231 lines
9.9 KiB
C++
231 lines
9.9 KiB
C++
#include "testutils/DataTreeTest.h"
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#include "testutils/TwoLevelDataFixture.h"
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#include "blobstore/implementations/onblocks/utils/Math.h"
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#include <cpp-utils/data/Data.h>
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#include <tuple>
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using ::testing::WithParamInterface;
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using ::testing::Values;
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using ::testing::Combine;
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using std::tuple;
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using std::get;
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using std::function;
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using std::mem_fn;
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using cpputils::dynamic_pointer_move;
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using blobstore::onblocks::datanodestore::DataLeafNode;
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using blobstore::onblocks::datanodestore::DataInnerNode;
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using blobstore::onblocks::datanodestore::DataNode;
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using blobstore::onblocks::datanodestore::DataNodeLayout;
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using blobstore::onblocks::datatreestore::DataTree;
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using blobstore::onblocks::datatreestore::LeafHandle;
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using blobstore::onblocks::utils::ceilDivision;
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using blockstore::BlockId;
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using cpputils::Data;
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using boost::none;
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using cpputils::unique_ref;
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class DataTreeTest_ResizeByTraversing: public DataTreeTest {
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public:
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static constexpr DataNodeLayout LAYOUT = DataNodeLayout(BLOCKSIZE_BYTES);
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unique_ref<DataTree> CreateTree(unique_ref<DataNode> root) {
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BlockId blockId = root->blockId();
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cpputils::destruct(std::move(root));
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return treeStore.load(blockId).value();
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}
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unique_ref<DataTree> CreateLeafTreeWithSize(uint32_t size) {
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return CreateTree(CreateLeafWithSize(size));
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}
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unique_ref<DataTree> CreateTwoLeafTreeWithSecondLeafSize(uint32_t size) {
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return CreateTree(CreateTwoLeafWithSecondLeafSize(size));
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}
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unique_ref<DataTree> CreateFullTwoLevelTreeWithLastLeafSize(uint32_t size) {
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return CreateTree(CreateFullTwoLevelWithLastLeafSize(size));
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}
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unique_ref<DataTree> CreateThreeLevelTreeWithTwoChildrenAndLastLeafSize(uint32_t size) {
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return CreateTree(CreateThreeLevelWithTwoChildrenAndLastLeafSize(size));
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}
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unique_ref<DataTree> CreateThreeLevelTreeWithThreeChildrenAndLastLeafSize(uint32_t size) {
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return CreateTree(CreateThreeLevelWithThreeChildrenAndLastLeafSize(size));
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}
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unique_ref<DataTree> CreateFullThreeLevelTreeWithLastLeafSize(uint32_t size) {
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return CreateTree(CreateFullThreeLevelWithLastLeafSize(size));
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}
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unique_ref<DataTree> CreateFourLevelMinDataTreeWithLastLeafSize(uint32_t size) {
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return CreateTree(CreateFourLevelMinDataWithLastLeafSize(size));
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}
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void EXPECT_IS_LEFTMAXDATA_TREE(const BlockId &blockId) {
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auto root = nodeStore->load(blockId).value();
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DataInnerNode *inner = dynamic_cast<DataInnerNode*>(root.get());
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if (inner != nullptr) {
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for (uint32_t i = 0; i < inner->numChildren()-1; ++i) {
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EXPECT_IS_MAXDATA_TREE(inner->readChild(i).blockId());
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}
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EXPECT_IS_LEFTMAXDATA_TREE(inner->readLastChild().blockId());
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}
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}
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void EXPECT_IS_MAXDATA_TREE(const BlockId &blockId) {
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auto root = nodeStore->load(blockId).value();
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DataInnerNode *inner = dynamic_cast<DataInnerNode*>(root.get());
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if (inner != nullptr) {
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for (uint32_t i = 0; i < inner->numChildren(); ++i) {
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EXPECT_IS_MAXDATA_TREE(inner->readChild(i).blockId());
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}
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} else {
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DataLeafNode *leaf = dynamic_cast<DataLeafNode*>(root.get());
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EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf(), leaf->numBytes());
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}
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}
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};
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constexpr DataNodeLayout DataTreeTest_ResizeByTraversing::LAYOUT;
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class DataTreeTest_ResizeByTraversing_P: public DataTreeTest_ResizeByTraversing, public WithParamInterface<tuple<function<unique_ref<DataTree>(DataTreeTest_ResizeByTraversing*, uint32_t)>, uint32_t, uint32_t, std::function<uint32_t (uint32_t oldNumberOfLeaves, uint32_t newNumberOfLeaves)>>> {
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public:
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DataTreeTest_ResizeByTraversing_P()
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: oldLastLeafSize(get<1>(GetParam())),
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tree(get<0>(GetParam())(this, oldLastLeafSize)),
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numberOfLeavesToAdd(get<2>(GetParam())),
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newNumberOfLeaves(tree->numLeaves()+numberOfLeavesToAdd),
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traversalBeginIndex(get<3>(GetParam())(tree->numLeaves(), newNumberOfLeaves)),
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ZEROES(LAYOUT.maxBytesPerLeaf())
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{
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ZEROES.FillWithZeroes();
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}
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void GrowTree(const BlockId &blockId) {
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auto tree = treeStore.load(blockId);
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GrowTree(tree.get().get());
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}
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void GrowTree(DataTree *tree, std::function<void (int32_t)> traverse = [] (uint32_t){}) {
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uint64_t maxBytesPerLeaf = tree->maxBytesPerLeaf();
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tree->traverseLeaves(traversalBeginIndex, newNumberOfLeaves, [&traverse] (uint32_t index, bool, LeafHandle){traverse(index);}, [maxBytesPerLeaf, &traverse] (uint32_t index) -> Data { traverse(index); return Data(maxBytesPerLeaf).FillWithZeroes();});
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tree->flush();
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}
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unique_ref<DataLeafNode> LastLeaf(const BlockId &blockId) {
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auto root = nodeStore->load(blockId).value();
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auto leaf = dynamic_pointer_move<DataLeafNode>(root);
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if (leaf != none) {
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return std::move(*leaf);
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}
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auto inner = dynamic_pointer_move<DataInnerNode>(root).value();
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return LastLeaf(inner->readLastChild().blockId());
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}
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uint32_t oldLastLeafSize;
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unique_ref<DataTree> tree;
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uint32_t numberOfLeavesToAdd;
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uint32_t newNumberOfLeaves;
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uint32_t traversalBeginIndex;
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Data ZEROES;
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};
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INSTANTIATE_TEST_CASE_P(DataTreeTest_ResizeByTraversing_P, DataTreeTest_ResizeByTraversing_P,
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Combine(
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//Tree we're starting with
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Values<function<unique_ref<DataTree>(DataTreeTest_ResizeByTraversing*, uint32_t)>>(
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateLeafTreeWithSize),
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateTwoLeafTreeWithSecondLeafSize),
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateFullTwoLevelTreeWithLastLeafSize),
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateThreeLevelTreeWithTwoChildrenAndLastLeafSize),
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateThreeLevelTreeWithThreeChildrenAndLastLeafSize),
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateFullThreeLevelTreeWithLastLeafSize),
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mem_fn(&DataTreeTest_ResizeByTraversing::CreateFourLevelMinDataTreeWithLastLeafSize)
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),
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//Last leaf size of the start tree
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Values(
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0u,
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1u,
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10u,
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DataTreeTest_ResizeByTraversing::LAYOUT.maxBytesPerLeaf()
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),
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//Number of leaves we're adding
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Values(
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1u,
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2u,
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DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode(), //Full two level tree
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2* DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode(), //Three level tree with two children
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3* DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode(), //Three level tree with three children
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DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode() * DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode(), //Full three level tree
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DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode() * DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode() + 1 //Four level mindata tree
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),
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//Decide the traversal begin index
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Values(
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[] (uint32_t /*oldNumberOfLeaves*/, uint32_t newNumberOfLeaves) {return newNumberOfLeaves;}, // Don't traverse any leaves, just resize (begin==end)
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[] (uint32_t /*oldNumberOfLeaves*/, uint32_t newNumberOfLeaves) {return newNumberOfLeaves-1;}, // Traverse last leaf (begin==end-1)
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[] (uint32_t oldNumberOfLeaves, uint32_t newNumberOfLeaves) {return (oldNumberOfLeaves+newNumberOfLeaves)/2;}, // Start traversal in middle of new leaves
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[] (uint32_t oldNumberOfLeaves, uint32_t /*newNumberOfLeaves*/) {return oldNumberOfLeaves-1;}, // Start traversal with last old leaf
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[] (uint32_t oldNumberOfLeaves, uint32_t /*newNumberOfLeaves*/) {return oldNumberOfLeaves;}, // Start traversal with first new leaf
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[] (uint32_t /*oldNumberOfLeaves*/, uint32_t /*newNumberOfLeaves*/) {return 0;}, // Traverse full tree
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[] (uint32_t /*oldNumberOfLeaves*/, uint32_t /*newNumberOfLeaves*/) {return 1;} // Traverse full tree except first leaf
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)
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)
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);
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TEST_P(DataTreeTest_ResizeByTraversing_P, StructureIsValid) {
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GrowTree(tree.get());
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EXPECT_IS_LEFTMAXDATA_TREE(tree->blockId());
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}
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TEST_P(DataTreeTest_ResizeByTraversing_P, NumLeavesIsCorrect_FromCache) {
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tree->numLeaves(); // fill cache with old value
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GrowTree(tree.get());
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// tree->numLeaves() only goes down the right border nodes and expects the tree to be a left max data tree.
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// This is what the StructureIsValid test case is for.
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EXPECT_EQ(newNumberOfLeaves, tree->numLeaves());
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}
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TEST_P(DataTreeTest_ResizeByTraversing_P, NumLeavesIsCorrect) {
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GrowTree(tree.get());
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// tree->_forceComputeNumLeaves() only goes down the right border nodes and expects the tree to be a left max data tree.
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// This is what the StructureIsValid test case is for.
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EXPECT_EQ(newNumberOfLeaves, tree->_forceComputeNumLeaves());
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}
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TEST_P(DataTreeTest_ResizeByTraversing_P, DepthFlagsAreCorrect) {
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GrowTree(tree.get());
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uint32_t depth = ceil(log(newNumberOfLeaves)/log(DataTreeTest_ResizeByTraversing::LAYOUT.maxChildrenPerInnerNode()));
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CHECK_DEPTH(depth, tree->blockId());
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}
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TEST_P(DataTreeTest_ResizeByTraversing_P, KeyDoesntChange) {
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BlockId blockId = tree->blockId();
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tree->flush();
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GrowTree(tree.get());
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EXPECT_EQ(blockId, tree->blockId());
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}
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TEST_P(DataTreeTest_ResizeByTraversing_P, DataStaysIntact) {
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uint32_t oldNumberOfLeaves = std::max(UINT64_C(1), ceilDivision(tree->numStoredBytes(), static_cast<uint64_t>(nodeStore->layout().maxBytesPerLeaf())));
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TwoLevelDataFixture data(nodeStore, TwoLevelDataFixture::SizePolicy::Unchanged);
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BlockId blockId = tree->blockId();
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cpputils::destruct(std::move(tree));
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data.FillInto(nodeStore->load(blockId).get().get());
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GrowTree(blockId);
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data.EXPECT_DATA_CORRECT(nodeStore->load(blockId).get().get(), oldNumberOfLeaves, oldLastLeafSize);
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}
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TEST_P(DataTreeTest_ResizeByTraversing_P, AllLeavesAreTraversed) {
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std::vector<uint32_t> traversedLeaves;
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GrowTree(tree.get(), [&traversedLeaves] (uint32_t index) {traversedLeaves.push_back(index);});
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EXPECT_EQ(newNumberOfLeaves-traversalBeginIndex, traversedLeaves.size());
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for (uint32_t i = traversalBeginIndex; i < newNumberOfLeaves; ++i) {
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EXPECT_NE(traversedLeaves.end(), std::find(traversedLeaves.begin(), traversedLeaves.end(), i));
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}
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}
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