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| author | Douglas B. Rumbaugh <dbr4@psu.edu> | 2024-12-06 13:13:51 -0500 |
|---|---|---|
| committer | GitHub <noreply@github.com> | 2024-12-06 18:13:51 +0000 |
| commit | 9fe305c7d28e993e55c55427f377ae7e3251ea4f (patch) | |
| tree | 384b687f64b84eb81bde2becac8a5f24916b07b4 /include/shard/ISAMTree.h | |
| parent | 47916da2ba5ed5bee2dda3cbcc58d39e1e931bfc (diff) | |
| download | dynamic-extension-9fe305c7d28e993e55c55427f377ae7e3251ea4f.tar.gz | |
Interface update (#5)
* Query Interface Adjustments/Refactoring
Began the process of adjusting the query interface (and also the shard
interface, to a lesser degree) to better accommodate the user. In
particular the following changes have been made,
1. The number of necessary template arguments for the query type
has been drastically reduced, while also removing the void pointers
and manual delete functions from the interface.
This was accomplished by requiring many of the sub-types associated
with a query (parameters, etc.) to be nested inside the main query
class, and by forcing the SHARD type to expose its associated
record type.
2. User-defined query return types are now supported.
Queries no longer are required to return strictly sets of records.
Instead, the query now has LocalResultType and ResultType
template parameters (which can be defaulted using a typedef in
the Query type itself), allowing much more flexibility.
Note that, at least for the short term, the LocalResultType must
still expose the same is_deleted/is_tombstone interface as a
Wrapped<R> used to, as this is currently needed for delete
filtering. A better approach to this is, hopefully, forthcoming.
3. Updated the ISAMTree.h shard and rangequery.h query to use the
new interfaces, and adjusted the associated unit tests as well.
4. Dropped the unnecessary "get_data()" function from the ShardInterface
concept.
5. Dropped the need to specify a record type in the ShardInterface
concept. This is now handled using a required Shard::RECORD
member of the Shard class itself, which should expose the name
of the record type.
* Updates to framework to support new Query/Shard interfaces
Pretty extensive adjustments to the framework, particularly to the
templates themselves, along with some type-renaming work, to support
the new query and shard interfaces.
Adjusted the external query interface to take an rvalue reference, rather
than a pointer, to the query parameters.
* Removed framework-level delete filtering
This was causing some issues with the new query interface, and should
probably be reworked anyway, so I'm temporarily (TM) removing the
feature.
* Updated benchmarks + remaining code for new interface
Diffstat (limited to 'include/shard/ISAMTree.h')
| -rw-r--r-- | include/shard/ISAMTree.h | 402 |
1 files changed, 195 insertions, 207 deletions
diff --git a/include/shard/ISAMTree.h b/include/shard/ISAMTree.h index 1cca506..64c0b2b 100644 --- a/include/shard/ISAMTree.h +++ b/include/shard/ISAMTree.h @@ -1,8 +1,8 @@ /* * include/shard/ISAMTree.h * - * Copyright (C) 2023 Douglas B. Rumbaugh <drumbaugh@psu.edu> - * Dong Xie <dongx@psu.edu> + * Copyright (C) 2023-2024 Douglas B. Rumbaugh <drumbaugh@psu.edu> + * Dong Xie <dongx@psu.edu> * * Distributed under the Modified BSD License. * @@ -12,258 +12,246 @@ */ #pragma once -#include <vector> #include <cassert> +#include <vector> #include "framework/ShardRequirements.h" -#include "util/bf_config.h" #include "psu-ds/BloomFilter.h" #include "util/SortedMerge.h" +#include "util/bf_config.h" -using psudb::CACHELINE_SIZE; using psudb::BloomFilter; -using psudb::PriorityQueue; -using psudb::queue_record; using psudb::byte; +using psudb::CACHELINE_SIZE; namespace de { -template <KVPInterface R> -class ISAMTree { +template <KVPInterface R> class ISAMTree { private: + typedef decltype(R::key) K; + typedef decltype(R::value) V; -typedef decltype(R::key) K; -typedef decltype(R::value) V; - -constexpr static size_t NODE_SZ = 256; -constexpr static size_t INTERNAL_FANOUT = NODE_SZ / (sizeof(K) + sizeof(byte*)); + constexpr static size_t NODE_SZ = 256; + constexpr static size_t INTERNAL_FANOUT = + NODE_SZ / (sizeof(K) + sizeof(byte *)); -struct InternalNode { + struct InternalNode { K keys[INTERNAL_FANOUT]; - byte* child[INTERNAL_FANOUT]; -}; - -static_assert(sizeof(InternalNode) == NODE_SZ, "node size does not match"); + byte *child[INTERNAL_FANOUT]; + }; -constexpr static size_t LEAF_FANOUT = NODE_SZ / sizeof(R); + static_assert(sizeof(InternalNode) == NODE_SZ, "node size does not match"); + constexpr static size_t LEAF_FANOUT = NODE_SZ / sizeof(R); public: - ISAMTree(BufferView<R> buffer) - : m_bf(nullptr) - , m_isam_nodes(nullptr) - , m_root(nullptr) - , m_reccnt(0) - , m_tombstone_cnt(0) - , m_internal_node_cnt(0) - , m_deleted_cnt(0) - , m_alloc_size(0) - { - m_alloc_size = psudb::sf_aligned_alloc(CACHELINE_SIZE, - buffer.get_record_count() * - sizeof(Wrapped<R>), - (byte**) &m_data); - - auto res = sorted_array_from_bufferview(std::move(buffer), m_data, m_bf); - m_reccnt = res.record_count; - m_tombstone_cnt = res.tombstone_count; - - if (m_reccnt > 0) { - build_internal_levels(); - } + typedef R RECORD; + + ISAMTree(BufferView<R> buffer) + : m_bf(nullptr), m_isam_nodes(nullptr), m_root(nullptr), m_reccnt(0), + m_tombstone_cnt(0), m_internal_node_cnt(0), m_deleted_cnt(0), + m_alloc_size(0) { + m_alloc_size = psudb::sf_aligned_alloc( + CACHELINE_SIZE, buffer.get_record_count() * sizeof(Wrapped<R>), + (byte **)&m_data); + + auto res = sorted_array_from_bufferview(std::move(buffer), m_data, m_bf); + m_reccnt = res.record_count; + m_tombstone_cnt = res.tombstone_count; + + if (m_reccnt > 0) { + build_internal_levels(); + } + } + + ISAMTree(std::vector<ISAMTree *> const &shards) + : m_bf(nullptr), m_isam_nodes(nullptr), m_root(nullptr), m_reccnt(0), + m_tombstone_cnt(0), m_internal_node_cnt(0), m_deleted_cnt(0), + m_alloc_size(0) { + size_t attemp_reccnt = 0; + size_t tombstone_count = 0; + auto cursors = + build_cursor_vec<R, ISAMTree>(shards, &attemp_reccnt, &tombstone_count); + + m_bf = nullptr; + m_alloc_size = psudb::sf_aligned_alloc( + CACHELINE_SIZE, attemp_reccnt * sizeof(Wrapped<R>), (byte **)&m_data); + + auto res = sorted_array_merge<R>(cursors, m_data, m_bf); + m_reccnt = res.record_count; + m_tombstone_cnt = res.tombstone_count; + + if (m_reccnt > 0) { + build_internal_levels(); } + } - ISAMTree(std::vector<ISAMTree*> &shards) - : m_bf(nullptr) - , m_isam_nodes(nullptr) - , m_root(nullptr) - , m_reccnt(0) - , m_tombstone_cnt(0) - , m_internal_node_cnt(0) - , m_deleted_cnt(0) - , m_alloc_size(0) - { - size_t attemp_reccnt = 0; - size_t tombstone_count = 0; - auto cursors = build_cursor_vec<R, ISAMTree>(shards, &attemp_reccnt, &tombstone_count); - - m_bf = nullptr; - m_alloc_size = psudb::sf_aligned_alloc(CACHELINE_SIZE, - attemp_reccnt * sizeof(Wrapped<R>), - (byte **) &m_data); - - auto res = sorted_array_merge<R>(cursors, m_data, m_bf); - m_reccnt = res.record_count; - m_tombstone_cnt = res.tombstone_count; - - if (m_reccnt > 0) { - build_internal_levels(); - } + ~ISAMTree() { + free(m_data); + free(m_isam_nodes); + delete m_bf; + } + + Wrapped<R> *point_lookup(const R &rec, bool filter = false) { + if (filter && !m_bf->lookup(rec)) { + return nullptr; } - ~ISAMTree() { - free(m_data); - free(m_isam_nodes); - delete m_bf; + size_t idx = get_lower_bound(rec.key); + if (idx >= m_reccnt) { + return nullptr; } - Wrapped<R> *point_lookup(const R &rec, bool filter=false) { - if (filter && !m_bf->lookup(rec)) { - return nullptr; - } + while (idx < m_reccnt && m_data[idx].rec < rec) + ++idx; - size_t idx = get_lower_bound(rec.key); - if (idx >= m_reccnt) { - return nullptr; - } + if (m_data[idx].rec == rec) { + return m_data + idx; + } - while (idx < m_reccnt && m_data[idx].rec < rec) ++idx; + return nullptr; + } - if (m_data[idx].rec == rec) { - return m_data + idx; - } + Wrapped<R> *get_data() const { return m_data; } - return nullptr; - } + size_t get_record_count() const { return m_reccnt; } - Wrapped<R>* get_data() const { - return m_data; - } - - size_t get_record_count() const { - return m_reccnt; - } + size_t get_tombstone_count() const { return m_tombstone_cnt; } - size_t get_tombstone_count() const { - return m_tombstone_cnt; - } + size_t get_memory_usage() const { return m_internal_node_cnt * NODE_SZ; } + size_t get_aux_memory_usage() const { return (m_bf) ? m_bf->memory_usage() : 0; } - size_t get_memory_usage() { - return m_internal_node_cnt * NODE_SZ; - } + /* SortedShardInterface methods */ + size_t get_lower_bound(const K &key) const { + const InternalNode *now = m_root; + while (!is_leaf(reinterpret_cast<const byte *>(now))) { + const InternalNode *next = nullptr; + for (size_t i = 0; i < INTERNAL_FANOUT - 1; ++i) { + if (now->child[i + 1] == nullptr || key <= now->keys[i]) { + next = reinterpret_cast<InternalNode *>(now->child[i]); + break; + } + } - size_t get_aux_memory_usage() { - return (m_bf) ? m_bf->memory_usage() : 0; + now = next ? next + : reinterpret_cast<const InternalNode *>( + now->child[INTERNAL_FANOUT - 1]); } - /* SortedShardInterface methods */ - size_t get_lower_bound(const K& key) const { - const InternalNode* now = m_root; - while (!is_leaf(reinterpret_cast<const byte*>(now))) { - const InternalNode* next = nullptr; - for (size_t i = 0; i < INTERNAL_FANOUT - 1; ++i) { - if (now->child[i + 1] == nullptr || key <= now->keys[i]) { - next = reinterpret_cast<InternalNode*>(now->child[i]); - break; - } - } - - now = next ? next : reinterpret_cast<const InternalNode*>(now->child[INTERNAL_FANOUT - 1]); + const Wrapped<R> *pos = reinterpret_cast<const Wrapped<R> *>(now); + while (pos < m_data + m_reccnt && pos->rec.key < key) + pos++; + + return pos - m_data; + } + + size_t get_upper_bound(const K &key) const { + const InternalNode *now = m_root; + while (!is_leaf(reinterpret_cast<const byte *>(now))) { + const InternalNode *next = nullptr; + for (size_t i = 0; i < INTERNAL_FANOUT - 1; ++i) { + if (now->child[i + 1] == nullptr || key < now->keys[i]) { + next = reinterpret_cast<InternalNode *>(now->child[i]); + break; } + } - const Wrapped<R>* pos = reinterpret_cast<const Wrapped<R>*>(now); - while (pos < m_data + m_reccnt && pos->rec.key < key) pos++; - - return pos - m_data; + now = next ? next + : reinterpret_cast<const InternalNode *>( + now->child[INTERNAL_FANOUT - 1]); } - size_t get_upper_bound(const K& key) const { - const InternalNode* now = m_root; - while (!is_leaf(reinterpret_cast<const byte*>(now))) { - const InternalNode* next = nullptr; - for (size_t i = 0; i < INTERNAL_FANOUT - 1; ++i) { - if (now->child[i + 1] == nullptr || key < now->keys[i]) { - next = reinterpret_cast<InternalNode*>(now->child[i]); - break; - } - } - - now = next ? next : reinterpret_cast<const InternalNode*>(now->child[INTERNAL_FANOUT - 1]); - } - - const Wrapped<R>* pos = reinterpret_cast<const Wrapped<R>*>(now); - while (pos < m_data + m_reccnt && pos->rec.key <= key) pos++; + const Wrapped<R> *pos = reinterpret_cast<const Wrapped<R> *>(now); + while (pos < m_data + m_reccnt && pos->rec.key <= key) + pos++; - return pos - m_data; - } + return pos - m_data; + } - const Wrapped<R>* get_record_at(size_t idx) const { - return (idx < m_reccnt) ? m_data + idx : nullptr; - } + const Wrapped<R> *get_record_at(size_t idx) const { + return (idx < m_reccnt) ? m_data + idx : nullptr; + } private: - void build_internal_levels() { - size_t n_leaf_nodes = m_reccnt / LEAF_FANOUT + (m_reccnt % LEAF_FANOUT != 0); - - size_t level_node_cnt = n_leaf_nodes; - size_t node_cnt = 0; - do { - level_node_cnt = level_node_cnt / INTERNAL_FANOUT + (level_node_cnt % INTERNAL_FANOUT != 0); - node_cnt += level_node_cnt; - } while (level_node_cnt > 1); - - m_alloc_size += psudb::sf_aligned_calloc(CACHELINE_SIZE, node_cnt, NODE_SZ, (byte**) &m_isam_nodes); - m_internal_node_cnt = node_cnt; - - InternalNode* current_node = m_isam_nodes; - - const Wrapped<R>* leaf_base = m_data; - const Wrapped<R>* leaf_stop = m_data + m_reccnt; - while (leaf_base < leaf_stop) { - size_t fanout = 0; - for (size_t i = 0; i < INTERNAL_FANOUT; ++i) { - auto rec_ptr = leaf_base + LEAF_FANOUT * i; - if (rec_ptr >= leaf_stop) break; - const Wrapped<R>* sep_key = std::min(rec_ptr + LEAF_FANOUT - 1, leaf_stop - 1); - current_node->keys[i] = sep_key->rec.key; - current_node->child[i] = (byte*)rec_ptr; - ++fanout; - } - current_node++; - leaf_base += fanout * LEAF_FANOUT; - } - - auto level_start = m_isam_nodes; - auto level_stop = current_node; - auto current_level_node_cnt = level_stop - level_start; - while (current_level_node_cnt > 1) { - auto now = level_start; - while (now < level_stop) { - size_t child_cnt = 0; - for (size_t i = 0; i < INTERNAL_FANOUT; ++i) { - auto node_ptr = now + i; - ++child_cnt; - if (node_ptr >= level_stop) break; - current_node->keys[i] = node_ptr->keys[INTERNAL_FANOUT - 1]; - current_node->child[i] = (byte*)node_ptr; - } - now += child_cnt; - current_node++; - } - level_start = level_stop; - level_stop = current_node; - current_level_node_cnt = level_stop - level_start; - } - - assert(current_level_node_cnt == 1); - m_root = level_start; + void build_internal_levels() { + size_t n_leaf_nodes = + m_reccnt / LEAF_FANOUT + (m_reccnt % LEAF_FANOUT != 0); + + size_t level_node_cnt = n_leaf_nodes; + size_t node_cnt = 0; + do { + level_node_cnt = level_node_cnt / INTERNAL_FANOUT + + (level_node_cnt % INTERNAL_FANOUT != 0); + node_cnt += level_node_cnt; + } while (level_node_cnt > 1); + + m_alloc_size += psudb::sf_aligned_calloc(CACHELINE_SIZE, node_cnt, NODE_SZ, + (byte **)&m_isam_nodes); + m_internal_node_cnt = node_cnt; + + InternalNode *current_node = m_isam_nodes; + + const Wrapped<R> *leaf_base = m_data; + const Wrapped<R> *leaf_stop = m_data + m_reccnt; + while (leaf_base < leaf_stop) { + size_t fanout = 0; + for (size_t i = 0; i < INTERNAL_FANOUT; ++i) { + auto rec_ptr = leaf_base + LEAF_FANOUT * i; + if (rec_ptr >= leaf_stop) + break; + const Wrapped<R> *sep_key = + std::min(rec_ptr + LEAF_FANOUT - 1, leaf_stop - 1); + current_node->keys[i] = sep_key->rec.key; + current_node->child[i] = (byte *)rec_ptr; + ++fanout; + } + current_node++; + leaf_base += fanout * LEAF_FANOUT; } - bool is_leaf(const byte* ptr) const { - return ptr >= (const byte*)m_data && ptr < (const byte*)(m_data + m_reccnt); + auto level_start = m_isam_nodes; + auto level_stop = current_node; + auto current_level_node_cnt = level_stop - level_start; + while (current_level_node_cnt > 1) { + auto now = level_start; + while (now < level_stop) { + size_t child_cnt = 0; + for (size_t i = 0; i < INTERNAL_FANOUT; ++i) { + auto node_ptr = now + i; + ++child_cnt; + if (node_ptr >= level_stop) + break; + current_node->keys[i] = node_ptr->keys[INTERNAL_FANOUT - 1]; + current_node->child[i] = (byte *)node_ptr; + } + now += child_cnt; + current_node++; + } + level_start = level_stop; + level_stop = current_node; + current_level_node_cnt = level_stop - level_start; } - psudb::BloomFilter<R> *m_bf; - InternalNode* m_isam_nodes; - InternalNode* m_root; - size_t m_reccnt; - size_t m_tombstone_cnt; - size_t m_internal_node_cnt; - size_t m_deleted_cnt; - size_t m_alloc_size; - - Wrapped<R>* m_data; + assert(current_level_node_cnt == 1); + m_root = level_start; + } + + bool is_leaf(const byte *ptr) const { + return ptr >= (const byte *)m_data && + ptr < (const byte *)(m_data + m_reccnt); + } + + psudb::BloomFilter<R> *m_bf; + InternalNode *m_isam_nodes; + InternalNode *m_root; + size_t m_reccnt; + size_t m_tombstone_cnt; + size_t m_internal_node_cnt; + size_t m_deleted_cnt; + size_t m_alloc_size; + + Wrapped<R> *m_data; }; -} +} // namespace de |