.match(3).find(splitFramework.match(2)))) {
	this->Directory = splitFramework.match(1);
	this->FileName =
	std::string(file.begin() + this->Directory.size() + 1, file.end());
	}
	}

	if (this->FileName.empty()) {
	this->Directory = cmSystemTools::GetFilenamePath(file);
	this->FileName = cmSystemTools::GetFilenameName(file);
	}
	}
	virtual ~cmOrderDirectoriesConstraint() {}

	void AddDirectory()
	{
	this->DirectoryIndex = this->OD->AddOriginalDirectory(this->Directory);
	}

	virtual void Report(std::ostream& e) = 0;

	void FindConflicts(unsigned int index)
	{
	for (unsigned int i = 0; i < this->OD->OriginalDirectories.size(); ++i) {
	// Check if this directory conflicts with the entry.
	std::string const& dir = this->OD->OriginalDirectories[i];
	if (!this->OD->IsSameDirectory(dir, this->Directory) &&
	this->FindConflict(dir)) {
	// The library will be found in this directory but this is not
	// the directory named for it. Add an entry to make sure the
	// desired directory comes before this one.
	cmOrderDirectories::ConflictPair p(this->DirectoryIndex, index);
	this->OD->ConflictGraph[i].push_back(p);
	}
	}
	}

	void FindImplicitConflicts(std::ostringstream& w)
	{
	bool first = true;
	for (std::string const& dir : this->OD->OriginalDirectories) {
	// Check if this directory conflicts with the entry.
	if (dir != this->Directory &&
	cmSystemTools::GetRealPath(dir) !=
	cmSystemTools::GetRealPath(this->Directory) &&
	this->FindConflict(dir)) {
	// The library will be found in this directory but it is
	// supposed to be found in an implicit search directory.
	if (first) {
	first = false;
	w << " ";
	this->Report(w);
	w << " in " << this->Directory << " may be hidden by files in:\n";
	}
	w << " " << dir << "\n";
	}
	}
	}

	protected:
	virtual bool FindConflict(std::string const& dir) = 0;

	bool FileMayConflict(std::string const& dir, std::string const& name);

	cmOrderDirectories* OD;
	cmGlobalGenerator* GlobalGenerator;

	// The location in which the item is supposed to be found.
	std::string FullPath;
	std::string Directory;
	std::string FileName;

	// The index assigned to the directory.
	int DirectoryIndex;
	};

	bool cmOrderDirectoriesConstraint::FileMayConflict(std::string const& dir,
	std::string const& name)
	{
	// Check if the file exists on disk.
	std::string file = dir;
	file += "/";
	file += name;
	if (cmSystemTools::FileExists(file, true)) {
	// The file conflicts only if it is not the same as the original
	// file due to a symlink or hardlink.
	return !cmSystemTools::SameFile(this->FullPath, file);
	}

	// Check if the file will be built by cmake.
	std::set<std::string> const& files =
	(this->GlobalGenerator->GetDirectoryContent(dir, false));
	std::set<std::string>::const_iterator fi = files.find(name);
	return fi != files.end();
	}

	class cmOrderDirectoriesConstraintSOName : public cmOrderDirectoriesConstraint
	{
	public:
	cmOrderDirectoriesConstraintSOName(cmOrderDirectories* od,
	std::string const& file,
	const char* soname)
	: cmOrderDirectoriesConstraint(od, file)
	, SOName(soname ? soname : "")
	{
	if (this->SOName.empty()) {
	// Try to guess the soname.
	std::string soguess;
	if (cmSystemTools::GuessLibrarySOName(file, soguess)) {
	this->SOName = soguess;
	}
	}
	}

	void Report(std::ostream& e) override
	{
	e << "runtime library [";
	if (this->SOName.empty()) {
	e << this->FileName;
	} else {
	e << this->SOName;
	}
	e << "]";
	}

	bool FindConflict(std::string const& dir) override;

	private:
	// The soname of the shared library if it is known.
	std::string SOName;
	};

	bool cmOrderDirectoriesConstraintSOName::FindConflict(std::string const& dir)
	{
	// Determine which type of check to do.
	if (!this->SOName.empty()) {
	// We have the library soname. Check if it will be found.
	if (this->FileMayConflict(dir, this->SOName)) {
	return true;
	}
	} else {
	// We do not have the soname. Look for files in the directory
	// that may conflict.
	std::set<std::string> const& files =
	(this->GlobalGenerator->GetDirectoryContent(dir, true));

	// Get the set of files that might conflict. Since we do not
	// know the soname just look at all files that start with the
	// file name. Usually the soname starts with the library name.
	std::string base = this->FileName;
	std::set<std::string>::const_iterator first = files.lower_bound(base);
	++base[base.size() - 1];
	std::set<std::string>::const_iterator last = files.upper_bound(base);
	if (first != last) {
	return true;
	}
	}
	return false;
	}

	class cmOrderDirectoriesConstraintLibrary : public cmOrderDirectoriesConstraint
	{
	public:
	cmOrderDirectoriesConstraintLibrary(cmOrderDirectories* od,
	std::string const& file)
	: cmOrderDirectoriesConstraint(od, file)
	{
	}

	void Report(std::ostream& e) override
	{
	e << "link library [" << this->FileName << "]";
	}

	bool FindConflict(std::string const& dir) override;
	};

	bool cmOrderDirectoriesConstraintLibrary::FindConflict(std::string const& dir)
	{
	// We have the library file name. Check if it will be found.
	if (this->FileMayConflict(dir, this->FileName)) {
	return true;
	}

	// Now check if the file exists with other extensions the linker
	// might consider.
	if (!this->OD->LinkExtensions.empty() &&
	this->OD->RemoveLibraryExtension.find(this->FileName)) {
	std::string lib = this->OD->RemoveLibraryExtension.match(1);
	std::string ext = this->OD->RemoveLibraryExtension.match(2);
	for (std::string const& LinkExtension : this->OD->LinkExtensions) {
	if (LinkExtension != ext) {
	std::string fname = lib;
	fname += LinkExtension;
	if (this->FileMayConflict(dir, fname)) {
	return true;
	}
	}
	}
	}
	return false;
	}

	cmOrderDirectories::cmOrderDirectories(cmGlobalGenerator* gg,
	const cmGeneratorTarget* target,
	const char* purpose)
	{
	this->GlobalGenerator = gg;
	this->Target = target;
	this->Purpose = purpose;
	this->Computed = false;
	}

	cmOrderDirectories::~cmOrderDirectories()
	{
	cmDeleteAll(this->ConstraintEntries);
	cmDeleteAll(this->ImplicitDirEntries);
	}

	std::vector<std::string> const& cmOrderDirectories::GetOrderedDirectories()
	{
	if (!this->Computed) {
	this->Computed = true;
	this->CollectOriginalDirectories();
	this->FindConflicts();
	this->OrderDirectories();
	}
	return this->OrderedDirectories;
	}

	void cmOrderDirectories::AddRuntimeLibrary(std::string const& fullPath,
	const char* soname)
	{
	// Add the runtime library at most once.
	if (this->EmmittedConstraintSOName.insert(fullPath).second) {
	// Implicit link directories need special handling.
	if (!this->ImplicitDirectories.empty()) {
	std::string dir = cmSystemTools::GetFilenamePath(fullPath);

	if (fullPath.rfind(".framework") != std::string::npos) {
	static cmsys::RegularExpression splitFramework(
	"^(.)/(.).framework/(.*)$");
	if (splitFramework.find(fullPath) &&
	(std::string::npos !=
	splitFramework.match(3).find(splitFramework.match(2)))) {
	dir = splitFramework.match(1);
	}
	}

	if (this->IsImplicitDirectory(dir)) {
	this->ImplicitDirEntries.push_back(
	new cmOrderDirectoriesConstraintSOName(this, fullPath, soname));
	return;
	}
	}

	// Construct the runtime information entry for this library.
	this->ConstraintEntries.push_back(
	new cmOrderDirectoriesConstraintSOName(this, fullPath, soname));
	} else {
	// This can happen if the same library is linked multiple times.
	// In that case the runtime information check need be done only
	// once anyway. For shared libs we could add a check in AddItem
	// to not repeat them.
	}
	}

	void cmOrderDirectories::AddLinkLibrary(std::string const& fullPath)
	{
	// Link extension info is required for library constraints.
	assert(!this->LinkExtensions.empty());

	// Add the link library at most once.
	if (this->EmmittedConstraintLibrary.insert(fullPath).second) {
	// Implicit link directories need special handling.
	if (!this->ImplicitDirectories.empty()) {
	std::string dir = cmSystemTools::GetFilenamePath(fullPath);
	if (this->IsImplicitDirectory(dir)) {
	this->ImplicitDirEntries.push_back(
	new cmOrderDirectoriesConstraintLibrary(this, fullPath));
	return;
	}
	}

	// Construct the link library entry.
	this->ConstraintEntries.push_back(
	new cmOrderDirectoriesConstraintLibrary(this, fullPath));
	}
	}

	void cmOrderDirectories::AddUserDirectories(
	std::vector<std::string> const& extra)
	{
	this->UserDirectories.insert(this->UserDirectories.end(), extra.begin(),
	extra.end());
	}

	void cmOrderDirectories::AddLanguageDirectories(
	std::vector<std::string> const& dirs)
	{
	this->LanguageDirectories.insert(this->LanguageDirectories.end(),
	dirs.begin(), dirs.end());
	}

	void cmOrderDirectories::SetImplicitDirectories(
	std::set<std::string> const& implicitDirs)
	{
	this->ImplicitDirectories.clear();
	for (std::string const& implicitDir : implicitDirs) {
	this->ImplicitDirectories.insert(this->GetRealPath(implicitDir));
	}
	}

	bool cmOrderDirectories::IsImplicitDirectory(std::string const& dir)
	{
	std::string const& real = this->GetRealPath(dir);
	return this->ImplicitDirectories.find(real) !=
	this->ImplicitDirectories.end();
	}

	void cmOrderDirectories::SetLinkExtensionInfo(
	std::vector<std::string> const& linkExtensions,
	std::string const& removeExtRegex)
	{
	this->LinkExtensions = linkExtensions;
	this->RemoveLibraryExtension.compile(removeExtRegex.c_str());
	}

	void cmOrderDirectories::CollectOriginalDirectories()
	{
	// Add user directories specified for inclusion. These should be
	// indexed first so their original order is preserved as much as
	// possible subject to the constraints.
	this->AddOriginalDirectories(this->UserDirectories);

	// Add directories containing constraints.
	for (cmOrderDirectoriesConstraint* entry : this->ConstraintEntries) {
	entry->AddDirectory();
	}

	// Add language runtime directories last.
	this->AddOriginalDirectories(this->LanguageDirectories);
	}

	int cmOrderDirectories::AddOriginalDirectory(std::string const& dir)
	{
	// Add the runtime directory with a unique index.
	std::map<std::string, int>::iterator i = this->DirectoryIndex.find(dir);
	if (i == this->DirectoryIndex.end()) {
	std::map<std::string, int>::value_type entry(
	dir, static_cast<int>(this->OriginalDirectories.size()));
	i = this->DirectoryIndex.insert(entry).first;
	this->OriginalDirectories.push_back(dir);
	}

	return i->second;
	}

	void cmOrderDirectories::AddOriginalDirectories(
	std::vector<std::string> const& dirs)
	{
	for (std::string const& dir : dirs) {
	// We never explicitly specify implicit link directories.
	if (this->IsImplicitDirectory(dir)) {
	continue;
	}

	// Skip the empty string.
	if (dir.empty()) {
	continue;
	}

	// Add this directory.
	this->AddOriginalDirectory(dir);
	}
	}

	struct cmOrderDirectoriesCompare
	{
	typedef std::pair<int, int> ConflictPair;

	// The conflict pair is unique based on just the directory
	// (first). The second element is only used for displaying
	// information about why the entry is present.
	bool operator()(ConflictPair l, ConflictPair r)
	{
	return l.first == r.first;
	}
	};

	void cmOrderDirectories::FindConflicts()
	{
	// Allocate the conflict graph.
	this->ConflictGraph.resize(this->OriginalDirectories.size());
	this->DirectoryVisited.resize(this->OriginalDirectories.size(), 0);

	// Find directories conflicting with each entry.
	for (unsigned int i = 0; i < this->ConstraintEntries.size(); ++i) {
	this->ConstraintEntries[i]->FindConflicts(i);
	}

	// Clean up the conflict graph representation.
	for (ConflictList& cl : this->ConflictGraph) {
	// Sort the outgoing edges for each graph node so that the
	// original order will be preserved as much as possible.
	std::sort(cl.begin(), cl.end());

	// Make the edge list unique so cycle detection will be reliable.
	ConflictList::iterator last =
	std::unique(cl.begin(), cl.end(), cmOrderDirectoriesCompare());
	cl.erase(last, cl.end());
	}

	// Check items in implicit link directories.
	this->FindImplicitConflicts();
	}

	void cmOrderDirectories::FindImplicitConflicts()
	{
	// Check for items in implicit link directories that have conflicts
	// in the explicit directories.
	std::ostringstream conflicts;
	for (cmOrderDirectoriesConstraint* entry : this->ImplicitDirEntries) {
	entry->FindImplicitConflicts(conflicts);
	}

	// Skip warning if there were no conflicts.
	std::string const text = conflicts.str();
	if (text.empty()) {
	return;
	}

	// Warn about the conflicts.
	std::ostringstream w;
	w << "Cannot generate a safe " << this->Purpose << " for target "
	<< this->Target->GetName()
	<< " because files in some directories may conflict with "
	<< " libraries in implicit directories:\n"
	<< text << "Some of these libraries may not be found correctly.";
	this->GlobalGenerator->GetCMakeInstance()->IssueMessage(
	cmake::WARNING, w.str(), this->Target->GetBacktrace());
	}

	void cmOrderDirectories::OrderDirectories()
	{
	// Allow a cycle to be diagnosed once.
	this->CycleDiagnosed = false;
	this->WalkId = 0;

	// Iterate through the directories in the original order.
	for (unsigned int i = 0; i < this->OriginalDirectories.size(); ++i) {
	// Start a new DFS from this node.
	++this->WalkId;
	this->VisitDirectory(i);
	}
	}

	void cmOrderDirectories::VisitDirectory(unsigned int i)
	{
	// Skip nodes already visited.
	if (this->DirectoryVisited[i]) {
	if (this->DirectoryVisited[i] == this->WalkId) {
	// We have reached a node previously visited on this DFS.
	// There is a cycle.
	this->DiagnoseCycle();
	}
	return;
	}

	// We are now visiting this node so mark it.
	this->DirectoryVisited[i] = this->WalkId;

	// Visit the neighbors of the node first.
	ConflictList const& clist = this->ConflictGraph[i];
	for (ConflictPair const& j : clist) {
	this->VisitDirectory(j.first);
	}

	// Now that all directories required to come before this one have
	// been emmitted, emit this directory.
	this->OrderedDirectories.push_back(this->OriginalDirectories[i]);
	}

	void cmOrderDirectories::DiagnoseCycle()
	{
	// Report the cycle at most once.
	if (this->CycleDiagnosed) {
	return;
	}
	this->CycleDiagnosed = true;

	// Construct the message.
	std::ostringstream e;
	e << "Cannot generate a safe " << this->Purpose << " for target "
	<< this->Target->GetName()
	<< " because there is a cycle in the constraint graph:\n";

	// Display the conflict graph.
	for (unsigned int i = 0; i < this->ConflictGraph.size(); ++i) {
	ConflictList const& clist = this->ConflictGraph[i];
	e << " dir " << i << " is [" << this->OriginalDirectories[i] << "]\n";
	for (ConflictPair const& j : clist) {
	e << " dir " << j.first << " must precede it due to ";
	this->ConstraintEntries[j.second]->Report(e);
	e << "\n";
	}
	}
	e << "Some of these libraries may not be found correctly.";
	this->GlobalGenerator->GetCMakeInstance()->IssueMessage(
	cmake::WARNING, e.str(), this->Target->GetBacktrace());
	}

	bool cmOrderDirectories::IsSameDirectory(std::string const& l,
	std::string const& r)
	{
	return this->GetRealPath(l) == this->GetRealPath(r);
	}

	std::string const& cmOrderDirectories::GetRealPath(std::string const& dir)
	{
	std::map<std::string, std::string>::iterator i =
	this->RealPaths.lower_bound(dir);
	if (i == this->RealPaths.end() \|\|
	this->RealPaths.key_comp()(dir, i->first)) {
	typedef std::map<std::string, std::string>::value_type value_type;
	i = this->RealPaths.insert(
	i, value_type(dir, cmSystemTools::GetRealPath(dir)));
	}
	return i->second;
	}