osb/source/test/btree_test.cpp

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2023-06-20 04:33:09 +00:00
#include "StarBTree.hpp"
#include "StarString.hpp"
#include "StarMap.hpp"
#include "StarSet.hpp"
#include "StarLexicalCast.hpp"
#include "gtest/gtest.h"
using namespace Star;
using namespace std;
template <typename Key, typename Pointer>
struct SimpleBTreeIndex {
size_t pointerCount() const;
Pointer pointer(size_t i) const;
void updatePointer(size_t i, Pointer p);
Key const& keyBefore(size_t i) const;
void updateKeyBefore(size_t i, Key k);
void removeBefore(size_t i);
void insertAfter(size_t i, Key k, Pointer p);
size_t indexLevel() const;
void setIndexLevel(size_t indexLevel);
// count is number of elements to shift left *including* right's beginPointer
void shiftLeft(Key const& mid, SimpleBTreeIndex& right, size_t count);
// count is number of elements to shift right
void shiftRight(Key const& mid, SimpleBTreeIndex& left, size_t count);
// i should be index of pointer that will be the new beginPointer of right
// node (cannot be 0).
Key split(SimpleBTreeIndex& right, size_t i);
struct Element {
Key key;
Pointer pointer;
};
typedef List<Element> ElementList;
Pointer self;
size_t level;
Maybe<Pointer> beginPointer;
ElementList pointers;
};
template <typename Key, typename Data, typename Pointer>
struct SimpleBTreeLeaf {
size_t count() const;
Key const& key(size_t i) const;
Data const& data(size_t i) const;
void insert(size_t i, Key k, Data d);
void remove(size_t i);
Maybe<Pointer> nextLeaf() const;
void setNextLeaf(Maybe<Pointer> n);
// count is number of elements to shift left
void shiftLeft(SimpleBTreeLeaf& right, size_t count);
// count is number of elements to shift right
void shiftRight(SimpleBTreeLeaf& left, size_t count);
// i should be index of element that will be the new start of right node.
// Returns right index node.
void split(SimpleBTreeLeaf& right, size_t i);
struct Element {
Key key;
Data data;
};
typedef List<Element> ElementList;
Maybe<Pointer> next;
Pointer self;
ElementList elements;
};
template <typename Key, typename Pointer>
size_t SimpleBTreeIndex<Key, Pointer>::pointerCount() const {
// If no begin pointer is set then the index is simply uninitialized.
if (!beginPointer)
return 0;
else
return pointers.size() + 1;
}
template <typename Key, typename Pointer>
Pointer SimpleBTreeIndex<Key, Pointer>::pointer(size_t i) const {
if (i == 0)
return *beginPointer;
else
return pointers.at(i - 1).pointer;
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::updatePointer(size_t i, Pointer p) {
if (i == 0)
*beginPointer = p;
else
pointers.at(i - 1).pointer = p;
}
template <typename Key, typename Pointer>
Key const& SimpleBTreeIndex<Key, Pointer>::keyBefore(size_t i) const {
return pointers.at(i - 1).key;
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::updateKeyBefore(size_t i, Key k) {
pointers.at(i - 1).key = k;
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::removeBefore(size_t i) {
if (i == 0) {
beginPointer = pointers.at(0).pointer;
pointers.eraseAt(0);
} else {
pointers.eraseAt(i - 1);
}
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::insertAfter(size_t i, Key k, Pointer p) {
pointers.insertAt(i, Element{k, p});
}
template <typename Key, typename Pointer>
size_t SimpleBTreeIndex<Key, Pointer>::indexLevel() const {
return level;
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::setIndexLevel(size_t indexLevel) {
level = indexLevel;
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::shiftLeft(Key const& mid, SimpleBTreeIndex& right, size_t count) {
count = std::min(right.pointerCount(), count);
if (count == 0)
return;
pointers.append(Element{mid, *right.beginPointer});
typename ElementList::iterator s = right.pointers.begin();
std::advance(s, count - 1);
pointers.insert(pointers.end(), right.pointers.begin(), s);
right.pointers.erase(right.pointers.begin(), s);
if (right.pointers.size() != 0) {
right.beginPointer = right.pointers.at(0).pointer;
right.pointers.eraseAt(0);
} else {
right.beginPointer.reset();
}
}
template <typename Key, typename Pointer>
void SimpleBTreeIndex<Key, Pointer>::shiftRight(Key const& mid, SimpleBTreeIndex& left, size_t count) {
count = std::min(left.pointerCount(), count);
if (count == 0)
return;
--count;
pointers.insert(pointers.begin(), Element{mid, *beginPointer});
typename ElementList::iterator s = left.pointers.begin();
std::advance(s, left.pointers.size() - count);
pointers.insert(pointers.begin(), s, left.pointers.end());
left.pointers.erase(s, left.pointers.end());
if (left.pointers.size() != 0) {
beginPointer = left.pointers.at(left.pointers.size() - 1).pointer;
left.pointers.eraseAt(left.pointers.size() - 1);
} else {
beginPointer = left.beginPointer.take();
}
}
template <typename Key, typename Pointer>
Key SimpleBTreeIndex<Key, Pointer>::split(SimpleBTreeIndex& right, size_t i) {
typename ElementList::iterator s = pointers.begin();
std::advance(s, i - 1);
right.beginPointer = s->pointer;
Key midKey = s->key;
right.level = level;
++s;
right.pointers.insert(right.pointers.begin(), s, pointers.end());
--s;
pointers.erase(s, pointers.end());
return midKey;
}
template <typename Key, typename Data, typename Pointer>
size_t SimpleBTreeLeaf<Key, Data, Pointer>::count() const {
return elements.size();
}
template <typename Key, typename Data, typename Pointer>
Key const& SimpleBTreeLeaf<Key, Data, Pointer>::key(size_t i) const {
return elements.at(i).key;
}
template <typename Key, typename Data, typename Pointer>
Data const& SimpleBTreeLeaf<Key, Data, Pointer>::data(size_t i) const {
return elements.at(i).data;
}
template <typename Key, typename Data, typename Pointer>
void SimpleBTreeLeaf<Key, Data, Pointer>::insert(size_t i, Key k, Data d) {
elements.insertAt(i, Element{move(k), move(d)});
}
template <typename Key, typename Data, typename Pointer>
void SimpleBTreeLeaf<Key, Data, Pointer>::remove(size_t i) {
elements.eraseAt(i);
}
template <typename Key, typename Data, typename Pointer>
void SimpleBTreeLeaf<Key, Data, Pointer>::shiftLeft(SimpleBTreeLeaf& right, size_t count) {
count = std::min(right.count(), count);
if (count == 0)
return;
typename ElementList::iterator s = right.elements.begin();
std::advance(s, count);
elements.insert(elements.end(), right.elements.begin(), s);
right.elements.erase(right.elements.begin(), s);
}
template <typename Key, typename Data, typename Pointer>
void SimpleBTreeLeaf<Key, Data, Pointer>::shiftRight(SimpleBTreeLeaf& left, size_t count) {
count = std::min(left.count(), count);
if (count == 0)
return;
typename ElementList::iterator s = left.elements.begin();
std::advance(s, left.elements.size() - count);
elements.insert(elements.begin(), s, left.elements.end());
left.elements.erase(s, left.elements.end());
}
template <typename Key, typename Data, typename Pointer>
void SimpleBTreeLeaf<Key, Data, Pointer>::split(SimpleBTreeLeaf& right, size_t i) {
typename ElementList::iterator s = elements.begin();
std::advance(s, i);
right.elements.insert(right.elements.begin(), s, elements.end());
elements.erase(s, elements.end());
}
template <typename Key, typename Data, typename Pointer>
Maybe<Pointer> SimpleBTreeLeaf<Key, Data, Pointer>::nextLeaf() const {
return next;
}
template <typename Key, typename Data, typename Pointer>
void SimpleBTreeLeaf<Key, Data, Pointer>::setNextLeaf(Maybe<Pointer> n) {
next = move(n);
}
// Testing BTree class that simulates storage by storing in-memory copies of
// nodes. Used to test BTree algorithm.
struct SimpleBTreeBase {
typedef int Key;
typedef String Data;
typedef int Pointer;
typedef SimpleBTreeIndex<int, int> Index;
typedef SimpleBTreeLeaf<int, String, int> Leaf;
Pointer rootPointer() {
return root;
}
bool rootIsLeaf() {
return rootleaf;
}
void setNewRoot(Pointer pointer, bool isLeaf) {
root = pointer;
rootleaf = isLeaf;
for (int i : deletedLeaves)
leaves.remove(i);
for (int i : deletedIndexes)
indexes.remove(i);
deletedLeaves.clear();
deletedIndexes.clear();
}
// Should create new empty leaf.
Leaf createLeaf() {
Leaf leaf;
leaf.self = -1;
return leaf;
}
Leaf loadLeaf(Pointer const& pointer) {
// To make sure to accurately test storage, always *copy* in and out
return leaves.get(pointer);
}
bool leafNeedsShift(Leaf const& leaf) {
return leaf.count() < (maxLeafSize + 1) / 2;
}
bool shouldAppendNewLeaf(Leaf const& leaf) {
return maxLeafSize == 2 && leaf.count() == 2;
}
bool leafShift(Leaf& left, Leaf& right) {
if (left.count() + right.count() <= maxLeafSize) {
left.shiftLeft(right, right.count());
return true;
} else {
if (leafNeedsShift(right)) {
right.shiftRight(left, 1);
return true;
} else if (leafNeedsShift(left)) {
left.shiftLeft(right, 1);
return true;
} else {
return false;
}
}
}
Maybe<Leaf> leafSplit(Leaf& leaf) {
if (leaf.count() <= maxLeafSize) {
return {};
} else {
Leaf right;
right.self = -1;
leaf.split(right, (leaf.count() + 1) / 2);
return right;
}
}
Pointer storeLeaf(Leaf leaf) {
if (leaf.self != -1)
deleteLeaf(leaf);
while (leaves.contains(leafId))
++leafId;
leaf.self = leafId;
// To make sure to accurately test storage, always *copy* in and out
leaves[leafId] = leaf;
return leaf.self;
}
void deleteLeaf(Leaf const& leaf) {
deletedLeaves.append(leaf.self);
}
// Should create new index with two pointers and one mid key.
Index createIndex(Pointer beginPointer) {
Index indexNode;
indexNode.self = -1;
indexNode.level = 0;
indexNode.beginPointer = beginPointer;
return indexNode;
}
Index loadIndex(Pointer const& pointer) {
return indexes.get(pointer);
}
bool indexNeedsShift(Index const& index) {
return index.pointerCount() < (maxIndexSize + 1) / 2;
}
bool indexShift(Index& left, Key const& mid, Index& right) {
if (left.pointerCount() + right.pointerCount() <= maxIndexSize) {
left.shiftLeft(mid, right, right.pointerCount());
return true;
} else {
if (indexNeedsShift(right)) {
right.shiftRight(mid, left, 1);
return true;
} else if (indexNeedsShift(left)) {
left.shiftLeft(mid, right, 1);
return true;
} else {
return false;
}
}
}
Maybe<pair<Key, Index>> indexSplit(Index& index) {
if (index.pointerCount() <= maxIndexSize) {
return {};
} else {
Index right;
right.self = -1;
Key mid = index.split(right, (index.pointerCount() + 1) / 2);
return make_pair(mid, right);
}
}
Pointer storeIndex(Index index) {
if (index.self != -1)
deleteIndex(index);
while (indexes.contains(indexId))
++indexId;
index.self = indexId;
indexes[indexId] = index;
return index.self;
}
void deleteIndex(Index const& index) {
deletedIndexes.append(index.self);
}
size_t indexPointerCount(Index const& index) {
return index.pointerCount();
}
Pointer indexPointer(Index const& index, size_t i) {
return index.pointer(i);
}
void indexUpdatePointer(Index& index, size_t i, Pointer p) {
index.updatePointer(i, p);
}
Key indexKeyBefore(Index const& index, size_t i) {
return index.keyBefore(i);
}
void indexUpdateKeyBefore(Index& index, size_t i, Key k) {
index.updateKeyBefore(i, k);
}
void indexRemoveBefore(Index& index, size_t i) {
index.removeBefore(i);
}
void indexInsertAfter(Index& index, size_t i, Key k, Pointer p) {
index.insertAfter(i, k, p);
}
size_t indexLevel(Index const& index) {
return index.indexLevel();
}
void setIndexLevel(Index& index, size_t indexLevel) {
index.setIndexLevel(indexLevel);
}
size_t leafElementCount(Leaf const& leaf) {
return leaf.count();
}
Key leafKey(Leaf const& leaf, size_t i) {
return leaf.key(i);
}
Data leafData(Leaf const& leaf, size_t i) {
return leaf.data(i);
}
void leafInsert(Leaf& leaf, size_t i, Key k, Data d) {
return leaf.insert(i, k, d);
}
void leafRemove(Leaf& leaf, size_t i) {
return leaf.remove(i);
}
Maybe<Pointer> nextLeaf(Leaf const& leaf) {
return leaf.nextLeaf();
}
void setNextLeaf(Leaf& leaf, Maybe<Pointer> n) {
leaf.setNextLeaf(n);
}
int root;
bool rootleaf;
size_t maxIndexSize;
size_t maxLeafSize;
int indexId;
int leafId;
Map<int, Index> indexes;
Map<int, Leaf> leaves;
List<int> deletedLeaves;
List<int> deletedIndexes;
};
struct SimpleBTree : public BTreeMixin<SimpleBTreeBase> {
SimpleBTree(size_t maxisize, size_t maxlsize) {
maxIndexSize = maxisize;
maxLeafSize = maxlsize;
leafId = 0;
indexId = 0;
createNewRoot();
}
void print() {
forAllNodes(Printer());
cout << endl;
}
struct Printer {
bool operator()(Index const& index) {
cout << "[" << index.level << ":" << index.self << "]"
<< " " << index.beginPointer << " ";
for (Index::Element e : index.pointers) {
cout << "(" << e.key << ")"
<< " " << e.pointer << " ";
}
cout << endl;
return true;
}
bool operator()(Leaf const& leaf) {
cout << "[" << leaf.self << "]"
<< " ";
for (Leaf::Element e : leaf.elements) {
cout << "(" << e.key << ")"
<< " " << e.data << " ";
}
cout << endl;
return true;
}
};
};
const int RandFactor = 0xd5a2f037;
const size_t TestCount = 500;
const size_t WriteRepeat = 3;
const size_t ShrinkCount = 5;
String genValue(int k) {
return toString(k * RandFactor);
}
bool checkValue(int k, String v) {
return genValue(k) == v;
}
void putAll(SimpleBTree& db, List<int> keys) {
for (int k : keys)
db.insert(k, genValue(k));
}
void checkAll(SimpleBTree& db, List<int> keys) {
for (int k : keys) {
auto v = db.find(k);
EXPECT_TRUE(checkValue(k, *v));
}
}
size_t removeAll(SimpleBTree& db, List<int> keys) {
size_t totalRemoved = 0;
Set<int> removed;
for (int k : keys) {
if (db.remove(k)) {
EXPECT_FALSE(removed.contains(k));
removed.add(k);
++totalRemoved;
}
}
return totalRemoved;
}
void testBTree(size_t maxIndexSize, size_t maxLeafSize) {
srand(time(0));
SimpleBTree db(maxIndexSize, maxLeafSize);
Set<int> keySet;
while (keySet.size() < TestCount)
keySet.add(rand());
List<int> keys;
for (int k : keySet) {
for (size_t j = 0; j < WriteRepeat; ++j)
keys.append(k);
}
// record writes/reads repeated WriteRepeat times randomly each cycle
std::random_shuffle(keys.begin(), keys.end());
putAll(db, keys);
EXPECT_EQ(db.recordCount(), TestCount);
std::random_shuffle(keys.begin(), keys.end());
checkAll(db, keys);
// Random reads/writes with ShrinkCount cycles...
for (size_t i = 0; i < ShrinkCount; ++i) {
std::random_shuffle(keys.begin(), keys.end());
List<int> keysTemp = keys.slice(0, keys.size() / 2);
removeAll(db, keysTemp);
std::random_shuffle(keysTemp.begin(), keysTemp.end());
putAll(db, keysTemp);
std::random_shuffle(keysTemp.begin(), keysTemp.end());
checkAll(db, keys);
}
size_t totalRemoved = removeAll(db, keys);
EXPECT_EQ(totalRemoved, TestCount);
}
TEST(BTreeTest, All) {
testBTree(3, 2);
testBTree(6, 6);
}