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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.
#include <dbwrapper.h>
#include <clientversion.h>
#include <logging.h>
#include <random.h>
#include <serialize.h>
#include <span.h>
#include <streams.h>
#include <util/fs.h>
#include <util/fs_helpers.h>
#include <util/strencodings.h>
#include <algorithm>
#include <cassert>
#include <cstdarg>
#include <cstdint>
#include <cstdio>
#include <leveldb/cache.h>
#include <leveldb/db.h>
#include <leveldb/env.h>
#include <leveldb/filter_policy.h>
#include <leveldb/helpers/memenv/memenv.h>
#include <leveldb/iterator.h>
#include <leveldb/options.h>
#include <leveldb/slice.h>
#include <leveldb/status.h>
#include <leveldb/write_batch.h>
#include <memory>
#include <optional>
#include <utility>
static auto CharCast(const std::byte* data) { return reinterpret_cast<const char*>(data); }
bool DestroyDB(const std::string& path_str)
{
return leveldb::DestroyDB(path_str, {}).ok();
}
/** Handle database error by throwing dbwrapper_error exception.
*/
static void HandleError(const leveldb::Status& status)
{
if (status.ok())
return;
const std::string errmsg = "Fatal LevelDB error: " + status.ToString();
LogPrintf("%s\n", errmsg);
LogPrintf("You can use -debug=leveldb to get more complete diagnostic messages\n");
throw dbwrapper_error(errmsg);
}
class CBitcoinLevelDBLogger : public leveldb::Logger {
public:
// This code is adapted from posix_logger.h, which is why it is using vsprintf.
// Please do not do this in normal code
void Logv(const char * format, va_list ap) override {
if (!LogAcceptCategory(BCLog::LEVELDB, BCLog::Level::Debug)) {
return;
}
char buffer[500];
for (int iter = 0; iter < 2; iter++) {
char* base;
int bufsize;
if (iter == 0) {
bufsize = sizeof(buffer);
base = buffer;
}
else {
bufsize = 30000;
base = new char[bufsize];
}
char* p = base;
char* limit = base + bufsize;
// Print the message
if (p < limit) {
va_list backup_ap;
va_copy(backup_ap, ap);
// Do not use vsnprintf elsewhere in bitcoin source code, see above.
p += vsnprintf(p, limit - p, format, backup_ap);
va_end(backup_ap);
}
// Truncate to available space if necessary
if (p >= limit) {
if (iter == 0) {
continue; // Try again with larger buffer
}
else {
p = limit - 1;
}
}
// Add newline if necessary
if (p == base || p[-1] != '\n') {
*p++ = '\n';
}
assert(p <= limit);
base[std::min(bufsize - 1, (int)(p - base))] = '\0';
LogPrintLevel(BCLog::LEVELDB, BCLog::Level::Debug, "%s", base); /* Continued */
if (base != buffer) {
delete[] base;
}
break;
}
}
};
static void SetMaxOpenFiles(leveldb::Options *options) {
// On most platforms the default setting of max_open_files (which is 1000)
// is optimal. On Windows using a large file count is OK because the handles
// do not interfere with select() loops. On 64-bit Unix hosts this value is
// also OK, because up to that amount LevelDB will use an mmap
// implementation that does not use extra file descriptors (the fds are
// closed after being mmap'ed).
//
// Increasing the value beyond the default is dangerous because LevelDB will
// fall back to a non-mmap implementation when the file count is too large.
// On 32-bit Unix host we should decrease the value because the handles use
// up real fds, and we want to avoid fd exhaustion issues.
//
// See PR #12495 for further discussion.
int default_open_files = options->max_open_files;
#ifndef WIN32
if (sizeof(void*) < 8) {
options->max_open_files = 64;
}
#endif
LogPrint(BCLog::LEVELDB, "LevelDB using max_open_files=%d (default=%d)\n",
options->max_open_files, default_open_files);
}
static leveldb::Options GetOptions(size_t nCacheSize)
{
leveldb::Options options;
options.block_cache = leveldb::NewLRUCache(nCacheSize / 2);
options.write_buffer_size = nCacheSize / 4; // up to two write buffers may be held in memory simultaneously
options.filter_policy = leveldb::NewBloomFilterPolicy(10);
options.compression = leveldb::kNoCompression;
options.info_log = new CBitcoinLevelDBLogger();
if (leveldb::kMajorVersion > 1 || (leveldb::kMajorVersion == 1 && leveldb::kMinorVersion >= 16)) {
// LevelDB versions before 1.16 consider short writes to be corruption. Only trigger error
// on corruption in later versions.
options.paranoid_checks = true;
}
SetMaxOpenFiles(&options);
return options;
}
struct CDBBatch::WriteBatchImpl {
leveldb::WriteBatch batch;
};
CDBBatch::CDBBatch(const CDBWrapper& _parent) : parent(_parent),
m_impl_batch{std::make_unique<CDBBatch::WriteBatchImpl>()},
ssValue(SER_DISK, CLIENT_VERSION){};
CDBBatch::~CDBBatch() = default;
void CDBBatch::Clear()
{
m_impl_batch->batch.Clear();
size_estimate = 0;
}
void CDBBatch::WriteImpl(Span<const std::byte> ssKey, CDataStream& ssValue)
{
leveldb::Slice slKey(CharCast(ssKey.data()), ssKey.size());
ssValue.Xor(dbwrapper_private::GetObfuscateKey(parent));
leveldb::Slice slValue(CharCast(ssValue.data()), ssValue.size());
m_impl_batch->batch.Put(slKey, slValue);
// LevelDB serializes writes as:
// - byte: header
// - varint: key length (1 byte up to 127B, 2 bytes up to 16383B, ...)
// - byte[]: key
// - varint: value length
// - byte[]: value
// The formula below assumes the key and value are both less than 16k.
size_estimate += 3 + (slKey.size() > 127) + slKey.size() + (slValue.size() > 127) + slValue.size();
}
void CDBBatch::EraseImpl(Span<const std::byte> ssKey)
{
leveldb::Slice slKey(CharCast(ssKey.data()), ssKey.size());
m_impl_batch->batch.Delete(slKey);
// LevelDB serializes erases as:
// - byte: header
// - varint: key length
// - byte[]: key
// The formula below assumes the key is less than 16kB.
size_estimate += 2 + (slKey.size() > 127) + slKey.size();
}
CDBWrapper::CDBWrapper(const DBParams& params)
: m_name{fs::PathToString(params.path.stem())}, m_path{params.path}, m_is_memory{params.memory_only}
{
penv = nullptr;
readoptions.verify_checksums = true;
iteroptions.verify_checksums = true;
iteroptions.fill_cache = false;
syncoptions.sync = true;
options = GetOptions(params.cache_bytes);
options.create_if_missing = true;
if (params.memory_only) {
penv = leveldb::NewMemEnv(leveldb::Env::Default());
options.env = penv;
} else {
if (params.wipe_data) {
LogPrintf("Wiping LevelDB in %s\n", fs::PathToString(params.path));
leveldb::Status result = leveldb::DestroyDB(fs::PathToString(params.path), options);
HandleError(result);
}
TryCreateDirectories(params.path);
LogPrintf("Opening LevelDB in %s\n", fs::PathToString(params.path));
}
// PathToString() return value is safe to pass to leveldb open function,
// because on POSIX leveldb passes the byte string directly to ::open(), and
// on Windows it converts from UTF-8 to UTF-16 before calling ::CreateFileW
// (see env_posix.cc and env_windows.cc).
leveldb::Status status = leveldb::DB::Open(options, fs::PathToString(params.path), &pdb);
HandleError(status);
LogPrintf("Opened LevelDB successfully\n");
if (params.options.force_compact) {
LogPrintf("Starting database compaction of %s\n", fs::PathToString(params.path));
pdb->CompactRange(nullptr, nullptr);
LogPrintf("Finished database compaction of %s\n", fs::PathToString(params.path));
}
// The base-case obfuscation key, which is a noop.
obfuscate_key = std::vector<unsigned char>(OBFUSCATE_KEY_NUM_BYTES, '\000');
bool key_exists = Read(OBFUSCATE_KEY_KEY, obfuscate_key);
if (!key_exists && params.obfuscate && IsEmpty()) {
// Initialize non-degenerate obfuscation if it won't upset
// existing, non-obfuscated data.
std::vector<unsigned char> new_key = CreateObfuscateKey();
// Write `new_key` so we don't obfuscate the key with itself
Write(OBFUSCATE_KEY_KEY, new_key);
obfuscate_key = new_key;
LogPrintf("Wrote new obfuscate key for %s: %s\n", fs::PathToString(params.path), HexStr(obfuscate_key));
}
LogPrintf("Using obfuscation key for %s: %s\n", fs::PathToString(params.path), HexStr(obfuscate_key));
}
CDBWrapper::~CDBWrapper()
{
delete pdb;
pdb = nullptr;
delete options.filter_policy;
options.filter_policy = nullptr;
delete options.info_log;
options.info_log = nullptr;
delete options.block_cache;
options.block_cache = nullptr;
delete penv;
options.env = nullptr;
}
bool CDBWrapper::WriteBatch(CDBBatch& batch, bool fSync)
{
const bool log_memory = LogAcceptCategory(BCLog::LEVELDB, BCLog::Level::Debug);
double mem_before = 0;
if (log_memory) {
mem_before = DynamicMemoryUsage() / 1024.0 / 1024;
}
leveldb::Status status = pdb->Write(fSync ? syncoptions : writeoptions, &batch.m_impl_batch->batch);
HandleError(status);
if (log_memory) {
double mem_after = DynamicMemoryUsage() / 1024.0 / 1024;
LogPrint(BCLog::LEVELDB, "WriteBatch memory usage: db=%s, before=%.1fMiB, after=%.1fMiB\n",
m_name, mem_before, mem_after);
}
return true;
}
size_t CDBWrapper::DynamicMemoryUsage() const
{
std::string memory;
std::optional<size_t> parsed;
if (!pdb->GetProperty("leveldb.approximate-memory-usage", &memory) || !(parsed = ToIntegral<size_t>(memory))) {
LogPrint(BCLog::LEVELDB, "Failed to get approximate-memory-usage property\n");
return 0;
}
return parsed.value();
}
// Prefixed with null character to avoid collisions with other keys
//
// We must use a string constructor which specifies length so that we copy
// past the null-terminator.
const std::string CDBWrapper::OBFUSCATE_KEY_KEY("\000obfuscate_key", 14);
const unsigned int CDBWrapper::OBFUSCATE_KEY_NUM_BYTES = 8;
/**
* Returns a string (consisting of 8 random bytes) suitable for use as an
* obfuscating XOR key.
*/
std::vector<unsigned char> CDBWrapper::CreateObfuscateKey() const
{
std::vector<uint8_t> ret(OBFUSCATE_KEY_NUM_BYTES);
GetRandBytes(ret);
return ret;
}
std::optional<std::string> CDBWrapper::ReadImpl(Span<const std::byte> ssKey) const
{
leveldb::Slice slKey(CharCast(ssKey.data()), ssKey.size());
std::string strValue;
leveldb::Status status = pdb->Get(readoptions, slKey, &strValue);
if (!status.ok()) {
if (status.IsNotFound())
return std::nullopt;
LogPrintf("LevelDB read failure: %s\n", status.ToString());
HandleError(status);
}
return strValue;
}
bool CDBWrapper::ExistsImpl(Span<const std::byte> ssKey) const
{
leveldb::Slice slKey(CharCast(ssKey.data()), ssKey.size());
std::string strValue;
leveldb::Status status = pdb->Get(readoptions, slKey, &strValue);
if (!status.ok()) {
if (status.IsNotFound())
return false;
LogPrintf("LevelDB read failure: %s\n", status.ToString());
HandleError(status);
}
return true;
}
size_t CDBWrapper::EstimateSizeImpl(Span<const std::byte> ssKey1, Span<const std::byte> ssKey2) const
{
leveldb::Slice slKey1(CharCast(ssKey1.data()), ssKey1.size());
leveldb::Slice slKey2(CharCast(ssKey2.data()), ssKey2.size());
uint64_t size = 0;
leveldb::Range range(slKey1, slKey2);
pdb->GetApproximateSizes(&range, 1, &size);
return size;
}
bool CDBWrapper::IsEmpty()
{
std::unique_ptr<CDBIterator> it(NewIterator());
it->SeekToFirst();
return !(it->Valid());
}
struct CDBIterator::IteratorImpl {
const std::unique_ptr<leveldb::Iterator> iter;
explicit IteratorImpl(leveldb::Iterator* _iter) : iter{_iter} {}
};
CDBIterator::CDBIterator(const CDBWrapper& _parent, std::unique_ptr<IteratorImpl> _piter) : parent(_parent), m_impl_iter(std::move(_piter)) {}
CDBIterator* CDBWrapper::NewIterator()
{
return new CDBIterator{*this, std::make_unique<CDBIterator::IteratorImpl>(pdb->NewIterator(iteroptions))};
}
void CDBIterator::SeekImpl(Span<const std::byte> ssKey)
{
leveldb::Slice slKey(CharCast(ssKey.data()), ssKey.size());
m_impl_iter->iter->Seek(slKey);
}
Span<const std::byte> CDBIterator::GetKeyImpl() const
{
return MakeByteSpan(m_impl_iter->iter->key());
}
Span<const std::byte> CDBIterator::GetValueImpl() const
{
return MakeByteSpan(m_impl_iter->iter->value());
}
CDBIterator::~CDBIterator() = default;
bool CDBIterator::Valid() const { return m_impl_iter->iter->Valid(); }
void CDBIterator::SeekToFirst() { m_impl_iter->iter->SeekToFirst(); }
void CDBIterator::Next() { m_impl_iter->iter->Next(); }
namespace dbwrapper_private {
const std::vector<unsigned char>& GetObfuscateKey(const CDBWrapper &w)
{
return w.obfuscate_key;
}
} // namespace dbwrapper_private
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