CPP/Common/Wildcard.cpp - platform/external/lzma - Git at Google

 // Common/Wildcard.cpp

 #include "StdAfx.h"

 #include "Wildcard.h"

 bool g_CaseSensitive =
   #ifdef _WIN32
     false;
   #else
     true;
   #endif


 bool IsPath1PrefixedByPath2(const wchar_t *s1, const wchar_t *s2)
 {
   if (g_CaseSensitive)
   {
     for (;;)
     {
       wchar_t c2 = *s2++; if (c2 == 0) return true;
       wchar_t c1 = *s1++;
       if (MyCharUpper(c1) !=
           MyCharUpper(c2))
         return false;
     }
   }

   for (;;)
   {
     wchar_t c2 = *s2++; if (c2 == 0) return true;
     wchar_t c1 = *s1++; if (c1 != c2) return false;
   }
 }

 int CompareFileNames(const wchar_t *s1, const wchar_t *s2) STRING_UNICODE_THROW
 {
   if (g_CaseSensitive)
     return wcscmp(s1, s2);
   return MyStringCompareNoCase(s1, s2);
 }

 #ifndef USE_UNICODE_FSTRING
 int CompareFileNames(const char *s1, const char *s2)
 {
   if (g_CaseSensitive)
     return wcscmp(fs2us(s1), fs2us(s2));
   return MyStringCompareNoCase(fs2us(s1), fs2us(s2));
 }
 #endif

 // -----------------------------------------
 // this function compares name with mask
 // ? - any char
 // * - any char or empty

 static bool EnhancedMaskTest(const wchar_t *mask, const wchar_t *name)
 {
   for (;;)
   {
     wchar_t m = *mask;
     wchar_t c = *name;
     if (m == 0)
       return (c == 0);
     if (m == '*')
     {
       if (EnhancedMaskTest(mask + 1, name))
         return true;
       if (c == 0)
         return false;
     }
     else
     {
       if (m == '?')
       {
         if (c == 0)
           return false;
       }
       else if (m != c)
         if (g_CaseSensitive || MyCharUpper(m) != MyCharUpper(c))
           return false;
       mask++;
     }
     name++;
   }
 }

 // --------------------------------------------------
 // Splits path to strings

 void SplitPathToParts(const UString &path, UStringVector &pathParts)
 {
   pathParts.Clear();
   unsigned len = path.Len();
   if (len == 0)
     return;
   UString name;
   unsigned prev = 0;
   for (unsigned i = 0; i < len; i++)
     if (IsCharDirLimiter(path[i]))
     {
       name.SetFrom(path.Ptr(prev), i - prev);
       pathParts.Add(name);
       prev = i + 1;
     }
   name.SetFrom(path.Ptr(prev), len - prev);
   pathParts.Add(name);
 }

 void SplitPathToParts_2(const UString &path, UString &dirPrefix, UString &name)
 {
   const wchar_t *start = path;
   const wchar_t *p = start + path.Len();
   for (; p != start; p--)
     if (IsCharDirLimiter(*(p - 1)))
       break;
   dirPrefix.SetFrom(path, (unsigned)(p - start));
   name = p;
 }

 void SplitPathToParts_Smart(const UString &path, UString &dirPrefix, UString &name)
 {
   const wchar_t *start = path;
   const wchar_t *p = start + path.Len();
   if (p != start)
   {
     if (IsCharDirLimiter(*(p - 1)))
       p--;
     for (; p != start; p--)
       if (IsCharDirLimiter(*(p - 1)))
         break;
   }
   dirPrefix.SetFrom(path, (unsigned)(p - start));
   name = p;
 }

 UString ExtractDirPrefixFromPath(const UString &path)
 {
   const wchar_t *start = path;
   const wchar_t *p = start + path.Len();
   for (; p != start; p--)
     if (IsCharDirLimiter(*(p - 1)))
       break;
   return path.Left((unsigned)(p - start));
 }

 UString ExtractFileNameFromPath(const UString &path)
 {
   const wchar_t *start = path;
   const wchar_t *p = start + path.Len();
   for (; p != start; p--)
     if (IsCharDirLimiter(*(p - 1)))
       break;
   return p;
 }


 bool DoesWildcardMatchName(const UString &mask, const UString &name)
 {
   return EnhancedMaskTest(mask, name);
 }

 bool DoesNameContainWildcard(const UString &path)
 {
   for (unsigned i = 0; i < path.Len(); i++)
   {
     wchar_t c = path[i];
     if (c == '*' || c == '?')
       return true;
   }
   return false;
 }


 // ----------------------------------------------------------'
 // NWildcard

 namespace NWildcard {


 #ifdef _WIN32
 bool IsDriveColonName(const wchar_t *s)
 {
   wchar_t c = s[0];
   return c != 0 && s[1] == ':' && s[2] == 0 && (c >= 'a' && c <= 'z' || c >= 'A' && c <= 'Z');
 }
 #endif

 /*

 M = MaskParts.Size();
 N = TestNameParts.Size();

                            File                          Dir
 ForFile     rec   M<=N  [N-M, N)                          -
 !ForDir  nonrec   M=N   [0, M)                            -

 ForDir      rec   M<N   [0, M) ... [N-M-1, N-1)  same as ForBoth-File
 !ForFile nonrec         [0, M)                   same as ForBoth-File

 ForFile     rec   m<=N  [0, M) ... [N-M, N)      same as ForBoth-File
 ForDir   nonrec         [0, M)                   same as ForBoth-File

 */

 bool CItem::AreAllAllowed() const
 {
   return ForFile && ForDir && WildcardMatching && PathParts.Size() == 1 && PathParts.Front() == L"*";
 }

 bool CItem::CheckPath(const UStringVector &pathParts, bool isFile) const
 {
   if (!isFile && !ForDir)
     return false;
   int delta = (int)pathParts.Size() - (int)PathParts.Size();
   if (delta < 0)
     return false;
   int start = 0;
   int finish = 0;

   if (isFile)
   {
     if (!ForDir)
     {
       if (Recursive)
         start = delta;
       else if (delta !=0)
         return false;
     }
     if (!ForFile && delta == 0)
       return false;
   }

   if (Recursive)
   {
     finish = delta;
     if (isFile && !ForFile)
       finish = delta - 1;
   }

   for (int d = start; d <= finish; d++)
   {
     unsigned i;
     for (i = 0; i < PathParts.Size(); i++)
     {
       if (WildcardMatching)
       {
         if (!DoesWildcardMatchName(PathParts[i], pathParts[i + d]))
           break;
       }
       else
       {
         if (CompareFileNames(PathParts[i], pathParts[i + d]) != 0)
           break;
       }
     }
     if (i == PathParts.Size())
       return true;
   }
   return false;
 }

 bool CCensorNode::AreAllAllowed() const
 {
   if (!Name.IsEmpty() ||
       !SubNodes.IsEmpty() ||
       !ExcludeItems.IsEmpty() ||
       IncludeItems.Size() != 1)
     return false;
   return IncludeItems.Front().AreAllAllowed();
 }

 int CCensorNode::FindSubNode(const UString &name) const
 {
   FOR_VECTOR (i, SubNodes)
     if (CompareFileNames(SubNodes[i].Name, name) == 0)
       return i;
   return -1;
 }

 void CCensorNode::AddItemSimple(bool include, CItem &item)
 {
   if (include)
     IncludeItems.Add(item);
   else
     ExcludeItems.Add(item);
 }

 void CCensorNode::AddItem(bool include, CItem &item)
 {
   if (item.PathParts.Size() <= 1)
   {
     if (item.PathParts.Size() != 0 && item.WildcardMatching)
     {
       if (!DoesNameContainWildcard(item.PathParts.Front()))
         item.WildcardMatching = false;
     }
     AddItemSimple(include, item);
     return;
   }
   const UString &front = item.PathParts.Front();

   // We can't ignore wildcard, since we don't allow wildcard in SubNodes[].Name
   // if (item.Wildcard)
   if (DoesNameContainWildcard(front))
   {
     AddItemSimple(include, item);
     return;
   }
   int index = FindSubNode(front);
   if (index < 0)
     index = SubNodes.Add(CCensorNode(front, this));
   item.PathParts.Delete(0);
   SubNodes[index].AddItem(include, item);
 }

 void CCensorNode::AddItem(bool include, const UString &path, bool recursive, bool forFile, bool forDir, bool wildcardMatching)
 {
   CItem item;
   SplitPathToParts(path, item.PathParts);
   item.Recursive = recursive;
   item.ForFile = forFile;
   item.ForDir = forDir;
   item.WildcardMatching = wildcardMatching;
   AddItem(include, item);
 }

 bool CCensorNode::NeedCheckSubDirs() const
 {
   FOR_VECTOR (i, IncludeItems)
   {
     const CItem &item = IncludeItems[i];
     if (item.Recursive || item.PathParts.Size() > 1)
       return true;
   }
   return false;
 }

 bool CCensorNode::AreThereIncludeItems() const
 {
   if (IncludeItems.Size() > 0)
     return true;
   FOR_VECTOR (i, SubNodes)
     if (SubNodes[i].AreThereIncludeItems())
       return true;
   return false;
 }

 bool CCensorNode::CheckPathCurrent(bool include, const UStringVector &pathParts, bool isFile) const
 {
   const CObjectVector<CItem> &items = include ? IncludeItems : ExcludeItems;
   FOR_VECTOR (i, items)
     if (items[i].CheckPath(pathParts, isFile))
       return true;
   return false;
 }

 bool CCensorNode::CheckPathVect(const UStringVector &pathParts, bool isFile, bool &include) const
 {
   if (CheckPathCurrent(false, pathParts, isFile))
   {
     include = false;
     return true;
   }
   include = true;
   bool finded = CheckPathCurrent(true, pathParts, isFile);
   if (pathParts.Size() <= 1)
     return finded;
   int index = FindSubNode(pathParts.Front());
   if (index >= 0)
   {
     UStringVector pathParts2 = pathParts;
     pathParts2.Delete(0);
     if (SubNodes[index].CheckPathVect(pathParts2, isFile, include))
       return true;
   }
   return finded;
 }

 bool CCensorNode::CheckPath2(bool isAltStream, const UString &path, bool isFile, bool &include) const
 {
   UStringVector pathParts;
   SplitPathToParts(path, pathParts);
   if (CheckPathVect(pathParts, isFile, include))
   {
     if (!include || !isAltStream)
       return true;
   }
   if (isAltStream && !pathParts.IsEmpty())
   {
     UString &back = pathParts.Back();
     int pos = back.Find(L':');
     if (pos > 0)
     {
       back.DeleteFrom(pos);
       return CheckPathVect(pathParts, isFile, include);
     }
   }
   return false;
 }

 bool CCensorNode::CheckPath(bool isAltStream, const UString &path, bool isFile) const
 {
   bool include;
   if (CheckPath2(isAltStream, path, isFile, include))
     return include;
   return false;
 }

 bool CCensorNode::CheckPathToRoot(bool include, UStringVector &pathParts, bool isFile) const
 {
   if (CheckPathCurrent(include, pathParts, isFile))
     return true;
   if (Parent == 0)
     return false;
   pathParts.Insert(0, Name);
   return Parent->CheckPathToRoot(include, pathParts, isFile);
 }

 /*
 bool CCensorNode::CheckPathToRoot(bool include, const UString &path, bool isFile) const
 {
   UStringVector pathParts;
   SplitPathToParts(path, pathParts);
   return CheckPathToRoot(include, pathParts, isFile);
 }
 */

 void CCensorNode::AddItem2(bool include, const UString &path, bool recursive, bool wildcardMatching)
 {
   if (path.IsEmpty())
     return;
   bool forFile = true;
   bool forFolder = true;
   UString path2 = path;
   if (IsCharDirLimiter(path.Back()))
   {
     path2.DeleteBack();
     forFile = false;
   }
   AddItem(include, path2, recursive, forFile, forFolder, wildcardMatching);
 }

 void CCensorNode::ExtendExclude(const CCensorNode &fromNodes)
 {
   ExcludeItems += fromNodes.ExcludeItems;
   FOR_VECTOR (i, fromNodes.SubNodes)
   {
     const CCensorNode &node = fromNodes.SubNodes[i];
     int subNodeIndex = FindSubNode(node.Name);
     if (subNodeIndex < 0)
       subNodeIndex = SubNodes.Add(CCensorNode(node.Name, this));
     SubNodes[subNodeIndex].ExtendExclude(node);
   }
 }

 int CCensor::FindPrefix(const UString &prefix) const
 {
   FOR_VECTOR (i, Pairs)
     if (CompareFileNames(Pairs[i].Prefix, prefix) == 0)
       return i;
   return -1;
 }

 void CCensor::AddItem(ECensorPathMode pathMode, bool include, const UString &path, bool recursive, bool wildcardMatching)
 {
   UStringVector pathParts;
   if (path.IsEmpty())
     throw "Empty file path";
   SplitPathToParts(path, pathParts);
   bool forFile = true;
   if (pathParts.Back().IsEmpty())
   {
     forFile = false;
     pathParts.DeleteBack();
   }

   UString prefix;

   if (pathMode != k_AbsPath)
   {
     const UString &front = pathParts.Front();
     bool isAbs = false;

     if (front.IsEmpty())
       isAbs = true;
     else
     {
       #ifdef _WIN32

       if (IsDriveColonName(front))
         isAbs = true;
       else

       #endif

         FOR_VECTOR (i, pathParts)
         {
           const UString &part = pathParts[i];
           if (part == L".." || part == L".")
           {
             isAbs = true;
             break;
           }
         }
     }

     unsigned numAbsParts = 0;
     if (isAbs)
       if (pathParts.Size() > 1)
         numAbsParts = pathParts.Size() - 1;
       else
         numAbsParts = 1;

     #ifdef _WIN32

     // \\?\ case
     if (numAbsParts >= 3)
     {
       if (pathParts[0].IsEmpty() &&
           pathParts[1].IsEmpty() &&
           pathParts[2] == L"?")
       {
         prefix =
             WSTRING_PATH_SEPARATOR
             WSTRING_PATH_SEPARATOR L"?"
             WSTRING_PATH_SEPARATOR;
         numAbsParts -= 3;
         pathParts.DeleteFrontal(3);
       }
     }

     #endif

     if (numAbsParts > 1 && pathMode == k_FullPath)
       numAbsParts = 1;

     // We can't ignore wildcard, since we don't allow wildcard in SubNodes[].Name
     // if (wildcardMatching)
     for (unsigned i = 0; i < numAbsParts; i++)
     {
       {
         const UString &front = pathParts.Front();
         if (DoesNameContainWildcard(front))
           break;
         prefix += front;
         prefix += WCHAR_PATH_SEPARATOR;
       }
       pathParts.Delete(0);
     }
   }

   int index = FindPrefix(prefix);
   if (index < 0)
     index = Pairs.Add(CPair(prefix));

   CItem item;
   item.PathParts = pathParts;
   item.ForDir = true;
   item.ForFile = forFile;
   item.Recursive = recursive;
   item.WildcardMatching = wildcardMatching;
   Pairs[index].Head.AddItem(include, item);
 }

 bool CCensor::CheckPath(bool isAltStream, const UString &path, bool isFile) const
 {
   bool finded = false;
   FOR_VECTOR (i, Pairs)
   {
     bool include;
     if (Pairs[i].Head.CheckPath2(isAltStream, path, isFile, include))
     {
       if (!include)
         return false;
       finded = true;
     }
   }
   return finded;
 }

 void CCensor::ExtendExclude()
 {
   unsigned i;
   for (i = 0; i < Pairs.Size(); i++)
     if (Pairs[i].Prefix.IsEmpty())
       break;
   if (i == Pairs.Size())
     return;
   unsigned index = i;
   for (i = 0; i < Pairs.Size(); i++)
     if (index != i)
       Pairs[i].Head.ExtendExclude(Pairs[index].Head);
 }

 void CCensor::AddPathsToCensor(ECensorPathMode censorPathMode)
 {
   FOR_VECTOR(i, CensorPaths)
   {
     const CCensorPath &cp = CensorPaths[i];
     AddItem(censorPathMode, cp.Include, cp.Path, cp.Recursive, cp.WildcardMatching);
   }
   CensorPaths.Clear();
 }

 void CCensor::AddPreItem(bool include, const UString &path, bool recursive, bool wildcardMatching)
 {
   CCensorPath &cp = CensorPaths.AddNew();
   cp.Path = path;
   cp.Include = include;
   cp.Recursive = recursive;
   cp.WildcardMatching = wildcardMatching;
 }

 }
	// Common/Wildcard.cpp

	#include "StdAfx.h"

	#include "Wildcard.h"

	bool g_CaseSensitive =
	#ifdef _WIN32
	false;
	#else
	true;
	#endif


	bool IsPath1PrefixedByPath2(const wchar_t s1, const wchar_t s2)
	{
	if (g_CaseSensitive)
	{
	for (;;)
	{
	wchar_t c2 = *s2++; if (c2 == 0) return true;
	wchar_t c1 = *s1++;
	if (MyCharUpper(c1) !=
	MyCharUpper(c2))
	return false;
	}
	}

	for (;;)
	{
	wchar_t c2 = *s2++; if (c2 == 0) return true;
	wchar_t c1 = *s1++; if (c1 != c2) return false;
	}
	}

	int CompareFileNames(const wchar_t s1, const wchar_t s2) STRING_UNICODE_THROW
	{
	if (g_CaseSensitive)
	return wcscmp(s1, s2);
	return MyStringCompareNoCase(s1, s2);
	}

	#ifndef USE_UNICODE_FSTRING
	int CompareFileNames(const char s1, const char s2)
	{
	if (g_CaseSensitive)
	return wcscmp(fs2us(s1), fs2us(s2));
	return MyStringCompareNoCase(fs2us(s1), fs2us(s2));
	}
	#endif

	// -----------------------------------------
	// this function compares name with mask
	// ? - any char
	// * - any char or empty

	static bool EnhancedMaskTest(const wchar_t mask, const wchar_t name)
	{
	for (;;)
	{
	wchar_t m = *mask;
	wchar_t c = *name;
	if (m == 0)
	return (c == 0);
	if (m == '*')
	{
	if (EnhancedMaskTest(mask + 1, name))
	return true;
	if (c == 0)
	return false;
	}
	else
	{
	if (m == '?')
	{
	if (c == 0)
	return false;
	}
	else if (m != c)
	if (g_CaseSensitive \|\| MyCharUpper(m) != MyCharUpper(c))
	return false;
	mask++;
	}
	name++;
	}
	}

	// --------------------------------------------------
	// Splits path to strings

	void SplitPathToParts(const UString &path, UStringVector &pathParts)
	{
	pathParts.Clear();
	unsigned len = path.Len();
	if (len == 0)
	return;
	UString name;
	unsigned prev = 0;
	for (unsigned i = 0; i < len; i++)
	if (IsCharDirLimiter(path[i]))
	{
	name.SetFrom(path.Ptr(prev), i - prev);
	pathParts.Add(name);
	prev = i + 1;
	}
	name.SetFrom(path.Ptr(prev), len - prev);
	pathParts.Add(name);
	}

	void SplitPathToParts_2(const UString &path, UString &dirPrefix, UString &name)
	{
	const wchar_t *start = path;
	const wchar_t *p = start + path.Len();
	for (; p != start; p--)
	if (IsCharDirLimiter(*(p - 1)))
	break;
	dirPrefix.SetFrom(path, (unsigned)(p - start));
	name = p;
	}

	void SplitPathToParts_Smart(const UString &path, UString &dirPrefix, UString &name)
	{
	const wchar_t *start = path;
	const wchar_t *p = start + path.Len();
	if (p != start)
	{
	if (IsCharDirLimiter(*(p - 1)))
	p--;
	for (; p != start; p--)
	if (IsCharDirLimiter(*(p - 1)))
	break;
	}
	dirPrefix.SetFrom(path, (unsigned)(p - start));
	name = p;
	}

	UString ExtractDirPrefixFromPath(const UString &path)
	{
	const wchar_t *start = path;
	const wchar_t *p = start + path.Len();
	for (; p != start; p--)
	if (IsCharDirLimiter(*(p - 1)))
	break;
	return path.Left((unsigned)(p - start));
	}

	UString ExtractFileNameFromPath(const UString &path)
	{
	const wchar_t *start = path;
	const wchar_t *p = start + path.Len();
	for (; p != start; p--)
	if (IsCharDirLimiter(*(p - 1)))
	break;
	return p;
	}


	bool DoesWildcardMatchName(const UString &mask, const UString &name)
	{
	return EnhancedMaskTest(mask, name);
	}

	bool DoesNameContainWildcard(const UString &path)
	{
	for (unsigned i = 0; i < path.Len(); i++)
	{
	wchar_t c = path[i];
	if (c == '*' \|\| c == '?')
	return true;
	}
	return false;
	}


	// ----------------------------------------------------------'
	// NWildcard

	namespace NWildcard {


	#ifdef _WIN32
	bool IsDriveColonName(const wchar_t *s)
	{
	wchar_t c = s[0];
	return c != 0 && s[1] == ':' && s[2] == 0 && (c >= 'a' && c <= 'z' \|\| c >= 'A' && c <= 'Z');
	}
	#endif

	/*

	M = MaskParts.Size();
	N = TestNameParts.Size();

	File Dir
	ForFile rec M<=N [N-M, N) -
	!ForDir nonrec M=N [0, M) -

	ForDir rec M<N [0, M) ... [N-M-1, N-1) same as ForBoth-File
	!ForFile nonrec [0, M) same as ForBoth-File

	ForFile rec m<=N [0, M) ... [N-M, N) same as ForBoth-File
	ForDir nonrec [0, M) same as ForBoth-File

	*/

	bool CItem::AreAllAllowed() const
	{
	return ForFile && ForDir && WildcardMatching && PathParts.Size() == 1 && PathParts.Front() == L"*";
	}

	bool CItem::CheckPath(const UStringVector &pathParts, bool isFile) const
	{
	if (!isFile && !ForDir)
	return false;
	int delta = (int)pathParts.Size() - (int)PathParts.Size();
	if (delta < 0)
	return false;
	int start = 0;
	int finish = 0;

	if (isFile)
	{
	if (!ForDir)
	{
	if (Recursive)
	start = delta;
	else if (delta !=0)
	return false;
	}
	if (!ForFile && delta == 0)
	return false;
	}

	if (Recursive)
	{
	finish = delta;
	if (isFile && !ForFile)
	finish = delta - 1;
	}

	for (int d = start; d <= finish; d++)
	{
	unsigned i;
	for (i = 0; i < PathParts.Size(); i++)
	{
	if (WildcardMatching)
	{
	if (!DoesWildcardMatchName(PathParts[i], pathParts[i + d]))
	break;
	}
	else
	{
	if (CompareFileNames(PathParts[i], pathParts[i + d]) != 0)
	break;
	}
	}
	if (i == PathParts.Size())
	return true;
	}
	return false;
	}

	bool CCensorNode::AreAllAllowed() const
	{
	if (!Name.IsEmpty() \|\|
	!SubNodes.IsEmpty() \|\|
	!ExcludeItems.IsEmpty() \|\|
	IncludeItems.Size() != 1)
	return false;
	return IncludeItems.Front().AreAllAllowed();
	}

	int CCensorNode::FindSubNode(const UString &name) const
	{
	FOR_VECTOR (i, SubNodes)
	if (CompareFileNames(SubNodes[i].Name, name) == 0)
	return i;
	return -1;
	}

	void CCensorNode::AddItemSimple(bool include, CItem &item)
	{
	if (include)
	IncludeItems.Add(item);
	else
	ExcludeItems.Add(item);
	}

	void CCensorNode::AddItem(bool include, CItem &item)
	{
	if (item.PathParts.Size() <= 1)
	{
	if (item.PathParts.Size() != 0 && item.WildcardMatching)
	{
	if (!DoesNameContainWildcard(item.PathParts.Front()))
	item.WildcardMatching = false;
	}
	AddItemSimple(include, item);
	return;
	}
	const UString &front = item.PathParts.Front();

	// We can't ignore wildcard, since we don't allow wildcard in SubNodes[].Name
	// if (item.Wildcard)
	if (DoesNameContainWildcard(front))
	{
	AddItemSimple(include, item);
	return;
	}
	int index = FindSubNode(front);
	if (index < 0)
	index = SubNodes.Add(CCensorNode(front, this));
	item.PathParts.Delete(0);
	SubNodes[index].AddItem(include, item);
	}

	void CCensorNode::AddItem(bool include, const UString &path, bool recursive, bool forFile, bool forDir, bool wildcardMatching)
	{
	CItem item;
	SplitPathToParts(path, item.PathParts);
	item.Recursive = recursive;
	item.ForFile = forFile;
	item.ForDir = forDir;
	item.WildcardMatching = wildcardMatching;
	AddItem(include, item);
	}

	bool CCensorNode::NeedCheckSubDirs() const
	{
	FOR_VECTOR (i, IncludeItems)
	{
	const CItem &item = IncludeItems[i];
	if (item.Recursive \|\| item.PathParts.Size() > 1)
	return true;
	}
	return false;
	}

	bool CCensorNode::AreThereIncludeItems() const
	{
	if (IncludeItems.Size() > 0)
	return true;
	FOR_VECTOR (i, SubNodes)
	if (SubNodes[i].AreThereIncludeItems())
	return true;
	return false;
	}

	bool CCensorNode::CheckPathCurrent(bool include, const UStringVector &pathParts, bool isFile) const
	{
	const CObjectVector<CItem> &items = include ? IncludeItems : ExcludeItems;
	FOR_VECTOR (i, items)
	if (items[i].CheckPath(pathParts, isFile))
	return true;
	return false;
	}

	bool CCensorNode::CheckPathVect(const UStringVector &pathParts, bool isFile, bool &include) const
	{
	if (CheckPathCurrent(false, pathParts, isFile))
	{
	include = false;
	return true;
	}
	include = true;
	bool finded = CheckPathCurrent(true, pathParts, isFile);
	if (pathParts.Size() <= 1)
	return finded;
	int index = FindSubNode(pathParts.Front());
	if (index >= 0)
	{
	UStringVector pathParts2 = pathParts;
	pathParts2.Delete(0);
	if (SubNodes[index].CheckPathVect(pathParts2, isFile, include))
	return true;
	}
	return finded;
	}

	bool CCensorNode::CheckPath2(bool isAltStream, const UString &path, bool isFile, bool &include) const
	{
	UStringVector pathParts;
	SplitPathToParts(path, pathParts);
	if (CheckPathVect(pathParts, isFile, include))
	{
	if (!include \|\| !isAltStream)
	return true;
	}
	if (isAltStream && !pathParts.IsEmpty())
	{
	UString &back = pathParts.Back();
	int pos = back.Find(L':');
	if (pos > 0)
	{
	back.DeleteFrom(pos);
	return CheckPathVect(pathParts, isFile, include);
	}
	}
	return false;
	}

	bool CCensorNode::CheckPath(bool isAltStream, const UString &path, bool isFile) const
	{
	bool include;
	if (CheckPath2(isAltStream, path, isFile, include))
	return include;
	return false;
	}

	bool CCensorNode::CheckPathToRoot(bool include, UStringVector &pathParts, bool isFile) const
	{
	if (CheckPathCurrent(include, pathParts, isFile))
	return true;
	if (Parent == 0)
	return false;
	pathParts.Insert(0, Name);
	return Parent->CheckPathToRoot(include, pathParts, isFile);
	}

	/*
	bool CCensorNode::CheckPathToRoot(bool include, const UString &path, bool isFile) const
	{
	UStringVector pathParts;
	SplitPathToParts(path, pathParts);
	return CheckPathToRoot(include, pathParts, isFile);
	}
	*/

	void CCensorNode::AddItem2(bool include, const UString &path, bool recursive, bool wildcardMatching)
	{
	if (path.IsEmpty())
	return;
	bool forFile = true;
	bool forFolder = true;
	UString path2 = path;
	if (IsCharDirLimiter(path.Back()))
	{
	path2.DeleteBack();
	forFile = false;
	}
	AddItem(include, path2, recursive, forFile, forFolder, wildcardMatching);
	}

	void CCensorNode::ExtendExclude(const CCensorNode &fromNodes)
	{
	ExcludeItems += fromNodes.ExcludeItems;
	FOR_VECTOR (i, fromNodes.SubNodes)
	{
	const CCensorNode &node = fromNodes.SubNodes[i];
	int subNodeIndex = FindSubNode(node.Name);
	if (subNodeIndex < 0)
	subNodeIndex = SubNodes.Add(CCensorNode(node.Name, this));
	SubNodes[subNodeIndex].ExtendExclude(node);
	}
	}

	int CCensor::FindPrefix(const UString &prefix) const
	{
	FOR_VECTOR (i, Pairs)
	if (CompareFileNames(Pairs[i].Prefix, prefix) == 0)
	return i;
	return -1;
	}

	void CCensor::AddItem(ECensorPathMode pathMode, bool include, const UString &path, bool recursive, bool wildcardMatching)
	{
	UStringVector pathParts;
	if (path.IsEmpty())
	throw "Empty file path";
	SplitPathToParts(path, pathParts);
	bool forFile = true;
	if (pathParts.Back().IsEmpty())
	{
	forFile = false;
	pathParts.DeleteBack();
	}

	UString prefix;

	if (pathMode != k_AbsPath)
	{
	const UString &front = pathParts.Front();
	bool isAbs = false;

	if (front.IsEmpty())
	isAbs = true;
	else
	{
	#ifdef _WIN32

	if (IsDriveColonName(front))
	isAbs = true;
	else

	#endif

	FOR_VECTOR (i, pathParts)
	{
	const UString &part = pathParts[i];
	if (part == L".." \|\| part == L".")
	{
	isAbs = true;
	break;
	}
	}
	}

	unsigned numAbsParts = 0;
	if (isAbs)
	if (pathParts.Size() > 1)
	numAbsParts = pathParts.Size() - 1;
	else
	numAbsParts = 1;

	#ifdef _WIN32

	// \\?\ case
	if (numAbsParts >= 3)
	{
	if (pathParts[0].IsEmpty() &&
	pathParts[1].IsEmpty() &&
	pathParts[2] == L"?")
	{
	prefix =
	WSTRING_PATH_SEPARATOR
	WSTRING_PATH_SEPARATOR L"?"
	WSTRING_PATH_SEPARATOR;
	numAbsParts -= 3;
	pathParts.DeleteFrontal(3);
	}
	}

	#endif

	if (numAbsParts > 1 && pathMode == k_FullPath)
	numAbsParts = 1;

	// We can't ignore wildcard, since we don't allow wildcard in SubNodes[].Name
	// if (wildcardMatching)
	for (unsigned i = 0; i < numAbsParts; i++)
	{
	{
	const UString &front = pathParts.Front();
	if (DoesNameContainWildcard(front))
	break;
	prefix += front;
	prefix += WCHAR_PATH_SEPARATOR;
	}
	pathParts.Delete(0);
	}
	}

	int index = FindPrefix(prefix);
	if (index < 0)
	index = Pairs.Add(CPair(prefix));

	CItem item;
	item.PathParts = pathParts;
	item.ForDir = true;
	item.ForFile = forFile;
	item.Recursive = recursive;
	item.WildcardMatching = wildcardMatching;
	Pairs[index].Head.AddItem(include, item);
	}

	bool CCensor::CheckPath(bool isAltStream, const UString &path, bool isFile) const
	{
	bool finded = false;
	FOR_VECTOR (i, Pairs)
	{
	bool include;
	if (Pairs[i].Head.CheckPath2(isAltStream, path, isFile, include))
	{
	if (!include)
	return false;
	finded = true;
	}
	}
	return finded;
	}

	void CCensor::ExtendExclude()
	{
	unsigned i;
	for (i = 0; i < Pairs.Size(); i++)
	if (Pairs[i].Prefix.IsEmpty())
	break;
	if (i == Pairs.Size())
	return;
	unsigned index = i;
	for (i = 0; i < Pairs.Size(); i++)
	if (index != i)
	Pairs[i].Head.ExtendExclude(Pairs[index].Head);
	}

	void CCensor::AddPathsToCensor(ECensorPathMode censorPathMode)
	{
	FOR_VECTOR(i, CensorPaths)
	{
	const CCensorPath &cp = CensorPaths[i];
	AddItem(censorPathMode, cp.Include, cp.Path, cp.Recursive, cp.WildcardMatching);
	}
	CensorPaths.Clear();
	}

	void CCensor::AddPreItem(bool include, const UString &path, bool recursive, bool wildcardMatching)
	{
	CCensorPath &cp = CensorPaths.AddNew();
	cp.Path = path;
	cp.Include = include;
	cp.Recursive = recursive;
	cp.WildcardMatching = wildcardMatching;
	}

	}