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bitcoin-bitcoin-core/src/dbwrapper.h
Maciej S. Szmigiero b73d331937 dbwrapper: Bump max file size to 32 MiB 
The default max file size for LevelDB is 2 MiB, which results in the
LevelDB compaction code generating ~4 disk cache flushes per second when
syncing with the Bitcoin network.
These disk cache flushes are triggered by fdatasync() syscall issued by the
LevelDB compaction code when reaching the max file size.

If the database is on a HDD this flush rate brings the whole system to a
crawl.
It also results in very slow throughput since 2 MiB * 4 flushes per second
is about 8 MiB / second max throughput, while even an old HDD can pull
100 - 200 MiB / second streaming throughput.

Increase the max file size for LevelDB to 32 MiB instead so the flush rate
drops significantly and the system no longer gets so sluggish.

The new max file size value chosen is a compromise between the one that
works best for HDD and SSD performance, as determined by benchmarks done by
various people.
2024-11-30 20:19:08 +01:00

298 lines
7.8 KiB
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// Copyright (c) 2012-2022 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#ifndef BITCOIN_DBWRAPPER_H
#define BITCOIN_DBWRAPPER_H
#include <attributes.h>
#include <serialize.h>
#include <span.h>
#include <streams.h>
#include <util/check.h>
#include <util/fs.h>
#include <cstddef>
#include <exception>
#include <memory>
#include <optional>
#include <stdexcept>
#include <string>
#include <vector>
static const size_t DBWRAPPER_PREALLOC_KEY_SIZE = 64;
static const size_t DBWRAPPER_PREALLOC_VALUE_SIZE = 1024;
static const size_t DBWRAPPER_MAX_FILE_SIZE = 32 << 20; // 32 MiB
//! User-controlled performance and debug options.
struct DBOptions {
//! Compact database on startup.
bool force_compact = false;
};
//! Application-specific storage settings.
struct DBParams {
//! Location in the filesystem where leveldb data will be stored.
fs::path path;
//! Configures various leveldb cache settings.
size_t cache_bytes;
//! If true, use leveldb's memory environment.
bool memory_only = false;
//! If true, remove all existing data.
bool wipe_data = false;
//! If true, store data obfuscated via simple XOR. If false, XOR with a
//! zero'd byte array.
bool obfuscate = false;
//! Passed-through options.
DBOptions options{};
};
class dbwrapper_error : public std::runtime_error
{
public:
explicit dbwrapper_error(const std::string& msg) : std::runtime_error(msg) {}
};
class CDBWrapper;
/** These should be considered an implementation detail of the specific database.
*/
namespace dbwrapper_private {
/** Work around circular dependency, as well as for testing in dbwrapper_tests.
* Database obfuscation should be considered an implementation detail of the
* specific database.
*/
const std::vector<unsigned char>& GetObfuscateKey(const CDBWrapper &w);
}; // namespace dbwrapper_private
bool DestroyDB(const std::string& path_str);
/** Batch of changes queued to be written to a CDBWrapper */
class CDBBatch
{
friend class CDBWrapper;
private:
const CDBWrapper &parent;
struct WriteBatchImpl;
const std::unique_ptr<WriteBatchImpl> m_impl_batch;
DataStream ssKey{};
DataStream ssValue{};
size_t size_estimate{0};
void WriteImpl(Span<const std::byte> key, DataStream& ssValue);
void EraseImpl(Span<const std::byte> key);
public:
/**
* @param[in] _parent CDBWrapper that this batch is to be submitted to
*/
explicit CDBBatch(const CDBWrapper& _parent);
~CDBBatch();
void Clear();
template <typename K, typename V>
void Write(const K& key, const V& value)
{
ssKey.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssValue.reserve(DBWRAPPER_PREALLOC_VALUE_SIZE);
ssKey << key;
ssValue << value;
WriteImpl(ssKey, ssValue);
ssKey.clear();
ssValue.clear();
}
template <typename K>
void Erase(const K& key)
{
ssKey.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssKey << key;
EraseImpl(ssKey);
ssKey.clear();
}
size_t SizeEstimate() const { return size_estimate; }
};
class CDBIterator
{
public:
struct IteratorImpl;
private:
const CDBWrapper &parent;
const std::unique_ptr<IteratorImpl> m_impl_iter;
void SeekImpl(Span<const std::byte> key);
Span<const std::byte> GetKeyImpl() const;
Span<const std::byte> GetValueImpl() const;
public:
/**
* @param[in] _parent Parent CDBWrapper instance.
* @param[in] _piter The original leveldb iterator.
*/
CDBIterator(const CDBWrapper& _parent, std::unique_ptr<IteratorImpl> _piter);
~CDBIterator();
bool Valid() const;
void SeekToFirst();
template<typename K> void Seek(const K& key) {
DataStream ssKey{};
ssKey.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssKey << key;
SeekImpl(ssKey);
}
void Next();
template<typename K> bool GetKey(K& key) {
try {
DataStream ssKey{GetKeyImpl()};
ssKey >> key;
} catch (const std::exception&) {
return false;
}
return true;
}
template<typename V> bool GetValue(V& value) {
try {
DataStream ssValue{GetValueImpl()};
ssValue.Xor(dbwrapper_private::GetObfuscateKey(parent));
ssValue >> value;
} catch (const std::exception&) {
return false;
}
return true;
}
};
struct LevelDBContext;
class CDBWrapper
{
friend const std::vector<unsigned char>& dbwrapper_private::GetObfuscateKey(const CDBWrapper &w);
private:
//! holds all leveldb-specific fields of this class
std::unique_ptr<LevelDBContext> m_db_context;
//! the name of this database
std::string m_name;
//! a key used for optional XOR-obfuscation of the database
std::vector<unsigned char> obfuscate_key;
//! the key under which the obfuscation key is stored
static const std::string OBFUSCATE_KEY_KEY;
//! the length of the obfuscate key in number of bytes
static const unsigned int OBFUSCATE_KEY_NUM_BYTES;
std::vector<unsigned char> CreateObfuscateKey() const;
//! path to filesystem storage
const fs::path m_path;
//! whether or not the database resides in memory
bool m_is_memory;
std::optional<std::string> ReadImpl(Span<const std::byte> key) const;
bool ExistsImpl(Span<const std::byte> key) const;
size_t EstimateSizeImpl(Span<const std::byte> key1, Span<const std::byte> key2) const;
auto& DBContext() const LIFETIMEBOUND { return *Assert(m_db_context); }
public:
CDBWrapper(const DBParams& params);
~CDBWrapper();
CDBWrapper(const CDBWrapper&) = delete;
CDBWrapper& operator=(const CDBWrapper&) = delete;
template <typename K, typename V>
bool Read(const K& key, V& value) const
{
DataStream ssKey{};
ssKey.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssKey << key;
std::optional<std::string> strValue{ReadImpl(ssKey)};
if (!strValue) {
return false;
}
try {
DataStream ssValue{MakeByteSpan(*strValue)};
ssValue.Xor(obfuscate_key);
ssValue >> value;
} catch (const std::exception&) {
return false;
}
return true;
}
template <typename K, typename V>
bool Write(const K& key, const V& value, bool fSync = false)
{
CDBBatch batch(*this);
batch.Write(key, value);
return WriteBatch(batch, fSync);
}
//! @returns filesystem path to the on-disk data.
std::optional<fs::path> StoragePath() {
if (m_is_memory) {
return {};
}
return m_path;
}
template <typename K>
bool Exists(const K& key) const
{
DataStream ssKey{};
ssKey.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssKey << key;
return ExistsImpl(ssKey);
}
template <typename K>
bool Erase(const K& key, bool fSync = false)
{
CDBBatch batch(*this);
batch.Erase(key);
return WriteBatch(batch, fSync);
}
bool WriteBatch(CDBBatch& batch, bool fSync = false);
// Get an estimate of LevelDB memory usage (in bytes).
size_t DynamicMemoryUsage() const;
CDBIterator* NewIterator();
/**
* Return true if the database managed by this class contains no entries.
*/
bool IsEmpty();
template<typename K>
size_t EstimateSize(const K& key_begin, const K& key_end) const
{
DataStream ssKey1{}, ssKey2{};
ssKey1.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssKey2.reserve(DBWRAPPER_PREALLOC_KEY_SIZE);
ssKey1 << key_begin;
ssKey2 << key_end;
return EstimateSizeImpl(ssKey1, ssKey2);
}
};
#endif // BITCOIN_DBWRAPPER_H
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