#include "DataTree.h" #include "../datanodestore/DataNodeStore.h" #include "../datanodestore/DataInnerNode.h" #include "../datanodestore/DataLeafNode.h" #include "../utils/Math.h" #include "impl/algorithms.h" #include "messmer/cpp-utils/pointer.h" #include "messmer/cpp-utils/optional_ownership_ptr.h" #include using blockstore::Key; using blobstore::onblocks::datanodestore::DataNodeStore; using blobstore::onblocks::datanodestore::DataNode; using blobstore::onblocks::datanodestore::DataInnerNode; using blobstore::onblocks::datanodestore::DataLeafNode; using blobstore::onblocks::datanodestore::DataNodeLayout; using std::unique_ptr; using std::dynamic_pointer_cast; using std::function; using cpputils::dynamic_pointer_move; using cpputils::optional_ownership_ptr; using cpputils::WithOwnership; using cpputils::WithoutOwnership; namespace blobstore { namespace onblocks { namespace datatreestore { DataTree::DataTree(DataNodeStore *nodeStore, unique_ptr rootNode) : _nodeStore(nodeStore), _rootNode(std::move(rootNode)) { } DataTree::~DataTree() { } void DataTree::removeLastDataLeaf() { auto deletePosOrNull = algorithms::GetLowestRightBorderNodeWithMoreThanOneChildOrNull(_nodeStore, _rootNode.get()); assert(deletePosOrNull.get() != nullptr); //TODO Correct exception (tree has only one leaf, can't shrink it) deleteLastChildSubtree(deletePosOrNull.get()); ifRootHasOnlyOneChildReplaceRootWithItsChild(); } void DataTree::ifRootHasOnlyOneChildReplaceRootWithItsChild() { DataInnerNode *rootNode = dynamic_cast(_rootNode.get()); assert(rootNode != nullptr); if (rootNode->numChildren() == 1) { auto child = _nodeStore->load(rootNode->getChild(0)->key()); _rootNode = _nodeStore->overwriteNodeWith(std::move(_rootNode), *child); _nodeStore->remove(std::move(child)); } } void DataTree::deleteLastChildSubtree(DataInnerNode *node) { auto lastChild = _nodeStore->load(node->LastChild()->key()); _nodeStore->removeSubtree(std::move(lastChild)); node->removeLastChild(); } unique_ptr DataTree::addDataLeaf() { auto insertPosOrNull = algorithms::GetLowestInnerRightBorderNodeWithLessThanKChildrenOrNull(_nodeStore, _rootNode.get()); if (insertPosOrNull) { return addDataLeafAt(insertPosOrNull.get()); } else { return addDataLeafToFullTree(); } } unique_ptr DataTree::addDataLeafAt(DataInnerNode *insertPos) { auto new_leaf = _nodeStore->createNewLeafNode(); auto chain = createChainOfInnerNodes(insertPos->depth()-1, new_leaf.get()); insertPos->addChild(*chain); return new_leaf; } optional_ownership_ptr DataTree::createChainOfInnerNodes(unsigned int num, DataLeafNode *leaf) { optional_ownership_ptr chain = cpputils::WithoutOwnership(leaf); for(unsigned int i=0; icreateNewInnerNode(*chain); chain = cpputils::WithOwnership(std::move(newnode)); } return chain; } unique_ptr DataTree::addDataLeafToFullTree() { auto copyOfOldRoot = _nodeStore->createNewNodeAsCopyFrom(*_rootNode); auto newRootNode = DataNode::convertToNewInnerNode(std::move(_rootNode), *copyOfOldRoot); auto newLeaf = addDataLeafAt(newRootNode.get()); _rootNode = std::move(newRootNode); return newLeaf; } const Key &DataTree::key() const { return _rootNode->key(); } void DataTree::flush() const { _rootNode->flush(); } unique_ptr DataTree::releaseRootNode() { return std::move(_rootNode); } void DataTree::traverseLeaves(uint32_t beginIndex, uint32_t endIndex, function func) { const_cast(this)->traverseLeaves(beginIndex, endIndex, [func](const DataLeafNode* leaf, uint32_t leafIndex) { func(const_cast(leaf), leafIndex); }); flush(); } void DataTree::traverseLeaves(uint32_t beginIndex, uint32_t endIndex, function func) const { assert(beginIndex <= endIndex); //TODO assert(beginIndex <= numLeaves()); //TODO assert(endIndex <= numLeaves()); traverseLeaves(_rootNode.get(), 0, beginIndex, endIndex, func); } void DataTree::traverseLeaves(const DataNode *root, uint32_t leafOffset, uint32_t beginIndex, uint32_t endIndex, function func) const { const DataLeafNode *leaf = dynamic_cast(root); if (leaf != nullptr) { assert(beginIndex <= 1 && endIndex <= 1); if (beginIndex == 0 && endIndex == 1) { func(leaf, leafOffset); } return; } const DataInnerNode *inner = dynamic_cast(root); uint32_t leavesPerChild = leavesPerFullChild(*inner); uint32_t beginChild = beginIndex/leavesPerChild; uint32_t endChild = utils::ceilDivision(endIndex, leavesPerChild); for (uint32_t childIndex = beginChild; childIndex < endChild; ++childIndex) { uint32_t childOffset = childIndex * leavesPerChild; uint32_t localBeginIndex = utils::maxZeroSubtraction(beginIndex, childOffset); uint32_t localEndIndex = std::min(leavesPerChild, endIndex - childOffset); auto child = _nodeStore->load(inner->getChild(childIndex)->key()); traverseLeaves(child.get(), leafOffset + childOffset, localBeginIndex, localEndIndex, func); } } uint32_t DataTree::leavesPerFullChild(const DataInnerNode &root) const { return utils::intPow(_nodeStore->layout().maxChildrenPerInnerNode(), root.depth()-1); } uint64_t DataTree::numStoredBytes() const { return numStoredBytes(*_rootNode); } uint64_t DataTree::numStoredBytes(const DataNode &root) const { const DataLeafNode *leaf = dynamic_cast(&root); if (leaf != nullptr) { return leaf->numBytes(); } const DataInnerNode &inner = dynamic_cast(root); uint64_t numBytesInLeftChildren = (inner.numChildren()-1) * leavesPerFullChild(inner) * _nodeStore->layout().maxBytesPerLeaf(); auto lastChild = _nodeStore->load(inner.LastChild()->key()); uint64_t numBytesInRightChild = numStoredBytes(*lastChild); return numBytesInLeftChildren + numBytesInRightChild; } void DataTree::resizeNumBytes(uint64_t newNumBytes) { //TODO Faster implementation possible LastLeaf(_rootNode.get())->resize(_nodeStore->layout().maxBytesPerLeaf()); uint64_t currentNumBytes = numStoredBytes(); assert(currentNumBytes % _nodeStore->layout().maxBytesPerLeaf() == 0); uint32_t currentNumLeaves = currentNumBytes / _nodeStore->layout().maxBytesPerLeaf(); uint32_t newNumLeaves = std::max(1u, utils::ceilDivision(newNumBytes, _nodeStore->layout().maxBytesPerLeaf())); for(uint32_t i = currentNumLeaves; i < newNumLeaves; ++i) { addDataLeaf()->resize(_nodeStore->layout().maxBytesPerLeaf()); } for(uint32_t i = currentNumLeaves; i > newNumLeaves; --i) { removeLastDataLeaf(); } uint32_t newLastLeafSize = newNumBytes - (newNumLeaves-1)*_nodeStore->layout().maxBytesPerLeaf(); LastLeaf(_rootNode.get())->resize(newLastLeafSize); assert(newNumBytes == numStoredBytes()); flush(); } optional_ownership_ptr DataTree::LastLeaf(DataNode *root) { DataLeafNode *leaf = dynamic_cast(root); if (leaf != nullptr) { return WithoutOwnership(leaf); } DataInnerNode *inner = dynamic_cast(root); return WithOwnership(LastLeaf(_nodeStore->load(inner->LastChild()->key()))); } unique_ptr DataTree::LastLeaf(unique_ptr root) { auto leaf = dynamic_pointer_move(root); if (leaf.get() != nullptr) { return leaf; } auto inner = dynamic_pointer_move(root); return LastLeaf(_nodeStore->load(inner->LastChild()->key())); } uint32_t DataTree::maxBytesPerLeaf() const { return _nodeStore->layout().maxBytesPerLeaf(); } } } }