Merge branch 'release/0.10' into develop

This commit is contained in:
Sebastian Messmer 2019-01-12 23:21:40 -08:00
commit d86fcf27c6
18 changed files with 658 additions and 336 deletions

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@ -22,6 +22,8 @@ Version 0.9.10 (unreleased)
--------------
Fixed bugs:
* Fixed occasional deadlock (https://github.com/cryfs/cryfs/issues/64)
* Fix for reading empty files out of bounds
* Fixed race condition (https://github.com/cryfs/cryfs/issues/224)
Version 0.9.9

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@ -11,6 +11,7 @@ set(SOURCES
implementations/onblocks/datanodestore/DataInnerNode.cpp
implementations/onblocks/datanodestore/DataNodeStore.cpp
implementations/onblocks/datatreestore/impl/algorithms.cpp
implementations/onblocks/datatreestore/impl/CachedValue.cpp
implementations/onblocks/datatreestore/impl/LeafTraverser.cpp
implementations/onblocks/datatreestore/LeafHandle.cpp
implementations/onblocks/datatreestore/DataTree.cpp

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@ -8,13 +8,9 @@
#include <cpp-utils/assert/assert.h>
#include "datatreestore/LeafHandle.h"
using std::function;
using std::unique_lock;
using std::mutex;
using cpputils::unique_ref;
using cpputils::Data;
using blockstore::BlockId;
using blobstore::onblocks::datatreestore::LeafHandle;
namespace blobstore {
namespace onblocks {
@ -22,128 +18,34 @@ namespace onblocks {
using parallelaccessdatatreestore::DataTreeRef;
BlobOnBlocks::BlobOnBlocks(unique_ref<DataTreeRef> datatree)
: _datatree(std::move(datatree)), _sizeCache(boost::none), _mutex() {
: _datatree(std::move(datatree)) {
}
BlobOnBlocks::~BlobOnBlocks() {
} // NOLINT (workaround https://gcc.gnu.org/bugzilla/show_bug.cgi?id=82481 )
uint64_t BlobOnBlocks::size() const {
if (_sizeCache == boost::none) {
_sizeCache = _datatree->numStoredBytes();
}
return *_sizeCache;
return _datatree->numBytes();
}
void BlobOnBlocks::resize(uint64_t numBytes) {
_datatree->resizeNumBytes(numBytes);
_sizeCache = numBytes;
}
void BlobOnBlocks::_traverseLeaves(uint64_t beginByte, uint64_t sizeBytes, function<void (uint64_t leafOffset, LeafHandle leaf, uint32_t begin, uint32_t count)> onExistingLeaf, function<Data (uint64_t beginByte, uint32_t count)> onCreateLeaf) const {
unique_lock<mutex> lock(_mutex); // TODO Multiple traverse calls in parallel?
uint64_t endByte = beginByte + sizeBytes;
uint64_t maxBytesPerLeaf = _datatree->maxBytesPerLeaf();
uint32_t firstLeaf = beginByte / maxBytesPerLeaf;
uint32_t endLeaf = utils::ceilDivision(endByte, maxBytesPerLeaf);
bool blobIsGrowingFromThisTraversal = false;
auto _onExistingLeaf = [&onExistingLeaf, beginByte, endByte, endLeaf, maxBytesPerLeaf, &blobIsGrowingFromThisTraversal] (uint32_t leafIndex, bool isRightBorderLeaf, LeafHandle leafHandle) {
uint64_t indexOfFirstLeafByte = leafIndex * maxBytesPerLeaf;
ASSERT(endByte > indexOfFirstLeafByte, "Traversal went too far right");
uint32_t dataBegin = utils::maxZeroSubtraction(beginByte, indexOfFirstLeafByte);
uint32_t dataEnd = std::min(maxBytesPerLeaf, endByte - indexOfFirstLeafByte);
// If we are traversing exactly until the last leaf, then the last leaf wasn't resized by the traversal and might have a wrong size. We have to fix it.
if (isRightBorderLeaf) {
ASSERT(leafIndex == endLeaf-1, "If we traversed further right, this wouldn't be the right border leaf.");
auto leaf = leafHandle.node();
if (leaf->numBytes() < dataEnd) {
leaf->resize(dataEnd);
blobIsGrowingFromThisTraversal = true;
}
}
onExistingLeaf(indexOfFirstLeafByte, std::move(leafHandle), dataBegin, dataEnd-dataBegin);
};
auto _onCreateLeaf = [&onCreateLeaf, maxBytesPerLeaf, beginByte, firstLeaf, endByte, endLeaf, &blobIsGrowingFromThisTraversal] (uint32_t leafIndex) -> Data {
blobIsGrowingFromThisTraversal = true;
uint64_t indexOfFirstLeafByte = leafIndex * maxBytesPerLeaf;
ASSERT(endByte > indexOfFirstLeafByte, "Traversal went too far right");
uint32_t dataBegin = utils::maxZeroSubtraction(beginByte, indexOfFirstLeafByte);
uint32_t dataEnd = std::min(maxBytesPerLeaf, endByte - indexOfFirstLeafByte);
ASSERT(leafIndex == firstLeaf || dataBegin == 0, "Only the leftmost leaf can have a gap on the left.");
ASSERT(leafIndex == endLeaf-1 || dataEnd == maxBytesPerLeaf, "Only the rightmost leaf can have a gap on the right");
Data data = onCreateLeaf(indexOfFirstLeafByte + dataBegin, dataEnd-dataBegin);
ASSERT(data.size() == dataEnd-dataBegin, "Returned leaf data with wrong size");
// If this leaf is created but only partly in the traversed region (i.e. dataBegin > leafBegin), we have to fill the data before the traversed region with zeroes.
if (dataBegin != 0) {
Data actualData(dataBegin + data.size());
std::memset(actualData.data(), 0, dataBegin);
std::memcpy(actualData.dataOffset(dataBegin), data.data(), data.size());
data = std::move(actualData);
}
return data;
};
_datatree->traverseLeaves(firstLeaf, endLeaf, _onExistingLeaf, _onCreateLeaf);
if (blobIsGrowingFromThisTraversal) {
ASSERT(_datatree->numStoredBytes() == endByte, "Writing didn't grow by the correct number of bytes");
_sizeCache = endByte;
}
}
Data BlobOnBlocks::readAll() const {
//TODO Querying size is inefficient. Is this possible without a call to size()?
uint64_t count = size();
Data result(count);
_read(result.data(), 0, count);
return result;
return _datatree->readAllBytes();
}
void BlobOnBlocks::read(void *target, uint64_t offset, uint64_t count) const {
uint64_t _size = size();
ASSERT(offset <= _size && offset + count <= _size, "BlobOnBlocks::read() read outside blob. Use BlobOnBlocks::tryRead() if this should be allowed.");
uint64_t read = tryRead(target, offset, count);
ASSERT(read == count, "BlobOnBlocks::read() couldn't read all requested bytes. Use BlobOnBlocks::tryRead() if this should be allowed.");
return _datatree->readBytes(target, offset, count);
}
uint64_t BlobOnBlocks::tryRead(void *target, uint64_t offset, uint64_t count) const {
//TODO Quite inefficient to call size() here, because that has to traverse the tree
uint64_t realCount = std::max(INT64_C(0), std::min(static_cast<int64_t>(count), static_cast<int64_t>(size())-static_cast<int64_t>(offset)));
_read(target, offset, realCount);
return realCount;
}
void BlobOnBlocks::_read(void *target, uint64_t offset, uint64_t count) const {
auto onExistingLeaf = [target, offset, count] (uint64_t indexOfFirstLeafByte, LeafHandle leaf, uint32_t leafDataOffset, uint32_t leafDataSize) {
ASSERT(indexOfFirstLeafByte+leafDataOffset>=offset && indexOfFirstLeafByte-offset+leafDataOffset <= count && indexOfFirstLeafByte-offset+leafDataOffset+leafDataSize <= count, "Writing to target out of bounds");
//TODO Simplify formula, make it easier to understand
leaf.node()->read(static_cast<uint8_t*>(target) + indexOfFirstLeafByte - offset + leafDataOffset, leafDataOffset, leafDataSize);
};
auto onCreateLeaf = [] (uint64_t /*beginByte*/, uint32_t /*count*/) -> Data {
ASSERT(false, "Reading shouldn't create new leaves.");
};
_traverseLeaves(offset, count, onExistingLeaf, onCreateLeaf);
return _datatree->tryReadBytes(target, offset, count);
}
void BlobOnBlocks::write(const void *source, uint64_t offset, uint64_t count) {
auto onExistingLeaf = [source, offset, count] (uint64_t indexOfFirstLeafByte, LeafHandle leaf, uint32_t leafDataOffset, uint32_t leafDataSize) {
ASSERT(indexOfFirstLeafByte+leafDataOffset>=offset && indexOfFirstLeafByte-offset+leafDataOffset <= count && indexOfFirstLeafByte-offset+leafDataOffset+leafDataSize <= count, "Reading from source out of bounds");
if (leafDataOffset == 0 && leafDataSize == leaf.nodeStore()->layout().maxBytesPerLeaf()) {
Data leafData(leafDataSize);
std::memcpy(leafData.data(), static_cast<const uint8_t*>(source) + indexOfFirstLeafByte - offset, leafDataSize);
leaf.nodeStore()->overwriteLeaf(leaf.blockId(), std::move(leafData));
} else {
//TODO Simplify formula, make it easier to understand
leaf.node()->write(static_cast<const uint8_t*>(source) + indexOfFirstLeafByte - offset + leafDataOffset, leafDataOffset,
leafDataSize);
}
};
auto onCreateLeaf = [source, offset, count] (uint64_t beginByte, uint32_t numBytes) -> Data {
ASSERT(beginByte >= offset && beginByte-offset <= count && beginByte-offset+numBytes <= count, "Reading from source out of bounds");
Data result(numBytes);
//TODO Simplify formula, make it easier to understand
std::memcpy(result.data(), static_cast<const uint8_t*>(source) + beginByte - offset, numBytes);
return result;
};
_traverseLeaves(offset, count, onExistingLeaf, onCreateLeaf);
_datatree->writeBytes(source, offset, count);
}
void BlobOnBlocks::flush() {

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@ -7,6 +7,7 @@
#include <memory>
#include <boost/optional.hpp>
#include <boost/thread/shared_mutex.hpp>
namespace blobstore {
namespace onblocks {
@ -38,12 +39,11 @@ public:
private:
uint64_t _tryRead(void *target, uint64_t offset, uint64_t size) const;
void _read(void *target, uint64_t offset, uint64_t count) const;
void _traverseLeaves(uint64_t offsetBytes, uint64_t sizeBytes, std::function<void (uint64_t leafOffset, datatreestore::LeafHandle leaf, uint32_t begin, uint32_t count)> onExistingLeaf, std::function<cpputils::Data (uint64_t beginByte, uint32_t count)> onCreateLeaf) const;
cpputils::unique_ref<parallelaccessdatatreestore::DataTreeRef> _datatree;
mutable boost::optional<uint64_t> _sizeCache;
mutable std::mutex _mutex;
DISALLOW_COPY_AND_ASSIGN(BlobOnBlocks);
};

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@ -12,6 +12,7 @@
#include <cmath>
#include <cpp-utils/assert/assert.h>
#include "impl/LeafTraverser.h"
#include <boost/thread.hpp>
using blockstore::BlockId;
using blobstore::onblocks::datanodestore::DataNodeStore;
@ -24,17 +25,21 @@ using boost::shared_mutex;
using boost::shared_lock;
using boost::unique_lock;
using boost::none;
using boost::optional;
using cpputils::optional_ownership_ptr;
using cpputils::unique_ref;
using cpputils::Data;
using namespace cpputils::logging;
//TODO shared_lock currently not enough for traverse because of root replacement. Can be fixed while keeping shared?
namespace blobstore {
namespace onblocks {
namespace datatreestore {
DataTree::DataTree(DataNodeStore *nodeStore, unique_ref<DataNode> rootNode)
: _mutex(), _nodeStore(nodeStore), _rootNode(std::move(rootNode)), _blockId(_rootNode->blockId()), _numLeavesCache(none) {
: _treeStructureMutex(), _nodeStore(nodeStore), _rootNode(std::move(rootNode)), _blockId(_rootNode->blockId()), _sizeCache() {
}
DataTree::~DataTree() {
@ -45,102 +50,143 @@ const BlockId &DataTree::blockId() const {
}
void DataTree::flush() const {
// By grabbing a lock, we ensure that all modifying functions don't run currently and are therefore flushed
unique_lock<shared_mutex> lock(_mutex);
// By grabbing a lock, we ensure that all modifying functions don't run currently and are therefore flushed.
// It's only a shared lock, because this doesn't modify the tree structure.
shared_lock<shared_mutex> lock(_treeStructureMutex);
// We also have to flush the root node
_rootNode->flush();
}
unique_ref<DataNode> DataTree::releaseRootNode() {
unique_lock<shared_mutex> lock(_mutex); // Lock ensures that the root node is currently set (traversing unsets it temporarily)
// Lock also ensures that the root node is currently set (traversing unsets it temporarily)
// It's a unique lock because this "modifies" tree structure by changing _rootNode.
unique_lock<shared_mutex> lock(_treeStructureMutex);
return std::move(_rootNode);
}
//TODO Test numLeaves(), for example also two configurations with same number of bytes but different number of leaves (last leaf has 0 bytes)
uint32_t DataTree::numLeaves() const {
shared_lock<shared_mutex> lock(_mutex);
return _numLeaves();
shared_lock<shared_mutex> lock(_treeStructureMutex);
return _getOrComputeSizeCache().numLeaves;
}
uint32_t DataTree::_numLeaves() const {
if (_numLeavesCache == none) {
_numLeavesCache = _computeNumLeaves(*_rootNode);
}
return *_numLeavesCache;
uint64_t DataTree::numBytes() const {
shared_lock<shared_mutex> lock(_treeStructureMutex);
return _numBytes();
}
uint32_t DataTree::_forceComputeNumLeaves() const {
unique_lock<shared_mutex> lock(_mutex); // Lock ensures that the root node is currently set (traversing unsets it temporarily)
_numLeavesCache = _computeNumLeaves(*_rootNode);
return *_numLeavesCache;
uint64_t DataTree::_numBytes() const {
return _getOrComputeSizeCache().numBytes;
}
uint32_t DataTree::_computeNumLeaves(const DataNode &node) const {
DataTree::SizeCache DataTree::_getOrComputeSizeCache() const {
return _sizeCache.getOrCompute([this] () {
return _computeSizeCache(*_rootNode);
});
}
uint32_t DataTree::forceComputeNumLeaves() const {
_sizeCache.clear();
return numLeaves();
}
DataTree::SizeCache DataTree::_computeSizeCache(const DataNode &node) const {
const DataLeafNode *leaf = dynamic_cast<const DataLeafNode*>(&node);
if (leaf != nullptr) {
return 1;
return {1, leaf->numBytes()};
}
const DataInnerNode &inner = dynamic_cast<const DataInnerNode&>(node);
uint64_t numLeavesInLeftChildren = static_cast<uint64_t>(inner.numChildren()-1) * leavesPerFullChild(inner);
uint32_t numLeavesInLeftChildren = static_cast<uint32_t>(inner.numChildren()-1) * _leavesPerFullChild(inner);
uint64_t numBytesInLeftChildren = numLeavesInLeftChildren * _nodeStore->layout().maxBytesPerLeaf();
auto lastChild = _nodeStore->load(inner.readLastChild().blockId());
ASSERT(lastChild != none, "Couldn't load last child");
uint64_t numLeavesInRightChild = _computeNumLeaves(**lastChild);
SizeCache sizeInRightChild = _computeSizeCache(**lastChild);
return numLeavesInLeftChildren + numLeavesInRightChild;
return SizeCache {
numLeavesInLeftChildren + sizeInRightChild.numLeaves,
numBytesInLeftChildren + sizeInRightChild.numBytes
};
}
void DataTree::traverseLeaves(uint32_t beginIndex, uint32_t endIndex, function<void (uint32_t index, bool isRightBorderLeaf, LeafHandle leaf)> onExistingLeaf, function<Data (uint32_t index)> onCreateLeaf) {
//TODO Can we allow multiple runs of traverseLeaves() in parallel? Also in parallel with resizeNumBytes()?
std::unique_lock<shared_mutex> lock(_mutex);
ASSERT(beginIndex <= endIndex, "Invalid parameters");
void DataTree::_traverseLeavesByLeafIndices(uint32_t beginIndex, uint32_t endIndex, bool readOnlyTraversal,
function<void (uint32_t index, bool isRightBorderLeaf, LeafHandle leaf)> onExistingLeaf,
function<Data (uint32_t index)> onCreateLeaf,
function<void (DataInnerNode *node)> onBacktrackFromSubtree) const {
if(endIndex <= beginIndex) {
return;
}
auto onBacktrackFromSubtree = [] (DataInnerNode* /*node*/) {};
// TODO no const cast
LeafTraverser(_nodeStore, readOnlyTraversal).traverseAndUpdateRoot(&const_cast<DataTree*>(this)->_rootNode, beginIndex, endIndex, onExistingLeaf, onCreateLeaf, onBacktrackFromSubtree);
}
_traverseLeaves(beginIndex, endIndex, onExistingLeaf, onCreateLeaf, onBacktrackFromSubtree);
void DataTree::_traverseLeavesByByteIndices(uint64_t beginByte, uint64_t sizeBytes, bool readOnlyTraversal, function<void (uint64_t leafOffset, LeafHandle leaf, uint32_t begin, uint32_t count)> onExistingLeaf, function<Data (uint64_t beginByte, uint32_t count)> onCreateLeaf) const {
if (sizeBytes == 0) {
return;
}
if (_numLeavesCache != none && *_numLeavesCache < endIndex) {
_numLeavesCache = endIndex;
uint64_t endByte = beginByte + sizeBytes;
uint64_t _maxBytesPerLeaf = maxBytesPerLeaf();
uint32_t firstLeaf = beginByte / _maxBytesPerLeaf;
uint32_t endLeaf = utils::ceilDivision(endByte, _maxBytesPerLeaf);
bool blobIsGrowingFromThisTraversal = false;
auto _onExistingLeaf = [&onExistingLeaf, beginByte, endByte, endLeaf, _maxBytesPerLeaf, &blobIsGrowingFromThisTraversal] (uint32_t leafIndex, bool isRightBorderLeaf, LeafHandle leafHandle) {
uint64_t indexOfFirstLeafByte = leafIndex * _maxBytesPerLeaf;
ASSERT(endByte > indexOfFirstLeafByte, "Traversal went too far right");
uint32_t dataBegin = utils::maxZeroSubtraction(beginByte, indexOfFirstLeafByte);
uint32_t dataEnd = std::min(_maxBytesPerLeaf, endByte - indexOfFirstLeafByte);
// If we are traversing exactly until the last leaf, then the last leaf wasn't resized by the traversal and might have a wrong size. We have to fix it.
if (isRightBorderLeaf) {
ASSERT(leafIndex == endLeaf-1, "If we traversed further right, this wouldn't be the right border leaf.");
auto leaf = leafHandle.node();
if (leaf->numBytes() < dataEnd) {
leaf->resize(dataEnd);
blobIsGrowingFromThisTraversal = true;
}
}
onExistingLeaf(indexOfFirstLeafByte, std::move(leafHandle), dataBegin, dataEnd-dataBegin);
};
auto _onCreateLeaf = [&onCreateLeaf, _maxBytesPerLeaf, beginByte, firstLeaf, endByte, endLeaf, &blobIsGrowingFromThisTraversal, readOnlyTraversal] (uint32_t leafIndex) -> Data {
ASSERT(!readOnlyTraversal, "Cannot create leaves in a read-only traversal");
blobIsGrowingFromThisTraversal = true;
uint64_t indexOfFirstLeafByte = leafIndex * _maxBytesPerLeaf;
ASSERT(endByte > indexOfFirstLeafByte, "Traversal went too far right");
uint32_t dataBegin = utils::maxZeroSubtraction(beginByte, indexOfFirstLeafByte);
uint32_t dataEnd = std::min(_maxBytesPerLeaf, endByte - indexOfFirstLeafByte);
ASSERT(leafIndex == firstLeaf || dataBegin == 0, "Only the leftmost leaf can have a gap on the left.");
ASSERT(leafIndex == endLeaf-1 || dataEnd == _maxBytesPerLeaf, "Only the rightmost leaf can have a gap on the right");
Data data = onCreateLeaf(indexOfFirstLeafByte + dataBegin, dataEnd-dataBegin);
ASSERT(data.size() == dataEnd-dataBegin, "Returned leaf data with wrong size");
// If this leaf is created but only partly in the traversed region (i.e. dataBegin > leafBegin), we have to fill the data before the traversed region with zeroes.
if (dataBegin != 0) {
Data actualData(dataBegin + data.size());
std::memset(actualData.data(), 0, dataBegin);
std::memcpy(actualData.dataOffset(dataBegin), data.data(), data.size());
data = std::move(actualData);
}
return data;
};
auto _onBacktrackFromSubtree = [] (DataInnerNode* /*node*/) {};
_traverseLeavesByLeafIndices(firstLeaf, endLeaf, readOnlyTraversal, _onExistingLeaf, _onCreateLeaf, _onBacktrackFromSubtree);
ASSERT(!readOnlyTraversal || !blobIsGrowingFromThisTraversal, "Blob grew from traversal that didn't allow growing (i.e. reading)");
if (blobIsGrowingFromThisTraversal) {
_sizeCache.update([endLeaf, endByte] (optional<SizeCache>* cache) {
*cache = SizeCache{endLeaf, endByte};
});
}
}
void DataTree::_traverseLeaves(uint32_t beginIndex, uint32_t endIndex,
function<void (uint32_t index, bool isRightBorderLeaf, LeafHandle leaf)> onExistingLeaf,
function<Data (uint32_t index)> onCreateLeaf,
function<void (DataInnerNode *node)> onBacktrackFromSubtree) {
LeafTraverser(_nodeStore).traverseAndUpdateRoot(&_rootNode, beginIndex, endIndex, onExistingLeaf, onCreateLeaf, onBacktrackFromSubtree);
}
uint32_t DataTree::leavesPerFullChild(const DataInnerNode &root) const {
uint32_t DataTree::_leavesPerFullChild(const DataInnerNode &root) const {
return utils::intPow(_nodeStore->layout().maxChildrenPerInnerNode(), static_cast<uint64_t>(root.depth())-1);
}
uint64_t DataTree::numStoredBytes() const {
shared_lock<shared_mutex> lock(_mutex);
return _numStoredBytes();
}
uint64_t DataTree::_numStoredBytes() const {
return _numStoredBytes(*_rootNode);
}
uint64_t DataTree::_numStoredBytes(const DataNode &root) const {
const DataLeafNode *leaf = dynamic_cast<const DataLeafNode*>(&root);
if (leaf != nullptr) {
return leaf->numBytes();
}
const DataInnerNode &inner = dynamic_cast<const DataInnerNode&>(root);
uint64_t numBytesInLeftChildren = (inner.numChildren()-1) * leavesPerFullChild(inner) * _nodeStore->layout().maxBytesPerLeaf();
auto lastChild = _nodeStore->load(inner.readLastChild().blockId());
ASSERT(lastChild != none, "Couldn't load last child");
uint64_t numBytesInRightChild = _numStoredBytes(**lastChild);
return numBytesInLeftChildren + numBytesInRightChild;
}
void DataTree::resizeNumBytes(uint64_t newNumBytes) {
std::unique_lock<shared_mutex> lock(_mutex); // TODO Multiple ones in parallel? Also in parallel with traverseLeaves()?
std::unique_lock<shared_mutex> lock(_treeStructureMutex);
uint32_t newNumLeaves = std::max(UINT64_C(1), utils::ceilDivision(newNumBytes, _nodeStore->layout().maxBytesPerLeaf()));
uint32_t newLastLeafSize = newNumBytes - (newNumLeaves-1) * _nodeStore->layout().maxBytesPerLeaf();
@ -171,8 +217,11 @@ void DataTree::resizeNumBytes(uint64_t newNumBytes) {
}
};
_traverseLeaves(newNumLeaves - 1, newNumLeaves, onExistingLeaf, onCreateLeaf, onBacktrackFromSubtree);
_numLeavesCache = newNumLeaves;
_traverseLeavesByLeafIndices(newNumLeaves - 1, newNumLeaves, false, onExistingLeaf, onCreateLeaf, onBacktrackFromSubtree);
_sizeCache.update([newNumLeaves, newNumBytes] (boost::optional<SizeCache>* cache) {
*cache = SizeCache{newNumLeaves, newNumBytes};
});
}
uint64_t DataTree::maxBytesPerLeaf() const {
@ -180,9 +229,87 @@ uint64_t DataTree::maxBytesPerLeaf() const {
}
uint8_t DataTree::depth() const {
shared_lock<shared_mutex> lock(_treeStructureMutex);
return _rootNode->depth();
}
void DataTree::readBytes(void *target, uint64_t offset, uint64_t count) const {
shared_lock<shared_mutex> lock(_treeStructureMutex);
const uint64_t _size = _numBytes();
if(offset > _size || offset + count > _size) {
throw std::runtime_error("BlobOnBlocks::read() read outside blob. Use BlobOnBlocks::tryRead() if this should be allowed.");
}
const uint64_t read = _tryReadBytes(target, offset, count);
if (read != count) {
throw std::runtime_error("BlobOnBlocks::read() couldn't read all requested bytes. Use BlobOnBlocks::tryRead() if this should be allowed.");
}
}
Data DataTree::readAllBytes() const {
shared_lock<shared_mutex> lock(_treeStructureMutex);
//TODO Querying numBytes can be inefficient. Is this possible without a call to size()?
uint64_t count = _numBytes();
Data result(count);
_doReadBytes(result.data(), 0, count);
return result;
}
uint64_t DataTree::tryReadBytes(void *target, uint64_t offset, uint64_t count) const {
shared_lock<shared_mutex> lock(_treeStructureMutex);
auto result = _tryReadBytes(target, offset, count);
return result;
}
uint64_t DataTree::_tryReadBytes(void *target, uint64_t offset, uint64_t count) const {
//TODO Quite inefficient to call size() here, because that has to traverse the tree
const uint64_t _size = _numBytes();
const uint64_t realCount = std::max(INT64_C(0), std::min(static_cast<int64_t>(count), static_cast<int64_t>(_size)-static_cast<int64_t>(offset)));
_doReadBytes(target, offset, realCount);
return realCount;
}
void DataTree::_doReadBytes(void *target, uint64_t offset, uint64_t count) const {
auto onExistingLeaf = [target, offset, count] (uint64_t indexOfFirstLeafByte, LeafHandle leaf, uint32_t leafDataOffset, uint32_t leafDataSize) {
ASSERT(indexOfFirstLeafByte+leafDataOffset>=offset && indexOfFirstLeafByte-offset+leafDataOffset <= count && indexOfFirstLeafByte-offset+leafDataOffset+leafDataSize <= count, "Writing to target out of bounds");
//TODO Simplify formula, make it easier to understand
leaf.node()->read(static_cast<uint8_t*>(target) + indexOfFirstLeafByte - offset + leafDataOffset, leafDataOffset, leafDataSize);
};
auto onCreateLeaf = [] (uint64_t /*beginByte*/, uint32_t /*count*/) -> Data {
ASSERT(false, "Reading shouldn't create new leaves.");
};
_traverseLeavesByByteIndices(offset, count, true, onExistingLeaf, onCreateLeaf);
}
void DataTree::writeBytes(const void *source, uint64_t offset, uint64_t count) {
unique_lock<shared_mutex> lock(_treeStructureMutex);
auto onExistingLeaf = [source, offset, count] (uint64_t indexOfFirstLeafByte, LeafHandle leaf, uint32_t leafDataOffset, uint32_t leafDataSize) {
ASSERT(indexOfFirstLeafByte+leafDataOffset>=offset && indexOfFirstLeafByte-offset+leafDataOffset <= count && indexOfFirstLeafByte-offset+leafDataOffset+leafDataSize <= count, "Reading from source out of bounds");
if (leafDataOffset == 0 && leafDataSize == leaf.nodeStore()->layout().maxBytesPerLeaf()) {
Data leafData(leafDataSize);
std::memcpy(leafData.data(), static_cast<const uint8_t*>(source) + indexOfFirstLeafByte - offset, leafDataSize);
leaf.nodeStore()->overwriteLeaf(leaf.blockId(), std::move(leafData));
} else {
//TODO Simplify formula, make it easier to understand
leaf.node()->write(static_cast<const uint8_t*>(source) + indexOfFirstLeafByte - offset + leafDataOffset, leafDataOffset,
leafDataSize);
}
};
auto onCreateLeaf = [source, offset, count] (uint64_t beginByte, uint32_t numBytes) -> Data {
ASSERT(beginByte >= offset && beginByte-offset <= count && beginByte-offset+numBytes <= count, "Reading from source out of bounds");
Data result(numBytes);
//TODO Simplify formula, make it easier to understand
std::memcpy(result.data(), static_cast<const uint8_t*>(source) + beginByte - offset, numBytes);
return result;
};
_traverseLeavesByByteIndices(offset, count, false, onExistingLeaf, onCreateLeaf);
}
}
}
}

View File

@ -10,6 +10,7 @@
#include <boost/thread/shared_mutex.hpp>
#include <blockstore/utils/BlockId.h>
#include "LeafHandle.h"
#include "impl/CachedValue.h"
namespace blobstore {
namespace onblocks {
@ -31,39 +32,57 @@ public:
//Returning uint64_t, because calculations handling this probably need to be done in 64bit to support >4GB blobs.
uint64_t maxBytesPerLeaf() const;
void traverseLeaves(uint32_t beginIndex, uint32_t endIndex, std::function<void (uint32_t index, bool isRightBorderLeaf, LeafHandle leaf)> onExistingLeaf, std::function<cpputils::Data (uint32_t index)> onCreateLeaf);
uint64_t tryReadBytes(void *target, uint64_t offset, uint64_t count) const;
void readBytes(void *target, uint64_t offset, uint64_t count) const;
cpputils::Data readAllBytes() const;
void writeBytes(const void *source, uint64_t offset, uint64_t count);
void resizeNumBytes(uint64_t newNumBytes);
uint32_t numLeaves() const;
uint64_t numStoredBytes() const;
uint64_t numBytes() const;
uint8_t depth() const;
// only used by test cases
uint32_t _forceComputeNumLeaves() const;
uint32_t forceComputeNumLeaves() const;
void flush() const;
private:
mutable boost::shared_mutex _mutex;
// This mutex must protect the tree structure, i.e. which nodes exist and how they're connected.
// Also protects total number of bytes (i.e. number of leaves + size of last leaf).
// It also protects the data in leaf nodes, because writing bytes might grow the blob and change the structure.
mutable boost::shared_mutex _treeStructureMutex;
datanodestore::DataNodeStore *_nodeStore;
cpputils::unique_ref<datanodestore::DataNode> _rootNode;
blockstore::BlockId _blockId; // BlockId is stored in a member variable, since _rootNode is nullptr while traversing, but we still want to be able to return the blockId.
mutable boost::optional<uint32_t> _numLeavesCache;
struct SizeCache final {
uint32_t numLeaves;
uint64_t numBytes;
};
mutable CachedValue<SizeCache> _sizeCache;
cpputils::unique_ref<datanodestore::DataNode> releaseRootNode();
friend class DataTreeStore;
//TODO Use underscore for private methods
void _traverseLeaves(uint32_t beginIndex, uint32_t endIndex,
void _traverseLeavesByLeafIndices(uint32_t beginIndex, uint32_t endIndex, bool readOnlyTraversal,
std::function<void (uint32_t index, bool isRightBorderLeaf, LeafHandle leaf)> onExistingLeaf,
std::function<cpputils::Data (uint32_t index)> onCreateLeaf,
std::function<void (datanodestore::DataInnerNode *node)> onBacktrackFromSubtree);
uint32_t leavesPerFullChild(const datanodestore::DataInnerNode &root) const;
uint64_t _numStoredBytes() const;
uint64_t _numStoredBytes(const datanodestore::DataNode &root) const;
uint32_t _numLeaves() const;
uint32_t _computeNumLeaves(const datanodestore::DataNode &node) const;
std::function<void (datanodestore::DataInnerNode *node)> onBacktrackFromSubtree) const;
void _traverseLeavesByByteIndices(uint64_t beginByte, uint64_t sizeBytes, bool readOnlyTraversal, std::function<void (uint64_t leafOffset, LeafHandle leaf, uint32_t begin, uint32_t count)> onExistingLeaf, std::function<cpputils::Data (uint64_t beginByte, uint32_t count)> onCreateLeaf) const;
uint32_t _leavesPerFullChild(const datanodestore::DataInnerNode &root) const;
SizeCache _getOrComputeSizeCache() const;
SizeCache _computeSizeCache(const datanodestore::DataNode &node) const;
uint64_t _tryReadBytes(void *target, uint64_t offset, uint64_t count) const;
void _doReadBytes(void *target, uint64_t offset, uint64_t count) const;
uint64_t _numBytes() const;
DISALLOW_COPY_AND_ASSIGN(DataTree);
};

View File

@ -0,0 +1,2 @@
#include "CachedValue.h"

View File

@ -0,0 +1,46 @@
#pragma once
#ifndef MESSMER_BLOBSTORE_IMPLEMENTATIONS_ONBLOCKS_IMPL_CACHEDVALUE_H_
#define MESSMER_BLOBSTORE_IMPLEMENTATIONS_ONBLOCKS_IMPL_CACHEDVALUE_H_
#include <boost/optional.hpp>
#include <boost/thread/shared_mutex.hpp>
#include <functional>
namespace blobstore {
namespace onblocks {
// TODO Test
template<class T>
class CachedValue final {
public:
CachedValue() :_cache(boost::none), _mutex() {}
T getOrCompute(std::function<T ()> compute) {
boost::upgrade_lock<boost::shared_mutex> readLock(_mutex);
if (_cache == boost::none) {
boost::upgrade_to_unique_lock<boost::shared_mutex> writeLock(readLock);
_cache = compute();
}
return *_cache;
}
void update(std::function<void (boost::optional<T>*)> func) {
boost::unique_lock<boost::shared_mutex> writeLock(_mutex);
func(&_cache);
}
void clear() {
update([] (boost::optional<T>* cache) {
*cache = boost::none;
});
}
private:
boost::optional<T> _cache;
boost::shared_mutex _mutex;
};
}
}
#endif

View File

@ -20,8 +20,8 @@ namespace blobstore {
namespace onblocks {
namespace datatreestore {
LeafTraverser::LeafTraverser(DataNodeStore *nodeStore)
: _nodeStore(nodeStore) {
LeafTraverser::LeafTraverser(DataNodeStore *nodeStore, bool readOnlyTraversal)
: _nodeStore(nodeStore), _readOnlyTraversal(readOnlyTraversal) {
}
void LeafTraverser::traverseAndUpdateRoot(unique_ref<DataNode>* root, uint32_t beginIndex, uint32_t endIndex, function<void (uint32_t index, bool isRightBorderLeaf, LeafHandle leaf)> onExistingLeaf, function<Data (uint32_t index)> onCreateLeaf, function<void (DataInnerNode *node)> onBacktrackFromSubtree) {
@ -38,6 +38,7 @@ namespace blobstore {
uint32_t maxLeavesForDepth = _maxLeavesForTreeDepth((*root)->depth());
bool increaseTreeDepth = endIndex > maxLeavesForDepth;
ASSERT(!_readOnlyTraversal || !increaseTreeDepth, "Tried to grow a tree on a read only traversal");
if ((*root)->depth() == 0) {
DataLeafNode *leaf = dynamic_cast<DataLeafNode*>(root->get());
@ -63,6 +64,8 @@ namespace blobstore {
// We don't increase to the full needed tree depth in one step, because we want the traversal to go as far as possible
// and only then increase the depth - this causes the tree to be in consistent shape (balanced) for longer.
if (increaseTreeDepth) {
ASSERT(!_readOnlyTraversal, "Can't increase tree depth in a read-only traversal");
// TODO Test cases that increase tree depth by 0, 1, 2, ... levels
*root = _increaseTreeDepth(std::move(*root));
_traverseAndUpdateRoot(root, std::max(beginIndex, maxLeavesForDepth), endIndex, false, onExistingLeaf, onCreateLeaf, onBacktrackFromSubtree);
@ -74,6 +77,8 @@ namespace blobstore {
}
unique_ref<DataInnerNode> LeafTraverser::_increaseTreeDepth(unique_ref<DataNode> root) {
ASSERT(!_readOnlyTraversal, "Can't increase tree depth in a read-only traversal");
auto copyOfOldRoot = _nodeStore->createNewNodeAsCopyFrom(*root);
return DataNode::convertToNewInnerNode(std::move(root), _nodeStore->layout(), *copyOfOldRoot);
}
@ -85,6 +90,7 @@ namespace blobstore {
LeafHandle leafHandle(_nodeStore, blockId);
if (growLastLeaf) {
if (leafHandle.node()->numBytes() != _nodeStore->layout().maxBytesPerLeaf()) {
ASSERT(!_readOnlyTraversal, "Can't grow the last leaf in a read-only traversal");
leafHandle.node()->resize(_nodeStore->layout().maxBytesPerLeaf());
}
}
@ -116,6 +122,7 @@ namespace blobstore {
ASSERT(endChild <= _nodeStore->layout().maxChildrenPerInnerNode(), "Traversal region would need increasing the tree depth. This should have happened before calling this function.");
uint32_t numChildren = root->numChildren();
ASSERT(!growLastLeaf || endChild >= numChildren, "Can only grow last leaf if it exists");
ASSERT(!_readOnlyTraversal || endChild <= numChildren, "Can only traverse out of bounds in a read-only traversal");
bool shouldGrowLastExistingLeaf = growLastLeaf || endChild > numChildren;
// If we traverse outside of the valid region (i.e. usually would only traverse to new leaves and not to the last leaf),
@ -146,6 +153,8 @@ namespace blobstore {
// Traverse new children (including gap children, i.e. children that are created but not traversed because they're to the right of the current size, but to the left of the traversal region)
for (uint32_t childIndex = numChildren; childIndex < endChild; ++childIndex) {
ASSERT(!_readOnlyTraversal, "Can't create new children in a read-only traversal");
uint32_t childOffset = childIndex * leavesPerChild;
uint32_t localBeginIndex = std::min(leavesPerChild, utils::maxZeroSubtraction(beginIndex, childOffset));
uint32_t localEndIndex = std::min(leavesPerChild, endIndex - childOffset);
@ -161,6 +170,8 @@ namespace blobstore {
}
unique_ref<DataNode> LeafTraverser::_createNewSubtree(uint32_t beginIndex, uint32_t endIndex, uint32_t leafOffset, uint8_t depth, function<Data (uint32_t index)> onCreateLeaf, function<void (DataInnerNode *node)> onBacktrackFromSubtree) {
ASSERT(!_readOnlyTraversal, "Can't create a new subtree in a read-only traversal");
ASSERT(beginIndex <= endIndex, "Invalid parameters");
if (0 == depth) {
ASSERT(beginIndex <= 1 && endIndex == 1, "With depth 0, we can only traverse one or zero leaves (i.e. traverse one leaf or traverse a gap leaf).");
@ -212,6 +223,8 @@ namespace blobstore {
}
function<Data (uint32_t index)> LeafTraverser::_createMaxSizeLeaf() const {
ASSERT(!_readOnlyTraversal, "Can't create a new leaf in a read-only traversal");
uint64_t maxBytesPerLeaf = _nodeStore->layout().maxBytesPerLeaf();
return [maxBytesPerLeaf] (uint32_t /*index*/) -> Data {
return Data(maxBytesPerLeaf).FillWithZeroes();
@ -221,6 +234,8 @@ namespace blobstore {
void LeafTraverser::_whileRootHasOnlyOneChildReplaceRootWithItsChild(unique_ref<DataNode>* root) {
DataInnerNode *inner = dynamic_cast<DataInnerNode*>(root->get());
if (inner != nullptr && inner->numChildren() == 1) {
ASSERT(!_readOnlyTraversal, "Can't decrease tree depth in a read-only traversal");
auto newRoot = _whileRootHasOnlyOneChildRemoveRootReturnChild(inner->readChild(0).blockId());
*root = _nodeStore->overwriteNodeWith(std::move(*root), *newRoot);
_nodeStore->remove(std::move(newRoot));
@ -228,6 +243,8 @@ namespace blobstore {
}
unique_ref<DataNode> LeafTraverser::_whileRootHasOnlyOneChildRemoveRootReturnChild(const blockstore::BlockId &blockId) {
ASSERT(!_readOnlyTraversal, "Can't decrease tree depth in a read-only traversal");
auto current = _nodeStore->load(blockId);
ASSERT(current != none, "Node not found");
auto inner = dynamic_pointer_move<DataInnerNode>(*current);

View File

@ -25,7 +25,7 @@ namespace blobstore {
*/
class LeafTraverser final {
public:
LeafTraverser(datanodestore::DataNodeStore *nodeStore);
LeafTraverser(datanodestore::DataNodeStore *nodeStore, bool readOnlyTraversal);
void traverseAndUpdateRoot(
cpputils::unique_ref<datanodestore::DataNode>* root, uint32_t beginIndex, uint32_t endIndex,
@ -35,6 +35,7 @@ namespace blobstore {
private:
datanodestore::DataNodeStore *_nodeStore;
const bool _readOnlyTraversal;
void _traverseAndUpdateRoot(
cpputils::unique_ref<datanodestore::DataNode>* root, uint32_t beginIndex, uint32_t endIndex, bool isLeftBorderOfTraversal,

View File

@ -22,10 +22,6 @@ public:
return _baseTree->maxBytesPerLeaf();
}
void traverseLeaves(uint32_t beginIndex, uint32_t endIndex, std::function<void (uint32_t index, bool isRightBorderLeaf, datatreestore::LeafHandle leaf)> onExistingLeaf, std::function<cpputils::Data (uint32_t index)> onCreateLeaf) {
return _baseTree->traverseLeaves(beginIndex, endIndex, onExistingLeaf, onCreateLeaf);
}
uint32_t numLeaves() const {
return _baseTree->numLeaves();
}
@ -34,8 +30,24 @@ public:
return _baseTree->resizeNumBytes(newNumBytes);
}
uint64_t numStoredBytes() const {
return _baseTree->numStoredBytes();
uint64_t numBytes() const {
return _baseTree->numBytes();
}
uint64_t tryReadBytes(void *target, uint64_t offset, uint64_t count) const {
return _baseTree->tryReadBytes(target, offset, count);
}
void readBytes(void *target, uint64_t offset, uint64_t count) const {
return _baseTree->readBytes(target, offset, count);
}
cpputils::Data readAllBytes() const {
return _baseTree->readAllBytes();
}
void writeBytes(const void *source, uint64_t offset, uint64_t count) {
return _baseTree->writeBytes(source, offset, count);
}
void flush() {

View File

@ -19,7 +19,7 @@ set(SOURCES
implementations/onblocks/datatreestore/DataTreeTest_NumStoredBytes.cpp
implementations/onblocks/datatreestore/DataTreeTest_ResizeNumBytes.cpp
implementations/onblocks/datatreestore/DataTreeStoreTest.cpp
implementations/onblocks/datatreestore/DataTreeTest_TraverseLeaves.cpp
implementations/onblocks/datatreestore/LeafTraverserTest.cpp
implementations/onblocks/BlobSizeTest.cpp
implementations/onblocks/BlobReadWriteTest.cpp
implementations/onblocks/BigBlobsTest.cpp

View File

@ -63,6 +63,92 @@ TEST_F(BlobReadWriteTest, WritingCloseTo16ByteLimitDoesntDestroySize) {
EXPECT_EQ(32780u, blob->size());
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenTryReadInFirstLeaf_thenFails) {
Data data(5);
size_t read = blob->tryRead(data.data(), 3, 5);
EXPECT_EQ(0, read);
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenTryReadInLaterLeaf_thenFails) {
Data data(5);
size_t read = blob->tryRead(data.data(), 2*LAYOUT.maxBytesPerLeaf(), 5);
EXPECT_EQ(0, read);
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenReadInFirstLeaf_thenFails) {
Data data(5);
EXPECT_ANY_THROW(
blob->read(data.data(), 3, 5)
);
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenReadInLaterLeaf_thenFails) {
Data data(5);
EXPECT_ANY_THROW(
blob->read(data.data(), 2*LAYOUT.maxBytesPerLeaf(), 5)
);
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenReadAll_thenReturnsZeroSizedData) {
Data data = blob->readAll();
EXPECT_EQ(0, data.size());
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenWrite_thenGrows) {
Data data(5);
blob->write(data.data(), 4, 5);
EXPECT_EQ(9, blob->size());
}
TEST_F(BlobReadWriteTest, givenEmptyBlob_whenWriteZeroBytes_thenDoesntGrow) {
Data data(5);
blob->write(data.data(), 4, 0);
EXPECT_EQ(0, blob->size());;
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenTryReadInFirstLeaf_thenFails) {
Data data(5);
size_t read = blob->tryRead(data.data(), 3, 5);
EXPECT_EQ(0, read);
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenTryReadInLaterLeaf_thenFails) {
Data data(5);
size_t read = blob->tryRead(data.data(), 2*LAYOUT.maxBytesPerLeaf(), 5);
EXPECT_EQ(0, read);
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenReadInFirstLeaf_thenFails) {
Data data(5);
EXPECT_ANY_THROW(
blob->read(data.data(), 3, 5)
);
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenReadInLaterLeaf_thenFails) {
Data data(5);
EXPECT_ANY_THROW(
blob->read(data.data(), 2*LAYOUT.maxBytesPerLeaf(), 5)
);
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenReadAll_thenReturnsZeroSizedData) {
Data data = blob->readAll();
EXPECT_EQ(0, data.size());
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenWrite_thenGrows) {
Data data(5);
blob->write(data.data(), 4, 5);
EXPECT_EQ(9, blob->size());
}
TEST_F(BlobReadWriteTest, givenBlobResizedToZero_whenWriteZeroBytes_thenDoesntGrow) {
Data data(5);
blob->write(data.data(), 4, 0);
EXPECT_EQ(0, blob->size());
}
struct DataRange {
uint64_t blobsize;
uint64_t offset;

View File

@ -13,7 +13,7 @@ public:
TEST_F(DataTreeTest_NumStoredBytes, CreatedTreeIsEmpty) {
auto tree = treeStore.createNewTree();
EXPECT_EQ(0u, tree->numStoredBytes());
EXPECT_EQ(0u, tree->numBytes());
}
class DataTreeTest_NumStoredBytes_P: public DataTreeTest_NumStoredBytes, public WithParamInterface<uint32_t> {};
@ -24,47 +24,47 @@ INSTANTIATE_TEST_CASE_P(FullLastLeaf, DataTreeTest_NumStoredBytes_P, Values(stat
TEST_P(DataTreeTest_NumStoredBytes_P, SingleLeaf) {
BlockId blockId = CreateLeafWithSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(GetParam(), tree->numStoredBytes());
EXPECT_EQ(GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, TwoLeafTree) {
BlockId blockId = CreateTwoLeafWithSecondLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numStoredBytes());
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, FullTwolevelTree) {
BlockId blockId = CreateFullTwoLevelWithLastLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*(nodeStore->layout().maxChildrenPerInnerNode()-1) + GetParam(), tree->numStoredBytes());
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*(nodeStore->layout().maxChildrenPerInnerNode()-1) + GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, ThreeLevelTreeWithOneChild) {
BlockId blockId = CreateThreeLevelWithOneChildAndLastLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numStoredBytes());
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, ThreeLevelTreeWithTwoChildren) {
BlockId blockId = CreateThreeLevelWithTwoChildrenAndLastLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numStoredBytes());
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, ThreeLevelTreeWithThreeChildren) {
BlockId blockId = CreateThreeLevelWithThreeChildrenAndLastLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(2*nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numStoredBytes());
EXPECT_EQ(2*nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxBytesPerLeaf() + GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, FullThreeLevelTree) {
BlockId blockId = CreateFullThreeLevelWithLastLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode()*(nodeStore->layout().maxChildrenPerInnerNode()-1) + nodeStore->layout().maxBytesPerLeaf()*(nodeStore->layout().maxChildrenPerInnerNode()-1) + GetParam(), tree->numStoredBytes());
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode()*(nodeStore->layout().maxChildrenPerInnerNode()-1) + nodeStore->layout().maxBytesPerLeaf()*(nodeStore->layout().maxChildrenPerInnerNode()-1) + GetParam(), tree->numBytes());
}
TEST_P(DataTreeTest_NumStoredBytes_P, FourLevelMinDataTree) {
BlockId blockId = CreateFourLevelMinDataWithLastLeafSize(GetParam())->blockId();
auto tree = treeStore.load(blockId).value();
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode() + GetParam(), tree->numStoredBytes());
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf()*nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode() + GetParam(), tree->numBytes());
}

View File

@ -3,14 +3,24 @@
#include <gmock/gmock.h>
using blobstore::onblocks::datatreestore::DataTree;
using blobstore::onblocks::datatreestore::LeafHandle;
using blockstore::BlockId;
using cpputils::Data;
class DataTreeTest_Performance: public DataTreeTest {
public:
void Traverse(DataTree *tree, uint64_t beginIndex, uint64_t endIndex) {
tree->traverseLeaves(beginIndex, endIndex, [] (uint32_t /*index*/, bool /*isRightBorderNode*/, LeafHandle /*leaf*/) {}, [this] (uint32_t /*index*/) -> Data {return Data(maxChildrenPerInnerNode).FillWithZeroes();});
void TraverseByWriting(DataTree *tree, uint64_t beginIndex, uint64_t endIndex) {
uint64_t offset = beginIndex * maxBytesPerLeaf;
uint64_t count = endIndex * maxBytesPerLeaf - offset;
Data data(count);
data.FillWithZeroes();
tree->writeBytes(data.data(), offset, count);
}
void TraverseByReading(DataTree *tree, uint64_t beginIndex, uint64_t endIndex) {
uint64_t offset = beginIndex * maxBytesPerLeaf;
uint64_t count = endIndex * maxBytesPerLeaf - offset;
Data data(count);
tree->readBytes(data.data(), offset, count);
}
uint64_t maxChildrenPerInnerNode = nodeStore->layout().maxChildrenPerInnerNode();
@ -71,84 +81,168 @@ TEST_F(DataTreeTest_Performance, DeletingDoesntLoadLeaves_Threelevel_DeleteByKey
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Twolevel_All) {
TEST_F(DataTreeTest_Performance, TraverseLeaves_Twolevel_All_ByWriting) {
auto blockId = CreateFullTwoLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 0, maxChildrenPerInnerNode);
TraverseByWriting(tree.get(), 0, maxChildrenPerInnerNode);
EXPECT_EQ(0u, blockStore->loadedBlocks().size()); // Doesn't actually load the leaves, but returns the keys of the leaves to the callback
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Has to load the rightmost leaf once to adapt its size, rest of the leaves aren't loaded but just overwritten
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(maxChildrenPerInnerNode, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Twolevel_Some) {
TEST_F(DataTreeTest_Performance, TraverseLeaves_Twolevel_All_ByReading) {
auto blockId = CreateFullTwoLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 3, 5);
TraverseByReading(tree.get(), 0, maxChildrenPerInnerNode);
EXPECT_EQ(0u, blockStore->loadedBlocks().size()); // Doesn't actually load the leaves, but returns the keys of the leaves to the callback
EXPECT_EQ(1u + maxChildrenPerInnerNode, blockStore->loadedBlocks().size()); // Has to read the rightmost leaf an additional time in the beginning to determine size.
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_All) {
auto blockId = CreateFullThreeLevel()->blockId();
TEST_F(DataTreeTest_Performance, TraverseLeaves_Twolevel_Some_ByWriting) {
auto blockId = CreateFullTwoLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 0, maxChildrenPerInnerNode * maxChildrenPerInnerNode);
TraverseByWriting(tree.get(), 3, 5);
EXPECT_EQ(maxChildrenPerInnerNode, blockStore->loadedBlocks().size()); // Loads inner nodes. Doesn't load the leaves, but returns the keys of the leaves to the callback
EXPECT_EQ(0u, blockStore->loadedBlocks().size());
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(2u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Twolevel_Some_ByReading) {
auto blockId = CreateFullTwoLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
TraverseByReading(tree.get(), 3, 5);
EXPECT_EQ(3u, blockStore->loadedBlocks().size()); // reads 2 leaves and the rightmost leaf to determine size
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_InOneInner) {
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_All_ByWriting) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 3, 5);
TraverseByWriting(tree.get(), 0, maxChildrenPerInnerNode * maxChildrenPerInnerNode);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads inner node. Doesn't load the leaves, but returns the keys of the leaves to the callback
EXPECT_EQ(maxChildrenPerInnerNode + 1, blockStore->loadedBlocks().size()); // Loads inner nodes and has to load the rightmost leaf once to adapt its size, rest of the leaves aren't loaded but just overwritten.
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(maxChildrenPerInnerNode*maxChildrenPerInnerNode, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_All_ByReading) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
TraverseByReading(tree.get(), 0, maxChildrenPerInnerNode * maxChildrenPerInnerNode);
EXPECT_EQ(maxChildrenPerInnerNode*maxChildrenPerInnerNode + maxChildrenPerInnerNode + 2, blockStore->loadedBlocks().size()); // Loads inner nodes and leaves. Has to load the rightmost inner node and leaf an additional time at the beginning to compute size
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_InTwoInner) {
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_InOneInner_ByWriting) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 3, 3 + maxChildrenPerInnerNode);
TraverseByWriting(tree.get(), 3, 5);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads inner node. Doesn't load the leaves, they're just overwritten.
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(2u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_InOneInner_ByReading) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
TraverseByReading(tree.get(), 3, 5);
EXPECT_EQ(5u, blockStore->loadedBlocks().size()); // reads 2 leaves and the inner node, also has to read the rightmost inner node and leaf additionally at the beginning to determine size
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_InTwoInner_ByWriting) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
TraverseByWriting(tree.get(), 3, 3 + maxChildrenPerInnerNode);
EXPECT_EQ(2u, blockStore->loadedBlocks().size()); // Loads both inner node
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(maxChildrenPerInnerNode, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_WholeInner) {
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_InTwoInner_ByReading) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), maxChildrenPerInnerNode, 2*maxChildrenPerInnerNode);
TraverseByReading(tree.get(), 3, 3 + maxChildrenPerInnerNode);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads inner node. Doesn't load the leaves, but returns the keys of the leaves to the callback
EXPECT_EQ(4u + maxChildrenPerInnerNode, blockStore->loadedBlocks().size()); // Loads both inner nodes and the requested leaves. Also has to load rightmost inner node and leaf additionally in the beginning to determine size.
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_WholeInner_ByWriting) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
TraverseByWriting(tree.get(), maxChildrenPerInnerNode, 2*maxChildrenPerInnerNode);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads inner node. Doesn't load the leaves, they're just overwritten.
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(maxChildrenPerInnerNode, blockStore->distinctWrittenBlocks().size());
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
TEST_F(DataTreeTest_Performance, TraverseLeaves_Threelevel_WholeInner_ByReading) {
auto blockId = CreateFullThreeLevel()->blockId();
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
TraverseByReading(tree.get(), maxChildrenPerInnerNode, 2*maxChildrenPerInnerNode);
EXPECT_EQ(3u + maxChildrenPerInnerNode, blockStore->loadedBlocks().size()); // Loads inner node and all requested leaves. Also has to load rightmost inner node and leaf additionally in the beginning to determine size.
EXPECT_EQ(0u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(0u, blockStore->distinctWrittenBlocks().size());
@ -160,12 +254,12 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTree_StartingInside) {
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 1, 4);
TraverseByWriting(tree.get(), 1, 4);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads last old child (for growing it)
EXPECT_EQ(2u, blockStore->createdBlocks());
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(1u, blockStore->distinctWrittenBlocks().size()); // add children to inner node
EXPECT_EQ(2u, blockStore->distinctWrittenBlocks().size()); // write the data and add children to inner node
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
@ -174,7 +268,7 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTree_StartingOutside_TwoL
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 4, 5);
TraverseByWriting(tree.get(), 4, 5);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads last old leaf for growing it
EXPECT_EQ(3u, blockStore->createdBlocks());
@ -188,7 +282,7 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTree_StartingOutside_Thre
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 2*maxChildrenPerInnerNode+1, 2*maxChildrenPerInnerNode+2);
TraverseByWriting(tree.get(), 2*maxChildrenPerInnerNode+1, 2*maxChildrenPerInnerNode+2);
EXPECT_EQ(2u, blockStore->loadedBlocks().size()); // Loads last old leaf (and its inner node) for growing it
EXPECT_EQ(3u, blockStore->createdBlocks()); // inner node and two leaves
@ -202,12 +296,12 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTree_StartingAtBeginOfChi
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), maxChildrenPerInnerNode, 3*maxChildrenPerInnerNode);
TraverseByWriting(tree.get(), maxChildrenPerInnerNode, 3*maxChildrenPerInnerNode);
EXPECT_EQ(2u, blockStore->loadedBlocks().size()); // Loads inner node and one leaf to check whether we have to grow it. Doesn't load the leaves, but returns the keys of the leaves to the callback.
EXPECT_EQ(1u + maxChildrenPerInnerNode, blockStore->createdBlocks()); // Creates an inner node and its leaves
EXPECT_EQ(0u, blockStore->removedBlocks().size());
EXPECT_EQ(1u, blockStore->distinctWrittenBlocks().size()); // add children to existing inner node
EXPECT_EQ(maxChildrenPerInnerNode + 1u, blockStore->distinctWrittenBlocks().size()); // write data and add children to existing inner node
EXPECT_EQ(0u, blockStore->resizedBlocks().size());
}
@ -216,7 +310,7 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTreeDepth_StartingInOldDe
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 4, maxChildrenPerInnerNode+2);
TraverseByWriting(tree.get(), 4, maxChildrenPerInnerNode+2);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads last old leaf for growing it
EXPECT_EQ(2u + maxChildrenPerInnerNode, blockStore->createdBlocks()); // 2x new inner node + leaves
@ -230,7 +324,7 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTreeDepth_StartingInOldDe
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), 4, maxChildrenPerInnerNode+2);
TraverseByWriting(tree.get(), 4, maxChildrenPerInnerNode+2);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads last old leaf for growing it
EXPECT_EQ(2u + maxChildrenPerInnerNode, blockStore->createdBlocks()); // 2x new inner node + leaves
@ -244,7 +338,7 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTreeDepth_StartingInNewDe
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), maxChildrenPerInnerNode, maxChildrenPerInnerNode+2);
TraverseByWriting(tree.get(), maxChildrenPerInnerNode, maxChildrenPerInnerNode+2);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads last old leaf for growing it
EXPECT_EQ(2u + maxChildrenPerInnerNode, blockStore->createdBlocks()); // 2x new inner node + leaves
@ -258,7 +352,7 @@ TEST_F(DataTreeTest_Performance, TraverseLeaves_GrowingTreeDepth_StartingInNewDe
auto tree = treeStore.load(blockId).value();
blockStore->resetCounters();
Traverse(tree.get(), maxChildrenPerInnerNode, maxChildrenPerInnerNode+2);
TraverseByWriting(tree.get(), maxChildrenPerInnerNode, maxChildrenPerInnerNode+2);
EXPECT_EQ(1u, blockStore->loadedBlocks().size()); // Loads last old leaf for growing it
EXPECT_EQ(2u + maxChildrenPerInnerNode, blockStore->createdBlocks()); // 2x new inner node + leaves

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@ -19,7 +19,6 @@ using blobstore::onblocks::datanodestore::DataInnerNode;
using blobstore::onblocks::datanodestore::DataNode;
using blobstore::onblocks::datanodestore::DataNodeLayout;
using blobstore::onblocks::datatreestore::DataTree;
using blobstore::onblocks::datatreestore::LeafHandle;
using blobstore::onblocks::utils::ceilDivision;
using blockstore::BlockId;
using cpputils::Data;
@ -109,9 +108,13 @@ public:
GrowTree(tree.get().get());
}
void GrowTree(DataTree *tree, std::function<void (int32_t)> traverse = [] (uint32_t){}) {
void GrowTree(DataTree *tree) {
uint64_t maxBytesPerLeaf = tree->maxBytesPerLeaf();
tree->traverseLeaves(traversalBeginIndex, newNumberOfLeaves, [&traverse] (uint32_t index, bool, LeafHandle){traverse(index);}, [maxBytesPerLeaf, &traverse] (uint32_t index) -> Data { traverse(index); return Data(maxBytesPerLeaf).FillWithZeroes();});
uint64_t offset = traversalBeginIndex * maxBytesPerLeaf;
uint64_t count = newNumberOfLeaves * maxBytesPerLeaf - offset;
Data data(count);
data.FillWithZeroes();
tree->writeBytes(data.data(), offset, count);
tree->flush();
}
@ -163,7 +166,6 @@ INSTANTIATE_TEST_CASE_P(DataTreeTest_ResizeByTraversing_P, DataTreeTest_ResizeBy
),
//Decide the traversal begin index
Values(
[] (uint32_t /*oldNumberOfLeaves*/, uint32_t newNumberOfLeaves) {return newNumberOfLeaves;}, // Don't traverse any leaves, just resize (begin==end)
[] (uint32_t /*oldNumberOfLeaves*/, uint32_t newNumberOfLeaves) {return newNumberOfLeaves-1;}, // Traverse last leaf (begin==end-1)
[] (uint32_t oldNumberOfLeaves, uint32_t newNumberOfLeaves) {return (oldNumberOfLeaves+newNumberOfLeaves)/2;}, // Start traversal in middle of new leaves
[] (uint32_t oldNumberOfLeaves, uint32_t /*newNumberOfLeaves*/) {return oldNumberOfLeaves-1;}, // Start traversal with last old leaf
@ -189,9 +191,9 @@ TEST_P(DataTreeTest_ResizeByTraversing_P, NumLeavesIsCorrect_FromCache) {
TEST_P(DataTreeTest_ResizeByTraversing_P, NumLeavesIsCorrect) {
GrowTree(tree.get());
// tree->_forceComputeNumLeaves() only goes down the right border nodes and expects the tree to be a left max data tree.
// tree->forceComputeNumLeaves() only goes down the right border nodes and expects the tree to be a left max data tree.
// This is what the StructureIsValid test case is for.
EXPECT_EQ(newNumberOfLeaves, tree->_forceComputeNumLeaves());
EXPECT_EQ(newNumberOfLeaves, tree->forceComputeNumLeaves());
}
TEST_P(DataTreeTest_ResizeByTraversing_P, DepthFlagsAreCorrect) {
@ -208,7 +210,8 @@ TEST_P(DataTreeTest_ResizeByTraversing_P, KeyDoesntChange) {
}
TEST_P(DataTreeTest_ResizeByTraversing_P, DataStaysIntact) {
uint32_t oldNumberOfLeaves = std::max(UINT64_C(1), ceilDivision(tree->numStoredBytes(), static_cast<uint64_t>(nodeStore->layout().maxBytesPerLeaf())));
uint32_t oldNumberOfLeaves = std::max(UINT64_C(1), ceilDivision(tree->numBytes(), static_cast<uint64_t>(nodeStore->layout().maxBytesPerLeaf())));
TwoLevelDataFixture data(nodeStore, TwoLevelDataFixture::SizePolicy::Unchanged);
BlockId blockId = tree->blockId();
cpputils::destruct(std::move(tree));
@ -216,15 +219,13 @@ TEST_P(DataTreeTest_ResizeByTraversing_P, DataStaysIntact) {
GrowTree(blockId);
if (traversalBeginIndex < oldNumberOfLeaves) {
// Traversal wrote over part of the pre-existing data, we can only check the data before it.
if (traversalBeginIndex != 0) {
data.EXPECT_DATA_CORRECT(nodeStore->load(blockId).get().get(), traversalBeginIndex - 1);
}
} else {
// Here, traversal was entirely outside the preexisting data, we can check all preexisting data.
data.EXPECT_DATA_CORRECT(nodeStore->load(blockId).get().get(), oldNumberOfLeaves, oldLastLeafSize);
}
TEST_P(DataTreeTest_ResizeByTraversing_P, AllLeavesAreTraversed) {
std::vector<uint32_t> traversedLeaves;
GrowTree(tree.get(), [&traversedLeaves] (uint32_t index) {traversedLeaves.push_back(index);});
EXPECT_EQ(newNumberOfLeaves-traversalBeginIndex, traversedLeaves.size());
for (uint32_t i = traversalBeginIndex; i < newNumberOfLeaves; ++i) {
EXPECT_NE(traversedLeaves.end(), std::find(traversedLeaves.begin(), traversedLeaves.end(), i));
}
}

View File

@ -171,9 +171,9 @@ TEST_P(DataTreeTest_ResizeNumBytes_P, StructureIsValid) {
TEST_P(DataTreeTest_ResizeNumBytes_P, NumBytesIsCorrect) {
tree->resizeNumBytes(newSize);
tree->flush();
// tree->numStoredBytes() only goes down the right border nodes and expects the tree to be a left max data tree.
// tree->numBytes() only goes down the right border nodes and expects the tree to be a left max data tree.
// This is what the StructureIsValid test case is for.
EXPECT_EQ(newSize, tree->numStoredBytes());
EXPECT_EQ(newSize, tree->numBytes());
}
TEST_P(DataTreeTest_ResizeNumBytes_P, NumLeavesIsCorrect) {
@ -181,7 +181,7 @@ TEST_P(DataTreeTest_ResizeNumBytes_P, NumLeavesIsCorrect) {
tree->flush();
// tree->numLeaves() only goes down the right border nodes and expects the tree to be a left max data tree.
// This is what the StructureIsValid test case is for.
EXPECT_EQ(newNumberOfLeaves, tree->_forceComputeNumLeaves());
EXPECT_EQ(newNumberOfLeaves, tree->forceComputeNumLeaves());
}
TEST_P(DataTreeTest_ResizeNumBytes_P, NumLeavesIsCorrect_FromCache) {
@ -208,7 +208,7 @@ TEST_P(DataTreeTest_ResizeNumBytes_P, KeyDoesntChange) {
}
TEST_P(DataTreeTest_ResizeNumBytes_P, DataStaysIntact) {
uint32_t oldNumberOfLeaves = std::max(UINT64_C(1), ceilDivision(tree->numStoredBytes(), static_cast<uint64_t>(nodeStore->layout().maxBytesPerLeaf())));
uint32_t oldNumberOfLeaves = std::max(UINT64_C(1), ceilDivision(tree->numBytes(), static_cast<uint64_t>(nodeStore->layout().maxBytesPerLeaf())));
TwoLevelDataFixture data(nodeStore, TwoLevelDataFixture::SizePolicy::Unchanged);
BlockId blockId = tree->blockId();
cpputils::destruct(std::move(tree));

View File

@ -1,4 +1,5 @@
#include "testutils/DataTreeTest.h"
#include <blobstore/implementations/onblocks/datatreestore/impl/LeafTraverser.h>
#include <gmock/gmock.h>
using ::testing::_;
@ -9,6 +10,7 @@ using blobstore::onblocks::datanodestore::DataLeafNode;
using blobstore::onblocks::datanodestore::DataInnerNode;
using blobstore::onblocks::datanodestore::DataNode;
using blobstore::onblocks::datatreestore::LeafHandle;
using blobstore::onblocks::datatreestore::LeafTraverser;
using blockstore::BlockId;
using cpputils::unique_ref;
@ -26,9 +28,9 @@ MATCHER_P(KeyEq, expected, "node blockId equals") {
return arg->blockId() == expected;
}
class DataTreeTest_TraverseLeaves: public DataTreeTest {
class LeafTraverserTest: public DataTreeTest {
public:
DataTreeTest_TraverseLeaves() :traversor() {}
LeafTraverserTest() :traversor() {}
unique_ref<DataInnerNode> CreateThreeLevel() {
return CreateInner({
@ -70,166 +72,172 @@ public:
EXPECT_CALL(traversor, calledCreateLeaf(_)).Times(0);
}
void TraverseLeaves(DataNode *root, uint32_t beginIndex, uint32_t endIndex) {
void TraverseLeaves(unique_ref<DataNode> root, uint32_t beginIndex, uint32_t endIndex, bool expectReadOnly) {
root->flush();
auto tree = treeStore.load(root->blockId()).value();
tree->traverseLeaves(beginIndex, endIndex, [this] (uint32_t nodeIndex, bool isRightBorderNode,LeafHandle leaf) {
auto* old_root = root.get();
LeafTraverser(nodeStore, expectReadOnly).traverseAndUpdateRoot(&root, beginIndex, endIndex, [this] (uint32_t nodeIndex, bool isRightBorderNode,LeafHandle leaf) {
traversor.calledExistingLeaf(leaf.node(), isRightBorderNode, nodeIndex);
}, [this] (uint32_t nodeIndex) -> Data {
return traversor.calledCreateLeaf(nodeIndex)->copy();
});
}, [] (auto) {});
if (expectReadOnly) {
EXPECT_EQ(old_root, root.get());
} else {
EXPECT_NE(old_root, root.get());
}
}
TraversorMock traversor;
};
TEST_F(DataTreeTest_TraverseLeaves, TraverseSingleLeafTree) {
auto root = CreateLeaf();
TEST_F(LeafTraverserTest, TraverseSingleLeafTree) {
unique_ref<DataNode> root = CreateLeaf();
EXPECT_TRAVERSE_LEAF(root->blockId(), true, 0);
TraverseLeaves(root.get(), 0, 1);
TraverseLeaves(std::move(root), 0, 1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseNothingInSingleLeafTree1) {
auto root = CreateLeaf();
TEST_F(LeafTraverserTest, TraverseNothingInSingleLeafTree1) {
unique_ref<DataNode> root = CreateLeaf();
EXPECT_DONT_TRAVERSE_ANY_LEAVES();
TraverseLeaves(root.get(), 0, 0);
TraverseLeaves(std::move(root), 0, 0, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseNothingInSingleLeafTree2) {
auto root = CreateLeaf();
TEST_F(LeafTraverserTest, TraverseNothingInSingleLeafTree2) {
unique_ref<DataNode> root = CreateLeaf();
EXPECT_DONT_TRAVERSE_ANY_LEAVES();
TraverseLeaves(root.get(), 1, 1);
TraverseLeaves(std::move(root), 1, 1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstLeafOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseFirstLeafOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
EXPECT_TRAVERSE_LEAF(root->readChild(0).blockId(), false, 0);
TraverseLeaves(root.get(), 0, 1);
TraverseLeaves(std::move(root), 0, 1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddleLeafOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseMiddleLeafOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
EXPECT_TRAVERSE_LEAF(root->readChild(5).blockId(), false, 5);
TraverseLeaves(root.get(), 5, 6);
TraverseLeaves(std::move(root), 5, 6, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseLastLeafOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseLastLeafOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
EXPECT_TRAVERSE_LEAF(root->readChild(nodeStore->layout().maxChildrenPerInnerNode()-1).blockId(), true, nodeStore->layout().maxChildrenPerInnerNode()-1);
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode()-1, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode()-1, nodeStore->layout().maxChildrenPerInnerNode(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseNothingInFullTwolevelTree1) {
TEST_F(LeafTraverserTest, TraverseNothingInFullTwolevelTree1) {
auto root = CreateFullTwoLevel();
EXPECT_DONT_TRAVERSE_ANY_LEAVES();
TraverseLeaves(root.get(), 0, 0);
TraverseLeaves(std::move(root), 0, 0, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseNothingInFullTwolevelTree2) {
TEST_F(LeafTraverserTest, TraverseNothingInFullTwolevelTree2) {
auto root = CreateFullTwoLevel();
EXPECT_DONT_TRAVERSE_ANY_LEAVES();
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode(), nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode(), nodeStore->layout().maxChildrenPerInnerNode(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstLeafOfThreeLevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseFirstLeafOfThreeLevelMinDataTree) {
auto root = CreateThreeLevelMinData();
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(0).blockId())->readChild(0).blockId(), false, 0);
TraverseLeaves(root.get(), 0, 1);
TraverseLeaves(std::move(root), 0, 1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddleLeafOfThreeLevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseMiddleLeafOfThreeLevelMinDataTree) {
auto root = CreateThreeLevelMinData();
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(0).blockId())->readChild(5).blockId(), false, 5);
TraverseLeaves(root.get(), 5, 6);
TraverseLeaves(std::move(root), 5, 6, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseLastLeafOfThreeLevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseLastLeafOfThreeLevelMinDataTree) {
auto root = CreateThreeLevelMinData();
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(1).blockId())->readChild(0).blockId(), true, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode(), nodeStore->layout().maxChildrenPerInnerNode()+1);
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode(), nodeStore->layout().maxChildrenPerInnerNode()+1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseAllLeavesOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseAllLeavesOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
EXPECT_TRAVERSE_ALL_CHILDREN_OF(*root, true, 0);
TraverseLeaves(root.get(), 0, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(std::move(root), 0, nodeStore->layout().maxChildrenPerInnerNode(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseAllLeavesOfThreelevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseAllLeavesOfThreelevelMinDataTree) {
auto root = CreateThreeLevelMinData();
EXPECT_TRAVERSE_ALL_CHILDREN_OF(*LoadInnerNode(root->readChild(0).blockId()), false, 0);
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(1).blockId())->readChild(0).blockId(), true, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(root.get(), 0, nodeStore->layout().maxChildrenPerInnerNode()+1);
TraverseLeaves(std::move(root), 0, nodeStore->layout().maxChildrenPerInnerNode()+1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstChildOfThreelevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseFirstChildOfThreelevelMinDataTree) {
auto root = CreateThreeLevelMinData();
EXPECT_TRAVERSE_ALL_CHILDREN_OF(*LoadInnerNode(root->readChild(0).blockId()), false, 0);
TraverseLeaves(root.get(), 0, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(std::move(root), 0, nodeStore->layout().maxChildrenPerInnerNode(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstPartOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseFirstPartOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
for (unsigned int i = 0; i < 5; ++i) {
EXPECT_TRAVERSE_LEAF(root->readChild(i).blockId(), false, i);
}
TraverseLeaves(root.get(), 0, 5);
TraverseLeaves(std::move(root), 0, 5, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseInnerPartOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseInnerPartOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
for (unsigned int i = 5; i < 10; ++i) {
EXPECT_TRAVERSE_LEAF(root->readChild(i).blockId(), false, i);
}
TraverseLeaves(root.get(), 5, 10);
TraverseLeaves(std::move(root), 5, 10, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseLastPartOfFullTwolevelTree) {
TEST_F(LeafTraverserTest, TraverseLastPartOfFullTwolevelTree) {
auto root = CreateFullTwoLevel();
for (unsigned int i = 5; i < nodeStore->layout().maxChildrenPerInnerNode(); ++i) {
EXPECT_TRAVERSE_LEAF(root->readChild(i).blockId(), i==nodeStore->layout().maxChildrenPerInnerNode()-1, i);
}
TraverseLeaves(root.get(), 5, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(std::move(root), 5, nodeStore->layout().maxChildrenPerInnerNode(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstPartOfThreelevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseFirstPartOfThreelevelMinDataTree) {
auto root = CreateThreeLevelMinData();
auto node = LoadInnerNode(root->readChild(0).blockId());
for (unsigned int i = 0; i < 5; ++i) {
EXPECT_TRAVERSE_LEAF(node->readChild(i).blockId(), false, i);
}
TraverseLeaves(root.get(), 0, 5);
TraverseLeaves(std::move(root), 0, 5, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseInnerPartOfThreelevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseInnerPartOfThreelevelMinDataTree) {
auto root = CreateThreeLevelMinData();
auto node = LoadInnerNode(root->readChild(0).blockId());
for (unsigned int i = 5; i < 10; ++i) {
EXPECT_TRAVERSE_LEAF(node->readChild(i).blockId(), false, i);
}
TraverseLeaves(root.get(), 5, 10);
TraverseLeaves(std::move(root), 5, 10, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseLastPartOfThreelevelMinDataTree) {
TEST_F(LeafTraverserTest, TraverseLastPartOfThreelevelMinDataTree) {
auto root = CreateThreeLevelMinData();
auto node = LoadInnerNode(root->readChild(0).blockId());
for (unsigned int i = 5; i < nodeStore->layout().maxChildrenPerInnerNode(); ++i) {
@ -237,33 +245,33 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseLastPartOfThreelevelMinDataTree) {
}
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(1).blockId())->readChild(0).blockId(), true, nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(root.get(), 5, nodeStore->layout().maxChildrenPerInnerNode()+1);
TraverseLeaves(std::move(root), 5, nodeStore->layout().maxChildrenPerInnerNode()+1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstLeafOfThreelevelTree) {
TEST_F(LeafTraverserTest, TraverseFirstLeafOfThreelevelTree) {
auto root = CreateThreeLevel();
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(0).blockId())->readChild(0).blockId(), false, 0);
TraverseLeaves(root.get(), 0, 1);
TraverseLeaves(std::move(root), 0, 1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseLastLeafOfThreelevelTree) {
TEST_F(LeafTraverserTest, TraverseLastLeafOfThreelevelTree) {
auto root = CreateThreeLevel();
uint32_t numLeaves = nodeStore->layout().maxChildrenPerInnerNode() * 5 + 3;
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readLastChild().blockId())->readLastChild().blockId(), true, numLeaves-1);
TraverseLeaves(root.get(), numLeaves-1, numLeaves);
TraverseLeaves(std::move(root), numLeaves-1, numLeaves, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddleLeafOfThreelevelTree) {
TEST_F(LeafTraverserTest, TraverseMiddleLeafOfThreelevelTree) {
auto root = CreateThreeLevel();
uint32_t wantedLeafIndex = nodeStore->layout().maxChildrenPerInnerNode() * 2 + 5;
EXPECT_TRAVERSE_LEAF(LoadInnerNode(root->readChild(2).blockId())->readChild(5).blockId(), false, wantedLeafIndex);
TraverseLeaves(root.get(), wantedLeafIndex, wantedLeafIndex+1);
TraverseLeaves(std::move(root), wantedLeafIndex, wantedLeafIndex+1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstPartOfThreelevelTree) {
TEST_F(LeafTraverserTest, TraverseFirstPartOfThreelevelTree) {
auto root = CreateThreeLevel();
//Traverse all leaves in the first two children of the root
for(unsigned int i = 0; i < 2; ++i) {
@ -275,10 +283,10 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseFirstPartOfThreelevelTree) {
EXPECT_TRAVERSE_LEAF(child->readChild(i).blockId(), false, 2 * nodeStore->layout().maxChildrenPerInnerNode() + i);
}
TraverseLeaves(root.get(), 0, 2 * nodeStore->layout().maxChildrenPerInnerNode() + 5);
TraverseLeaves(std::move(root), 0, 2 * nodeStore->layout().maxChildrenPerInnerNode() + 5, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddlePartOfThreelevelTree_OnlyFullChildren) {
TEST_F(LeafTraverserTest, TraverseMiddlePartOfThreelevelTree_OnlyFullChildren) {
auto root = CreateThreeLevel();
//Traverse some of the leaves in the second child of the root
auto child = LoadInnerNode(root->readChild(1).blockId());
@ -295,10 +303,10 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddlePartOfThreelevelTree_OnlyFullC
EXPECT_TRAVERSE_LEAF(child->readChild(i).blockId(), false, 4 * nodeStore->layout().maxChildrenPerInnerNode() + i);
}
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode() + 5, 4 * nodeStore->layout().maxChildrenPerInnerNode() + 5);
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode() + 5, 4 * nodeStore->layout().maxChildrenPerInnerNode() + 5, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddlePartOfThreelevelTree_AlsoLastNonfullChild) {
TEST_F(LeafTraverserTest, TraverseMiddlePartOfThreelevelTree_AlsoLastNonfullChild) {
auto root = CreateThreeLevel();
//Traverse some of the leaves in the second child of the root
auto child = LoadInnerNode(root->readChild(1).blockId());
@ -315,10 +323,10 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddlePartOfThreelevelTree_AlsoLastN
EXPECT_TRAVERSE_LEAF(child->readChild(i).blockId(), false, 5 * nodeStore->layout().maxChildrenPerInnerNode() + i);
}
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode() + 5, 5 * nodeStore->layout().maxChildrenPerInnerNode() + 2);
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode() + 5, 5 * nodeStore->layout().maxChildrenPerInnerNode() + 2, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseLastPartOfThreelevelTree) {
TEST_F(LeafTraverserTest, TraverseLastPartOfThreelevelTree) {
auto root = CreateThreeLevel();
//Traverse some of the leaves in the second child of the root
auto child = LoadInnerNode(root->readChild(1).blockId());
@ -335,10 +343,10 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseLastPartOfThreelevelTree) {
EXPECT_TRAVERSE_LEAF(child->readChild(i).blockId(), i == child->numChildren()-1, 5 * nodeStore->layout().maxChildrenPerInnerNode() + i);
}
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode() + 5, 5 * nodeStore->layout().maxChildrenPerInnerNode() + child->numChildren());
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode() + 5, 5 * nodeStore->layout().maxChildrenPerInnerNode() + child->numChildren(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseAllLeavesOfThreelevelTree) {
TEST_F(LeafTraverserTest, TraverseAllLeavesOfThreelevelTree) {
auto root = CreateThreeLevel();
//Traverse all leaves in the third, fourth and fifth child of the root
for(unsigned int i = 0; i < 5; ++i) {
@ -350,10 +358,10 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseAllLeavesOfThreelevelTree) {
EXPECT_TRAVERSE_LEAF(child->readChild(i).blockId(), i==child->numChildren()-1, 5 * nodeStore->layout().maxChildrenPerInnerNode() + i);
}
TraverseLeaves(root.get(), 0, 5 * nodeStore->layout().maxChildrenPerInnerNode() + child->numChildren());
TraverseLeaves(std::move(root), 0, 5 * nodeStore->layout().maxChildrenPerInnerNode() + child->numChildren(), true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseAllLeavesOfFourLevelTree) {
TEST_F(LeafTraverserTest, TraverseAllLeavesOfFourLevelTree) {
auto root = CreateFourLevel();
//Traverse all leaves of the full threelevel tree in the first child
auto firstChild = LoadInnerNode(root->readChild(0).blockId());
@ -370,10 +378,10 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseAllLeavesOfFourLevelTree) {
EXPECT_TRAVERSE_ALL_CHILDREN_OF(*LoadInnerNode(thirdChild->readChild(0).blockId()), false, 2 * nodeStore->layout().maxChildrenPerInnerNode() * nodeStore->layout().maxChildrenPerInnerNode());
EXPECT_TRAVERSE_LEAF(LoadInnerNode(thirdChild->readChild(1).blockId())->readChild(0).blockId(), true, 2 * nodeStore->layout().maxChildrenPerInnerNode() * nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxChildrenPerInnerNode());
TraverseLeaves(root.get(), 0, 2*nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxChildrenPerInnerNode() + 1);
TraverseLeaves(std::move(root), 0, 2*nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxChildrenPerInnerNode() + 1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddlePartOfFourLevelTree) {
TEST_F(LeafTraverserTest, TraverseMiddlePartOfFourLevelTree) {
auto root = CreateFourLevel();
//Traverse some leaves of the full threelevel tree in the first child
auto firstChild = LoadInnerNode(root->readChild(0).blockId());
@ -396,14 +404,15 @@ TEST_F(DataTreeTest_TraverseLeaves, TraverseMiddlePartOfFourLevelTree) {
EXPECT_TRAVERSE_LEAF(firstChildOfThirdChild->readChild(i).blockId(), false, 2 * nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode()+i);
}
TraverseLeaves(root.get(), nodeStore->layout().maxChildrenPerInnerNode()+5, 2*nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxChildrenPerInnerNode() -1);
TraverseLeaves(std::move(root), nodeStore->layout().maxChildrenPerInnerNode()+5, 2*nodeStore->layout().maxChildrenPerInnerNode()*nodeStore->layout().maxChildrenPerInnerNode() + nodeStore->layout().maxChildrenPerInnerNode() -1, true);
}
TEST_F(DataTreeTest_TraverseLeaves, LastLeafIsAlreadyResizedInCallback) {
auto root = CreateLeaf();
TEST_F(LeafTraverserTest, LastLeafIsAlreadyResizedInCallback) {
unique_ref<DataNode> root = CreateLeaf();
root->flush();
auto* old_root = root.get();
auto tree = treeStore.load(root->blockId()).value();
tree->traverseLeaves(0, 2, [this] (uint32_t leafIndex, bool /*isRightBorderNode*/, LeafHandle leaf) {
LeafTraverser(nodeStore, false).traverseAndUpdateRoot(&root, 0, 2, [this] (uint32_t leafIndex, bool /*isRightBorderNode*/, LeafHandle leaf) {
if (leafIndex == 0) {
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf(), leaf.node()->numBytes());
} else {
@ -411,28 +420,31 @@ TEST_F(DataTreeTest_TraverseLeaves, LastLeafIsAlreadyResizedInCallback) {
}
}, [] (uint32_t /*nodeIndex*/) -> Data {
return Data(1);
});
}, [] (auto) {});
EXPECT_NE(old_root, root.get()); // expect that we grew the tree
}
TEST_F(DataTreeTest_TraverseLeaves, LastLeafIsAlreadyResizedInCallback_TwoLevel) {
auto root = CreateFullTwoLevelWithLastLeafSize(5);
TEST_F(LeafTraverserTest, LastLeafIsAlreadyResizedInCallback_TwoLevel) {
unique_ref<DataNode> root = CreateFullTwoLevelWithLastLeafSize(5);
root->flush();
auto* old_root = root.get();
auto tree = treeStore.load(root->blockId()).value();
tree->traverseLeaves(0, nodeStore->layout().maxChildrenPerInnerNode()+1, [this] (uint32_t /*leafIndex*/, bool /*isRightBorderNode*/, LeafHandle leaf) {
LeafTraverser(nodeStore, false).traverseAndUpdateRoot(&root, 0, nodeStore->layout().maxChildrenPerInnerNode()+1, [this] (uint32_t /*leafIndex*/, bool /*isRightBorderNode*/, LeafHandle leaf) {
EXPECT_EQ(nodeStore->layout().maxBytesPerLeaf(), leaf.node()->numBytes());
}, [] (uint32_t /*nodeIndex*/) -> Data {
return Data(1);
});
}, [] (auto) {});
EXPECT_NE(old_root, root.get()); // expect that we grew the tree
}
TEST_F(DataTreeTest_TraverseLeaves, ResizeFromOneLeafToMultipleLeaves) {
TEST_F(LeafTraverserTest, ResizeFromOneLeafToMultipleLeaves) {
auto root = CreateLeaf();
EXPECT_TRAVERSE_LEAF(root->blockId(), false, 0);
//EXPECT_CALL(traversor, calledExistingLeaf(_, false, 0)).Times(1);
for (uint32_t i = 1; i < 10; ++i) {
EXPECT_CREATE_LEAF(i);
}
TraverseLeaves(root.get(), 0, 10);
TraverseLeaves(std::move(root), 0, 10, false);
}
//TODO Refactor the test cases that are too long
////TODO Refactor the test cases that are too long