SkRTree.h revision e16efc1882ab34a0bb3ae361a2d37f840044cf87
1 2/* 3 * Copyright 2012 Google Inc. 4 * 5 * Use of this source code is governed by a BSD-style license that can be 6 * found in the LICENSE file. 7 */ 8 9#ifndef SkRTree_DEFINED 10#define SkRTree_DEFINED 11 12#include "SkRect.h" 13#include "SkTDArray.h" 14#include "SkChunkAlloc.h" 15#include "SkBBoxHierarchy.h" 16 17/** 18 * An R-Tree implementation. In short, it is a balanced n-ary tree containing a hierarchy of 19 * bounding rectangles. 20 * 21 * Much like a B-Tree it maintains balance by enforcing minimum and maximum child counts, and 22 * splitting nodes when they become overfull. Unlike B-trees, however, we're using spatial data; so 23 * there isn't a canonical ordering to use when choosing insertion locations and splitting 24 * distributions. A variety of heuristics have been proposed for these problems; here, we're using 25 * something resembling an R*-tree, which attempts to minimize area and overlap during insertion, 26 * and aims to minimize a combination of margin, overlap, and area when splitting. 27 * 28 * One detail that is thus far unimplemented that may improve tree quality is attempting to remove 29 * and reinsert nodes when they become full, instead of immediately splitting (nodes that may have 30 * been placed well early on may hurt the tree later when more nodes have been added; removing 31 * and reinserting nodes generally helps reduce overlap and make a better tree). Deletion of nodes 32 * is also unimplemented. 33 * 34 * For more details see: 35 * 36 * Beckmann, N.; Kriegel, H. P.; Schneider, R.; Seeger, B. (1990). "The R*-tree: 37 * an efficient and robust access method for points and rectangles" 38 * 39 * It also supports bulk-loading from a batch of bounds and values; if you don't require the tree 40 * to be usable in its intermediate states while it is being constructed, this is significantly 41 * quicker than individual insertions and produces more consistent trees. 42 */ 43class SkRTree : public SkBBoxHierarchy { 44public: 45 SK_DECLARE_INST_COUNT(SkRTree) 46 47 /** 48 * Create a new R-Tree with specified min/max child counts. 49 * The child counts are valid iff: 50 * - (max + 1) / 2 >= min (splitting an overfull node must be enough to populate 2 nodes) 51 * - min < max 52 * - min > 0 53 * - max < SK_MaxU16 54 * If you have some prior information about the distribution of bounds you're expecting, you 55 * can provide an optional aspect ratio parameter. This allows the bulk-load algorithm to create 56 * better proportioned tiles of rectangles. 57 */ 58 static SkRTree* Create(int minChildren, int maxChildren, SkScalar aspectRatio = 1); 59 virtual ~SkRTree(); 60 61 /** 62 * Insert a node, consisting of bounds and a data value into the tree, if we don't immediately 63 * need to use the tree; we may allow the insert to be deferred (this can allow us to bulk-load 64 * a large batch of nodes at once, which tends to be faster and produce a better tree). 65 * @param data The data value 66 * @param bounds The corresponding bounding box 67 * @param defer Can this insert be deferred? (this may be ignored) 68 */ 69 virtual void insert(void* data, const SkIRect& bounds, bool defer = false); 70 71 /** 72 * If any inserts have been deferred, this will add them into the tree 73 */ 74 virtual void flushDeferredInserts(); 75 76 /** 77 * Given a query rectangle, populates the passed-in array with the elements it intersects 78 */ 79 virtual void search(const SkIRect& query, SkTDArray<void*>* results); 80 81 virtual void clear(); 82 bool isEmpty() const { return 0 == fCount; } 83 int getDepth() const { return this->isEmpty() ? 0 : fRoot.fChild.subtree->fLevel + 1; } 84 85 /** 86 * This gets the insertion count (rather than the node count) 87 */ 88 virtual int getCount() const { return fCount; } 89 90private: 91 92 struct Node; 93 94 /** 95 * A branch of the tree, this may contain a pointer to another interior node, or a data value 96 */ 97 struct Branch { 98 union { 99 Node* subtree; 100 void* data; 101 } fChild; 102 SkIRect fBounds; 103 }; 104 105 /** 106 * A node in the tree, has between fMinChildren and fMaxChildren (the root is a special case) 107 */ 108 struct Node { 109 uint16_t fNumChildren; 110 uint16_t fLevel; 111 bool isLeaf() { return 0 == fLevel; } 112 // Since we want to be able to pick min/max child counts at runtime, we assume the creator 113 // has allocated sufficient space directly after us in memory, and index into that space 114 Branch* child(size_t index) { 115 return reinterpret_cast<Branch*>(this + 1) + index; 116 } 117 }; 118 119 typedef int32_t SkIRect::*SortSide; 120 121 // Helper for sorting our children arrays by sides of their rects 122 static bool RectLessThan(SortSide const& side, const Branch lhs, const Branch rhs) { 123 return lhs.fBounds.*side < rhs.fBounds.*side; 124 } 125 126 static bool RectLessX(int&, const Branch lhs, const Branch rhs) { 127 return ((lhs.fBounds.fRight - lhs.fBounds.fLeft) >> 1) < 128 ((rhs.fBounds.fRight - lhs.fBounds.fLeft) >> 1); 129 } 130 131 static bool RectLessY(int&, const Branch lhs, const Branch rhs) { 132 return ((lhs.fBounds.fBottom - lhs.fBounds.fTop) >> 1) < 133 ((rhs.fBounds.fBottom - lhs.fBounds.fTop) >> 1); 134 } 135 136 SkRTree(int minChildren, int maxChildren, SkScalar aspectRatio); 137 138 /** 139 * Recursively descend the tree to find an insertion position for 'branch', updates 140 * bounding boxes on the way up. 141 */ 142 Branch* insert(Node* root, Branch* branch, uint16_t level = 0); 143 144 int chooseSubtree(Node* root, Branch* branch); 145 SkIRect computeBounds(Node* n); 146 int distributeChildren(Branch* children); 147 void search(Node* root, const SkIRect query, SkTDArray<void*>* results) const; 148 149 /** 150 * This performs a bottom-up bulk load using the STR (sort-tile-recursive) algorithm, this 151 * seems to generally produce better, more consistent trees at significantly lower cost than 152 * repeated insertions. 153 * 154 * This consumes the input array. 155 * 156 * TODO: Experiment with other bulk-load algorithms (in particular the Hilbert pack variant, 157 * which groups rects by position on the Hilbert curve, is probably worth a look). There also 158 * exist top-down bulk load variants (VAMSplit, TopDownGreedy, etc). 159 */ 160 Branch bulkLoad(SkTDArray<Branch>* branches, int level = 0); 161 162 void validate(); 163 int validateSubtree(Node* root, SkIRect bounds, bool isRoot = false); 164 165 const int fMinChildren; 166 const int fMaxChildren; 167 const size_t fNodeSize; 168 169 // This is the count of data elements (rather than total nodes in the tree) 170 size_t fCount; 171 172 Branch fRoot; 173 SkChunkAlloc fNodes; 174 SkTDArray<Branch> fDeferredInserts; 175 SkScalar fAspectRatio; 176 177 Node* allocateNode(uint16_t level); 178 179 typedef SkBBoxHierarchy INHERITED; 180}; 181 182#endif 183