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      1 /*
      2  * Copyright 2012 Google Inc.
      3  *
      4  * Use of this source code is governed by a BSD-style license that can be
      5  * found in the LICENSE file.
      6  */
      7 
      8 #include "SkRTree.h"
      9 #include "SkTSort.h"
     10 
     11 static inline uint32_t get_area(const SkIRect& rect);
     12 static inline uint32_t get_overlap(const SkIRect& rect1, const SkIRect& rect2);
     13 static inline uint32_t get_margin(const SkIRect& rect);
     14 static inline uint32_t get_area_increase(const SkIRect& rect1, SkIRect rect2);
     15 static inline void join_no_empty_check(const SkIRect& joinWith, SkIRect* out);
     16 
     17 ///////////////////////////////////////////////////////////////////////////////////////////////////
     18 
     19 SkRTree* SkRTree::Create(int minChildren, int maxChildren, SkScalar aspectRatio,
     20             bool sortWhenBulkLoading) {
     21     if (minChildren < maxChildren && (maxChildren + 1) / 2 >= minChildren &&
     22         minChildren > 0 && maxChildren < static_cast<int>(SK_MaxU16)) {
     23         return new SkRTree(minChildren, maxChildren, aspectRatio, sortWhenBulkLoading);
     24     }
     25     return NULL;
     26 }
     27 
     28 SkRTree::SkRTree(int minChildren, int maxChildren, SkScalar aspectRatio,
     29         bool sortWhenBulkLoading)
     30     : fMinChildren(minChildren)
     31     , fMaxChildren(maxChildren)
     32     , fNodeSize(sizeof(Node) + sizeof(Branch) * maxChildren)
     33     , fCount(0)
     34     , fNodes(fNodeSize * 256)
     35     , fAspectRatio(aspectRatio)
     36     , fSortWhenBulkLoading(sortWhenBulkLoading) {
     37     SkASSERT(minChildren < maxChildren && minChildren > 0 && maxChildren <
     38              static_cast<int>(SK_MaxU16));
     39     SkASSERT((maxChildren + 1) / 2 >= minChildren);
     40     this->validate();
     41 }
     42 
     43 SkRTree::~SkRTree() {
     44     this->clear();
     45 }
     46 
     47 void SkRTree::insert(void* data, const SkIRect& bounds, bool defer) {
     48     this->validate();
     49     if (bounds.isEmpty()) {
     50         SkASSERT(false);
     51         return;
     52     }
     53     Branch newBranch;
     54     newBranch.fBounds = bounds;
     55     newBranch.fChild.data = data;
     56     if (this->isEmpty()) {
     57         // since a bulk-load into an existing tree is as of yet unimplemented (and arguably not
     58         // of vital importance right now), we only batch up inserts if the tree is empty.
     59         if (defer) {
     60             fDeferredInserts.push(newBranch);
     61             return;
     62         } else {
     63             fRoot.fChild.subtree = allocateNode(0);
     64             fRoot.fChild.subtree->fNumChildren = 0;
     65         }
     66     }
     67 
     68     Branch* newSibling = insert(fRoot.fChild.subtree, &newBranch);
     69     fRoot.fBounds = this->computeBounds(fRoot.fChild.subtree);
     70 
     71     if (NULL != newSibling) {
     72         Node* oldRoot = fRoot.fChild.subtree;
     73         Node* newRoot = this->allocateNode(oldRoot->fLevel + 1);
     74         newRoot->fNumChildren = 2;
     75         *newRoot->child(0) = fRoot;
     76         *newRoot->child(1) = *newSibling;
     77         fRoot.fChild.subtree = newRoot;
     78         fRoot.fBounds = this->computeBounds(fRoot.fChild.subtree);
     79     }
     80 
     81     ++fCount;
     82     this->validate();
     83 }
     84 
     85 void SkRTree::flushDeferredInserts() {
     86     this->validate();
     87     if (this->isEmpty() && fDeferredInserts.count() > 0) {
     88         fCount = fDeferredInserts.count();
     89         if (1 == fCount) {
     90             fRoot.fChild.subtree = allocateNode(0);
     91             fRoot.fChild.subtree->fNumChildren = 0;
     92             this->insert(fRoot.fChild.subtree, &fDeferredInserts[0]);
     93             fRoot.fBounds = fDeferredInserts[0].fBounds;
     94         } else {
     95             fRoot = this->bulkLoad(&fDeferredInserts);
     96         }
     97     } else {
     98         // TODO: some algorithm for bulk loading into an already populated tree
     99         SkASSERT(0 == fDeferredInserts.count());
    100     }
    101     fDeferredInserts.rewind();
    102     this->validate();
    103 }
    104 
    105 void SkRTree::search(const SkIRect& query, SkTDArray<void*>* results) {
    106     this->validate();
    107     if (0 != fDeferredInserts.count()) {
    108         this->flushDeferredInserts();
    109     }
    110     if (!this->isEmpty() && SkIRect::IntersectsNoEmptyCheck(fRoot.fBounds, query)) {
    111         this->search(fRoot.fChild.subtree, query, results);
    112     }
    113     this->validate();
    114 }
    115 
    116 void SkRTree::clear() {
    117     this->validate();
    118     fNodes.reset();
    119     fDeferredInserts.rewind();
    120     fCount = 0;
    121     this->validate();
    122 }
    123 
    124 SkRTree::Node* SkRTree::allocateNode(uint16_t level) {
    125     Node* out = static_cast<Node*>(fNodes.allocThrow(fNodeSize));
    126     out->fNumChildren = 0;
    127     out->fLevel = level;
    128     return out;
    129 }
    130 
    131 SkRTree::Branch* SkRTree::insert(Node* root, Branch* branch, uint16_t level) {
    132     Branch* toInsert = branch;
    133     if (root->fLevel != level) {
    134         int childIndex = this->chooseSubtree(root, branch);
    135         toInsert = this->insert(root->child(childIndex)->fChild.subtree, branch, level);
    136         root->child(childIndex)->fBounds = this->computeBounds(
    137             root->child(childIndex)->fChild.subtree);
    138     }
    139     if (NULL != toInsert) {
    140         if (root->fNumChildren == fMaxChildren) {
    141             // handle overflow by splitting. TODO: opportunistic reinsertion
    142 
    143             // decide on a distribution to divide with
    144             Node* newSibling = this->allocateNode(root->fLevel);
    145             Branch* toDivide = SkNEW_ARRAY(Branch, fMaxChildren + 1);
    146             for (int i = 0; i < fMaxChildren; ++i) {
    147                 toDivide[i] = *root->child(i);
    148             }
    149             toDivide[fMaxChildren] = *toInsert;
    150             int splitIndex = this->distributeChildren(toDivide);
    151 
    152             // divide up the branches
    153             root->fNumChildren = splitIndex;
    154             newSibling->fNumChildren = fMaxChildren + 1 - splitIndex;
    155             for (int i = 0; i < splitIndex; ++i) {
    156                 *root->child(i) = toDivide[i];
    157             }
    158             for (int i = splitIndex; i < fMaxChildren + 1; ++i) {
    159                 *newSibling->child(i - splitIndex) = toDivide[i];
    160             }
    161             SkDELETE_ARRAY(toDivide);
    162 
    163             // pass the new sibling branch up to the parent
    164             branch->fChild.subtree = newSibling;
    165             branch->fBounds = this->computeBounds(newSibling);
    166             return branch;
    167         } else {
    168             *root->child(root->fNumChildren) = *toInsert;
    169             ++root->fNumChildren;
    170             return NULL;
    171         }
    172     }
    173     return NULL;
    174 }
    175 
    176 int SkRTree::chooseSubtree(Node* root, Branch* branch) {
    177     SkASSERT(!root->isLeaf());
    178     if (1 < root->fLevel) {
    179         // root's child pointers do not point to leaves, so minimize area increase
    180         int32_t minAreaIncrease = SK_MaxS32;
    181         int32_t minArea         = SK_MaxS32;
    182         int32_t bestSubtree     = -1;
    183         for (int i = 0; i < root->fNumChildren; ++i) {
    184             const SkIRect& subtreeBounds = root->child(i)->fBounds;
    185             int32_t areaIncrease = get_area_increase(subtreeBounds, branch->fBounds);
    186             // break ties in favor of subtree with smallest area
    187             if (areaIncrease < minAreaIncrease || (areaIncrease == minAreaIncrease &&
    188                 static_cast<int32_t>(get_area(subtreeBounds)) < minArea)) {
    189                 minAreaIncrease = areaIncrease;
    190                 minArea = get_area(subtreeBounds);
    191                 bestSubtree = i;
    192             }
    193         }
    194         SkASSERT(-1 != bestSubtree);
    195         return bestSubtree;
    196     } else if (1 == root->fLevel) {
    197         // root's child pointers do point to leaves, so minimize overlap increase
    198         int32_t minOverlapIncrease = SK_MaxS32;
    199         int32_t minAreaIncrease    = SK_MaxS32;
    200         int32_t bestSubtree = -1;
    201         for (int32_t i = 0; i < root->fNumChildren; ++i) {
    202             const SkIRect& subtreeBounds = root->child(i)->fBounds;
    203             SkIRect expandedBounds = subtreeBounds;
    204             join_no_empty_check(branch->fBounds, &expandedBounds);
    205             int32_t overlap = 0;
    206             for (int32_t j = 0; j < root->fNumChildren; ++j) {
    207                 if (j == i) continue;
    208                 // Note: this would be more correct if we subtracted the original pre-expanded
    209                 // overlap, but computing overlaps is expensive and omitting it doesn't seem to
    210                 // hurt query performance. See get_overlap_increase()
    211                 overlap += get_overlap(expandedBounds, root->child(j)->fBounds);
    212             }
    213             // break ties with lowest area increase
    214             if (overlap < minOverlapIncrease || (overlap == minOverlapIncrease &&
    215                 static_cast<int32_t>(get_area_increase(branch->fBounds, subtreeBounds)) <
    216                 minAreaIncrease)) {
    217                 minOverlapIncrease = overlap;
    218                 minAreaIncrease = get_area_increase(branch->fBounds, subtreeBounds);
    219                 bestSubtree = i;
    220             }
    221         }
    222         return bestSubtree;
    223     } else {
    224         SkASSERT(false);
    225         return 0;
    226     }
    227 }
    228 
    229 SkIRect SkRTree::computeBounds(Node* n) {
    230     SkIRect r = n->child(0)->fBounds;
    231     for (int i = 1; i < n->fNumChildren; ++i) {
    232         join_no_empty_check(n->child(i)->fBounds, &r);
    233     }
    234     return r;
    235 }
    236 
    237 int SkRTree::distributeChildren(Branch* children) {
    238     // We have two sides to sort by on each of two axes:
    239     const static SortSide sorts[2][2] = {
    240         {&SkIRect::fLeft, &SkIRect::fRight},
    241         {&SkIRect::fTop, &SkIRect::fBottom}
    242     };
    243 
    244     // We want to choose an axis to split on, then a distribution along that axis; we'll need
    245     // three pieces of info: the split axis, the side to sort by on that axis, and the index
    246     // to split the sorted array on.
    247     int32_t sortSide = -1;
    248     int32_t k        = -1;
    249     int32_t axis     = -1;
    250     int32_t bestS    = SK_MaxS32;
    251 
    252     // Evaluate each axis, we want the min summed margin-value (s) over all distributions
    253     for (int i = 0; i < 2; ++i) {
    254         int32_t minOverlap   = SK_MaxS32;
    255         int32_t minArea      = SK_MaxS32;
    256         int32_t axisBestK    = 0;
    257         int32_t axisBestSide = 0;
    258         int32_t s = 0;
    259 
    260         // Evaluate each sort
    261         for (int j = 0; j < 2; ++j) {
    262             SkTQSort(children, children + fMaxChildren, RectLessThan(sorts[i][j]));
    263 
    264             // Evaluate each split index
    265             for (int32_t k = 1; k <= fMaxChildren - 2 * fMinChildren + 2; ++k) {
    266                 SkIRect r1 = children[0].fBounds;
    267                 SkIRect r2 = children[fMinChildren + k - 1].fBounds;
    268                 for (int32_t l = 1; l < fMinChildren - 1 + k; ++l) {
    269                     join_no_empty_check(children[l].fBounds, &r1);
    270                 }
    271                 for (int32_t l = fMinChildren + k; l < fMaxChildren + 1; ++l) {
    272                     join_no_empty_check(children[l].fBounds, &r2);
    273                 }
    274 
    275                 int32_t area = get_area(r1) + get_area(r2);
    276                 int32_t overlap = get_overlap(r1, r2);
    277                 s += get_margin(r1) + get_margin(r2);
    278 
    279                 if (overlap < minOverlap || (overlap == minOverlap && area < minArea)) {
    280                     minOverlap = overlap;
    281                     minArea = area;
    282                     axisBestSide = j;
    283                     axisBestK = k;
    284                 }
    285             }
    286         }
    287 
    288         if (s < bestS) {
    289             bestS = s;
    290             axis = i;
    291             sortSide = axisBestSide;
    292             k = axisBestK;
    293         }
    294     }
    295 
    296     // replicate the sort of the winning distribution, (we can skip this if the last
    297     // sort ended up being best)
    298     if (!(axis == 1 && sortSide == 1)) {
    299         SkTQSort(children, children + fMaxChildren, RectLessThan(sorts[axis][sortSide]));
    300     }
    301 
    302     return fMinChildren - 1 + k;
    303 }
    304 
    305 void SkRTree::search(Node* root, const SkIRect query, SkTDArray<void*>* results) const {
    306     for (int i = 0; i < root->fNumChildren; ++i) {
    307         if (SkIRect::IntersectsNoEmptyCheck(root->child(i)->fBounds, query)) {
    308             if (root->isLeaf()) {
    309                 results->push(root->child(i)->fChild.data);
    310             } else {
    311                 this->search(root->child(i)->fChild.subtree, query, results);
    312             }
    313         }
    314     }
    315 }
    316 
    317 SkRTree::Branch SkRTree::bulkLoad(SkTDArray<Branch>* branches, int level) {
    318     if (branches->count() == 1) {
    319         // Only one branch: it will be the root
    320         Branch out = (*branches)[0];
    321         branches->rewind();
    322         return out;
    323     } else {
    324         // We sort the whole list by y coordinates, if we are told to do so.
    325         //
    326         // We expect Webkit / Blink to give us a reasonable x,y order.
    327         // Avoiding this call resulted in a 17% win for recording with
    328         // negligible difference in playback speed.
    329         if (fSortWhenBulkLoading) {
    330             SkTQSort(branches->begin(), branches->end() - 1, RectLessY());
    331         }
    332 
    333         int numBranches = branches->count() / fMaxChildren;
    334         int remainder = branches->count() % fMaxChildren;
    335         int newBranches = 0;
    336 
    337         if (0 != remainder) {
    338             ++numBranches;
    339             // If the remainder isn't enough to fill a node, we'll need to add fewer nodes to
    340             // some other branches to make up for it
    341             if (remainder >= fMinChildren) {
    342                 remainder = 0;
    343             } else {
    344                 remainder = fMinChildren - remainder;
    345             }
    346         }
    347 
    348         int numStrips = SkScalarCeil(SkScalarSqrt(SkIntToScalar(numBranches) *
    349                                      SkScalarInvert(fAspectRatio)));
    350         int numTiles = SkScalarCeil(SkIntToScalar(numBranches) /
    351                                     SkIntToScalar(numStrips));
    352         int currentBranch = 0;
    353 
    354         for (int i = 0; i < numStrips; ++i) {
    355             // Once again, if we are told to do so, we sort by x.
    356             if (fSortWhenBulkLoading) {
    357                 int begin = currentBranch;
    358                 int end = currentBranch + numTiles * fMaxChildren - SkMin32(remainder,
    359                         (fMaxChildren - fMinChildren) * numTiles);
    360                 if (end > branches->count()) {
    361                     end = branches->count();
    362                 }
    363 
    364                 // Now we sort horizontal strips of rectangles by their x coords
    365                 SkTQSort(branches->begin() + begin, branches->begin() + end - 1, RectLessX());
    366             }
    367 
    368             for (int j = 0; j < numTiles && currentBranch < branches->count(); ++j) {
    369                 int incrementBy = fMaxChildren;
    370                 if (remainder != 0) {
    371                     // if need be, omit some nodes to make up for remainder
    372                     if (remainder <= fMaxChildren - fMinChildren) {
    373                         incrementBy -= remainder;
    374                         remainder = 0;
    375                     } else {
    376                         incrementBy = fMinChildren;
    377                         remainder -= fMaxChildren - fMinChildren;
    378                     }
    379                 }
    380                 Node* n = allocateNode(level);
    381                 n->fNumChildren = 1;
    382                 *n->child(0) = (*branches)[currentBranch];
    383                 Branch b;
    384                 b.fBounds = (*branches)[currentBranch].fBounds;
    385                 b.fChild.subtree = n;
    386                 ++currentBranch;
    387                 for (int k = 1; k < incrementBy && currentBranch < branches->count(); ++k) {
    388                     b.fBounds.join((*branches)[currentBranch].fBounds);
    389                     *n->child(k) = (*branches)[currentBranch];
    390                     ++n->fNumChildren;
    391                     ++currentBranch;
    392                 }
    393                 (*branches)[newBranches] = b;
    394                 ++newBranches;
    395             }
    396         }
    397         branches->setCount(newBranches);
    398         return this->bulkLoad(branches, level + 1);
    399     }
    400 }
    401 
    402 void SkRTree::validate() {
    403 #ifdef SK_DEBUG
    404     if (this->isEmpty()) {
    405         return;
    406     }
    407     SkASSERT(fCount == this->validateSubtree(fRoot.fChild.subtree, fRoot.fBounds, true));
    408 #endif
    409 }
    410 
    411 int SkRTree::validateSubtree(Node* root, SkIRect bounds, bool isRoot) {
    412     // make sure the pointer is pointing to a valid place
    413     SkASSERT(fNodes.contains(static_cast<void*>(root)));
    414 
    415     if (isRoot) {
    416         // If the root of this subtree is the overall root, we have looser standards:
    417         if (root->isLeaf()) {
    418             SkASSERT(root->fNumChildren >= 1 && root->fNumChildren <= fMaxChildren);
    419         } else {
    420             SkASSERT(root->fNumChildren >= 2 && root->fNumChildren <= fMaxChildren);
    421         }
    422     } else {
    423         SkASSERT(root->fNumChildren >= fMinChildren && root->fNumChildren <= fMaxChildren);
    424     }
    425 
    426     for (int i = 0; i < root->fNumChildren; ++i) {
    427         SkASSERT(bounds.contains(root->child(i)->fBounds));
    428     }
    429 
    430     if (root->isLeaf()) {
    431         SkASSERT(0 == root->fLevel);
    432         return root->fNumChildren;
    433     } else {
    434         int childCount = 0;
    435         for (int i = 0; i < root->fNumChildren; ++i) {
    436             SkASSERT(root->child(i)->fChild.subtree->fLevel == root->fLevel - 1);
    437             childCount += this->validateSubtree(root->child(i)->fChild.subtree,
    438                                                 root->child(i)->fBounds);
    439         }
    440         return childCount;
    441     }
    442 }
    443 
    444 void SkRTree::rewindInserts() {
    445     SkASSERT(this->isEmpty()); // Currently only supports deferred inserts
    446     while (!fDeferredInserts.isEmpty() &&
    447            fClient->shouldRewind(fDeferredInserts.top().fChild.data)) {
    448         fDeferredInserts.pop();
    449     }
    450 }
    451 
    452 ///////////////////////////////////////////////////////////////////////////////////////////////////
    453 
    454 static inline uint32_t get_area(const SkIRect& rect) {
    455     return rect.width() * rect.height();
    456 }
    457 
    458 static inline uint32_t get_overlap(const SkIRect& rect1, const SkIRect& rect2) {
    459     // I suspect there's a more efficient way of computing this...
    460     return SkMax32(0, SkMin32(rect1.fRight, rect2.fRight) - SkMax32(rect1.fLeft, rect2.fLeft)) *
    461            SkMax32(0, SkMin32(rect1.fBottom, rect2.fBottom) - SkMax32(rect1.fTop, rect2.fTop));
    462 }
    463 
    464 // Get the margin (aka perimeter)
    465 static inline uint32_t get_margin(const SkIRect& rect) {
    466     return 2 * (rect.width() + rect.height());
    467 }
    468 
    469 static inline uint32_t get_area_increase(const SkIRect& rect1, SkIRect rect2) {
    470     join_no_empty_check(rect1, &rect2);
    471     return get_area(rect2) - get_area(rect1);
    472 }
    473 
    474 // Expand 'out' to include 'joinWith'
    475 static inline void join_no_empty_check(const SkIRect& joinWith, SkIRect* out) {
    476     // since we check for empty bounds on insert, we know we'll never have empty rects
    477     // and we can save the empty check that SkIRect::join requires
    478     if (joinWith.fLeft < out->fLeft) { out->fLeft = joinWith.fLeft; }
    479     if (joinWith.fTop < out->fTop) { out->fTop = joinWith.fTop; }
    480     if (joinWith.fRight > out->fRight) { out->fRight = joinWith.fRight; }
    481     if (joinWith.fBottom > out->fBottom) { out->fBottom = joinWith.fBottom; }
    482 }
    483