Source/cmLinkedTree.h - 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.  */
 #ifndef cmLinkedTree_h
 #define cmLinkedTree_h

 #include "cmConfigure.h" // IWYU pragma: keep

 #include <assert.h>
 #include <iterator>
 #include <vector>

 /**
   @brief A adaptor for traversing a tree structure in a vector

   This class is not intended to be wholly generic like a standard library
   container adaptor.  Mostly it exists to facilitate code sharing for the
   needs of the cmState.  For example, the Truncate() method is a specific
   requirement of the cmState.

   An empty cmLinkedTree provides a Root() method, and an Push() method,
   each of which return iterators.  A Tree can be built up by extending
   from the root, and then extending from any other iterator.

   An iterator resulting from this tree construction can be
   forward-only-iterated toward the root.  Extending the tree never
   invalidates existing iterators.
  */
 template <typename T>
 class cmLinkedTree
 {
   typedef typename std::vector<T>::size_type PositionType;
   typedef T* PointerType;
   typedef T& ReferenceType;

 public:
   class iterator : public std::iterator<std::forward_iterator_tag, T>
   {
     friend class cmLinkedTree;
     cmLinkedTree* Tree;

     // The Position is always 'one past the end'.
     PositionType Position;

     iterator(cmLinkedTree* tree, PositionType pos)
       : Tree(tree)
       , Position(pos)
     {
     }

   public:
     iterator()
       : Tree(nullptr)
       , Position(0)
     {
     }

     void operator++()
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       assert(this->Position <= this->Tree->Data.size());
       assert(this->Position > 0);
       this->Position = this->Tree->UpPositions[this->Position - 1];
     }

     PointerType operator->() const
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       assert(this->Position <= this->Tree->Data.size());
       assert(this->Position > 0);
       return this->Tree->GetPointer(this->Position - 1);
     }

     PointerType operator->()
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       assert(this->Position <= this->Tree->Data.size());
       assert(this->Position > 0);
       return this->Tree->GetPointer(this->Position - 1);
     }

     ReferenceType operator*() const
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       assert(this->Position <= this->Tree->Data.size());
       assert(this->Position > 0);
       return this->Tree->GetReference(this->Position - 1);
     }

     ReferenceType operator*()
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       assert(this->Position <= this->Tree->Data.size());
       assert(this->Position > 0);
       return this->Tree->GetReference(this->Position - 1);
     }

     bool operator==(iterator other) const
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       assert(this->Tree == other.Tree);
       return this->Position == other.Position;
     }

     bool operator!=(iterator other) const
     {
       assert(this->Tree);
       assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
       return !(*this == other);
     }

     bool IsValid() const
     {
       if (!this->Tree) {
         return false;
       }
       return this->Position <= this->Tree->Data.size();
     }

     bool StrictWeakOrdered(iterator other) const
     {
       assert(this->Tree);
       assert(this->Tree == other.Tree);
       return this->Position < other.Position;
     }
   };

   iterator Root() const
   {
     return iterator(const_cast<cmLinkedTree*>(this), 0);
   }

   iterator Push(iterator it) { return Push_impl(it, T()); }

   iterator Push(iterator it, T t) { return Push_impl(it, std::move(t)); }

   bool IsLast(iterator it) { return it.Position == this->Data.size(); }

   iterator Pop(iterator it)
   {
     assert(!this->Data.empty());
     assert(this->UpPositions.size() == this->Data.size());
     bool const isLast = this->IsLast(it);
     ++it;
     // If this is the last entry then no other entry can refer
     // to it so we can drop its storage.
     if (isLast) {
       this->Data.pop_back();
       this->UpPositions.pop_back();
     }
     return it;
   }

   iterator Truncate()
   {
     assert(!this->UpPositions.empty());
     this->UpPositions.erase(this->UpPositions.begin() + 1,
                             this->UpPositions.end());
     assert(!this->Data.empty());
     this->Data.erase(this->Data.begin() + 1, this->Data.end());
     return iterator(this, 1);
   }

   void Clear()
   {
     this->UpPositions.clear();
     this->Data.clear();
   }

 private:
   T& GetReference(PositionType pos) { return this->Data[pos]; }

   T* GetPointer(PositionType pos) { return &this->Data[pos]; }

   iterator Push_impl(iterator it, T&& t)
   {
     assert(this->UpPositions.size() == this->Data.size());
     assert(it.Position <= this->UpPositions.size());
     this->UpPositions.push_back(it.Position);
     this->Data.push_back(std::move(t));
     return iterator(this, this->UpPositions.size());
   }

   std::vector<T> Data;
   std::vector<PositionType> UpPositions;
 };

 #endif
	/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
	file Copyright.txt or https://cmake.org/licensing for details. */
	#ifndef cmLinkedTree_h
	#define cmLinkedTree_h

	#include "cmConfigure.h" // IWYU pragma: keep

	#include <assert.h>
	#include <iterator>
	#include <vector>

	/**
	@brief A adaptor for traversing a tree structure in a vector

	This class is not intended to be wholly generic like a standard library
	container adaptor. Mostly it exists to facilitate code sharing for the
	needs of the cmState. For example, the Truncate() method is a specific
	requirement of the cmState.

	An empty cmLinkedTree provides a Root() method, and an Push() method,
	each of which return iterators. A Tree can be built up by extending
	from the root, and then extending from any other iterator.

	An iterator resulting from this tree construction can be
	forward-only-iterated toward the root. Extending the tree never
	invalidates existing iterators.
	*/
	template <typename T>
	class cmLinkedTree
	{
	typedef typename std::vector<T>::size_type PositionType;
	typedef T* PointerType;
	typedef T& ReferenceType;

	public:
	class iterator : public std::iterator<std::forward_iterator_tag, T>
	{
	friend class cmLinkedTree;
	cmLinkedTree* Tree;

	// The Position is always 'one past the end'.
	PositionType Position;

	iterator(cmLinkedTree* tree, PositionType pos)
	: Tree(tree)
	, Position(pos)
	{
	}

	public:
	iterator()
	: Tree(nullptr)
	, Position(0)
	{
	}

	void operator++()
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	assert(this->Position <= this->Tree->Data.size());
	assert(this->Position > 0);
	this->Position = this->Tree->UpPositions[this->Position - 1];
	}

	PointerType operator->() const
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	assert(this->Position <= this->Tree->Data.size());
	assert(this->Position > 0);
	return this->Tree->GetPointer(this->Position - 1);
	}

	PointerType operator->()
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	assert(this->Position <= this->Tree->Data.size());
	assert(this->Position > 0);
	return this->Tree->GetPointer(this->Position - 1);
	}

	ReferenceType operator*() const
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	assert(this->Position <= this->Tree->Data.size());
	assert(this->Position > 0);
	return this->Tree->GetReference(this->Position - 1);
	}

	ReferenceType operator*()
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	assert(this->Position <= this->Tree->Data.size());
	assert(this->Position > 0);
	return this->Tree->GetReference(this->Position - 1);
	}

	bool operator==(iterator other) const
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	assert(this->Tree == other.Tree);
	return this->Position == other.Position;
	}

	bool operator!=(iterator other) const
	{
	assert(this->Tree);
	assert(this->Tree->UpPositions.size() == this->Tree->Data.size());
	return !(*this == other);
	}

	bool IsValid() const
	{
	if (!this->Tree) {
	return false;
	}
	return this->Position <= this->Tree->Data.size();
	}

	bool StrictWeakOrdered(iterator other) const
	{
	assert(this->Tree);
	assert(this->Tree == other.Tree);
	return this->Position < other.Position;
	}
	};

	iterator Root() const
	{
	return iterator(const_cast<cmLinkedTree*>(this), 0);
	}

	iterator Push(iterator it) { return Push_impl(it, T()); }

	iterator Push(iterator it, T t) { return Push_impl(it, std::move(t)); }

	bool IsLast(iterator it) { return it.Position == this->Data.size(); }

	iterator Pop(iterator it)
	{
	assert(!this->Data.empty());
	assert(this->UpPositions.size() == this->Data.size());
	bool const isLast = this->IsLast(it);
	++it;
	// If this is the last entry then no other entry can refer
	// to it so we can drop its storage.
	if (isLast) {
	this->Data.pop_back();
	this->UpPositions.pop_back();
	}
	return it;
	}

	iterator Truncate()
	{
	assert(!this->UpPositions.empty());
	this->UpPositions.erase(this->UpPositions.begin() + 1,
	this->UpPositions.end());
	assert(!this->Data.empty());
	this->Data.erase(this->Data.begin() + 1, this->Data.end());
	return iterator(this, 1);
	}

	void Clear()
	{
	this->UpPositions.clear();
	this->Data.clear();
	}

	private:
	T& GetReference(PositionType pos) { return this->Data[pos]; }

	T* GetPointer(PositionType pos) { return &this->Data[pos]; }

	iterator Push_impl(iterator it, T&& t)
	{
	assert(this->UpPositions.size() == this->Data.size());
	assert(it.Position <= this->UpPositions.size());
	this->UpPositions.push_back(it.Position);
	this->Data.push_back(std::move(t));
	return iterator(this, this->UpPositions.size());
	}

	std::vector<T> Data;
	std::vector<PositionType> UpPositions;
	};

	#endif