cc/base/rtree.h - chromium/src - Git at Google

 // Copyright (c) 2015 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef CC_BASE_RTREE_H_
 #define CC_BASE_RTREE_H_

 #include <stddef.h>
 #include <stdint.h>

 #include <deque>
 #include <vector>

 #include "cc/base/cc_export.h"
 #include "ui/gfx/geometry/rect.h"

 namespace cc {

 // The following description and most of the implementation is borrowed from
 // Skia's SkRTree implementation.
 //
 // An R-Tree implementation. In short, it is a balanced n-ary tree containing a
 // hierarchy of bounding rectangles.
 //
 // It only supports bulk-loading, i.e. creation from a batch of bounding
 // rectangles. This performs a bottom-up bulk load using the STR
 // (sort-tile-recursive) algorithm.
 //
 // Things to do: Experiment with other bulk-load algorithms (in particular the
 // Hilbert pack variant, which groups rects by position on the Hilbert curve, is
 // probably worth a look). There also exist top-down bulk load variants
 // (VAMSplit, TopDownGreedy, etc).
 //
 // For more details see:
 //
 //  Beckmann, N.; Kriegel, H. P.; Schneider, R.; Seeger, B. (1990).
 //  "The R*-tree: an efficient and robust access method for points and
 //  rectangles"
 class CC_EXPORT RTree {
  public:
   RTree();
   ~RTree();

   template <typename Container, typename Functor>
   void Build(const Container& items, const Functor& bounds_getter) {
     DCHECK_EQ(0u, num_data_elements_);

     std::vector<Branch> branches;
     branches.reserve(items.size());

     for (size_t i = 0; i < items.size(); i++) {
       const gfx::Rect& bounds = bounds_getter(items[i]);
       if (bounds.IsEmpty())
         continue;

       branches.push_back(Branch());
       Branch& branch = branches.back();
       branch.bounds = bounds;
       branch.index = i;
     }

     num_data_elements_ = branches.size();
     if (num_data_elements_ == 1u) {
       Node* node = AllocateNodeAtLevel(0);
       node->num_children = 1;
       node->children[0] = branches[0];
       root_.subtree = node;
       root_.bounds = branches[0].bounds;
     } else if (num_data_elements_ > 1u) {
       root_ = BuildRecursive(&branches, 0);
     }
   }

   template <typename Container>
   void Build(const Container& items) {
     Build(items, [](const gfx::Rect& bounds) { return bounds; });
   }

   void Search(const gfx::Rect& query, std::vector<size_t>* results) const;

   gfx::Rect GetBounds() const;

  private:
   // These values were empirically determined to produce reasonable performance
   // in most cases.
   enum { MIN_CHILDREN = 6, MAX_CHILDREN = 11 };

   struct Node;
   struct Branch {
     // When the node level is 0, then the node is a leaf and the branch has a
     // valid index pointing to an element in the vector that was used to build
     // this rtree. When the level is not 0, it's an internal node and it has a
     // valid subtree pointer.
     union {
       Node* subtree;
       size_t index;
     };
     gfx::Rect bounds;
   };

   struct Node {
     uint16_t num_children;
     uint16_t level;
     Branch children[MAX_CHILDREN];
   };

   void SearchRecursive(Node* root,
                        const gfx::Rect& query,
                        std::vector<size_t>* results) const;

   // Consumes the input array.
   Branch BuildRecursive(std::vector<Branch>* branches, int level);
   Node* AllocateNodeAtLevel(int level);

   // This is the count of data elements (rather than total nodes in the tree)
   size_t num_data_elements_;
   Branch root_;
   std::deque<Node> nodes_;
 };

 }  // namespace cc

 #endif  // CC_BASE_RTREE_H_
	// Copyright (c) 2015 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef CC_BASE_RTREE_H_
	#define CC_BASE_RTREE_H_

	#include <stddef.h>
	#include <stdint.h>

	#include <deque>
	#include <vector>

	#include "cc/base/cc_export.h"
	#include "ui/gfx/geometry/rect.h"

	namespace cc {

	// The following description and most of the implementation is borrowed from
	// Skia's SkRTree implementation.
	//
	// An R-Tree implementation. In short, it is a balanced n-ary tree containing a
	// hierarchy of bounding rectangles.
	//
	// It only supports bulk-loading, i.e. creation from a batch of bounding
	// rectangles. This performs a bottom-up bulk load using the STR
	// (sort-tile-recursive) algorithm.
	//
	// Things to do: Experiment with other bulk-load algorithms (in particular the
	// Hilbert pack variant, which groups rects by position on the Hilbert curve, is
	// probably worth a look). There also exist top-down bulk load variants
	// (VAMSplit, TopDownGreedy, etc).
	//
	// For more details see:
	//
	// Beckmann, N.; Kriegel, H. P.; Schneider, R.; Seeger, B. (1990).
	// "The R*-tree: an efficient and robust access method for points and
	// rectangles"
	class CC_EXPORT RTree {
	public:
	RTree();
	~RTree();

	template <typename Container, typename Functor>
	void Build(const Container& items, const Functor& bounds_getter) {
	DCHECK_EQ(0u, num_data_elements_);

	std::vector<Branch> branches;
	branches.reserve(items.size());

	for (size_t i = 0; i < items.size(); i++) {
	const gfx::Rect& bounds = bounds_getter(items[i]);
	if (bounds.IsEmpty())
	continue;

	branches.push_back(Branch());
	Branch& branch = branches.back();
	branch.bounds = bounds;
	branch.index = i;
	}

	num_data_elements_ = branches.size();
	if (num_data_elements_ == 1u) {
	Node* node = AllocateNodeAtLevel(0);
	node->num_children = 1;
	node->children[0] = branches[0];
	root_.subtree = node;
	root_.bounds = branches[0].bounds;
	} else if (num_data_elements_ > 1u) {
	root_ = BuildRecursive(&branches, 0);
	}
	}

	template <typename Container>
	void Build(const Container& items) {
	Build(items, [](const gfx::Rect& bounds) { return bounds; });
	}

	void Search(const gfx::Rect& query, std::vector<size_t>* results) const;

	gfx::Rect GetBounds() const;

	private:
	// These values were empirically determined to produce reasonable performance
	// in most cases.
	enum { MIN_CHILDREN = 6, MAX_CHILDREN = 11 };

	struct Node;
	struct Branch {
	// When the node level is 0, then the node is a leaf and the branch has a
	// valid index pointing to an element in the vector that was used to build
	// this rtree. When the level is not 0, it's an internal node and it has a
	// valid subtree pointer.
	union {
	Node* subtree;
	size_t index;
	};
	gfx::Rect bounds;
	};

	struct Node {
	uint16_t num_children;
	uint16_t level;
	Branch children[MAX_CHILDREN];
	};

	void SearchRecursive(Node* root,
	const gfx::Rect& query,
	std::vector<size_t>* results) const;

	// Consumes the input array.
	Branch BuildRecursive(std::vector<Branch>* branches, int level);
	Node* AllocateNodeAtLevel(int level);

	// This is the count of data elements (rather than total nodes in the tree)
	size_t num_data_elements_;
	Branch root_;
	std::deque<Node> nodes_;
	};

	} // namespace cc

	#endif // CC_BASE_RTREE_H_