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sqlite.cpp
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sqlite.cpp
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// Copyright (c) 2020-2022 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#if defined(HAVE_CONFIG_H)
#include <config/bitcoin-config.h>
#endif
#include <wallet/sqlite.h>
#include <chainparams.h>
#include <crypto/common.h>
#include <logging.h>
#include <sync.h>
#include <util/fs_helpers.h>
#include <util/check.h>
#include <util/strencodings.h>
#include <util/translation.h>
#include <wallet/db.h>
#include <sqlite3.h>
#include <stdint.h>
#include <optional>
#include <utility>
#include <vector>
namespace wallet {
static constexpr int32_t WALLET_SCHEMA_VERSION = 0;
static Span<const std::byte> SpanFromBlob(sqlite3_stmt* stmt, int col)
{
return {reinterpret_cast<const std::byte*>(sqlite3_column_blob(stmt, col)),
static_cast<size_t>(sqlite3_column_bytes(stmt, col))};
}
static void ErrorLogCallback(void* arg, int code, const char* msg)
{
// From sqlite3_config() documentation for the SQLITE_CONFIG_LOG option:
// "The void pointer that is the second argument to SQLITE_CONFIG_LOG is passed through as
// the first parameter to the application-defined logger function whenever that function is
// invoked."
// Assert that this is the case:
assert(arg == nullptr);
LogPrintf("SQLite Error. Code: %d. Message: %s\n", code, msg);
}
static int TraceSqlCallback(unsigned code, void* context, void* param1, void* param2)
{
auto* db = static_cast<SQLiteDatabase*>(context);
if (code == SQLITE_TRACE_STMT) {
auto* stmt = static_cast<sqlite3_stmt*>(param1);
// To be conservative and avoid leaking potentially secret information
// in the log file, only expand statements that query the database, not
// statements that update the database.
char* expanded{sqlite3_stmt_readonly(stmt) ? sqlite3_expanded_sql(stmt) : nullptr};
LogPrintf("[%s] SQLite Statement: %s\n", db->Filename(), expanded ? expanded : sqlite3_sql(stmt));
if (expanded) sqlite3_free(expanded);
}
return SQLITE_OK;
}
static bool BindBlobToStatement(sqlite3_stmt* stmt,
int index,
Span<const std::byte> blob,
const std::string& description)
{
// Pass a pointer to the empty string "" below instead of passing the
// blob.data() pointer if the blob.data() pointer is null. Passing a null
// data pointer to bind_blob would cause sqlite to bind the SQL NULL value
// instead of the empty blob value X'', which would mess up SQL comparisons.
int res = sqlite3_bind_blob(stmt, index, blob.data() ? static_cast<const void*>(blob.data()) : "", blob.size(), SQLITE_STATIC);
if (res != SQLITE_OK) {
LogPrintf("Unable to bind %s to statement: %s\n", description, sqlite3_errstr(res));
sqlite3_clear_bindings(stmt);
sqlite3_reset(stmt);
return false;
}
return true;
}
static std::optional<int> ReadPragmaInteger(sqlite3* db, const std::string& key, const std::string& description, bilingual_str& error)
{
std::string stmt_text = strprintf("PRAGMA %s", key);
sqlite3_stmt* pragma_read_stmt{nullptr};
int ret = sqlite3_prepare_v2(db, stmt_text.c_str(), -1, &pragma_read_stmt, nullptr);
if (ret != SQLITE_OK) {
sqlite3_finalize(pragma_read_stmt);
error = Untranslated(strprintf("SQLiteDatabase: Failed to prepare the statement to fetch %s: %s", description, sqlite3_errstr(ret)));
return std::nullopt;
}
ret = sqlite3_step(pragma_read_stmt);
if (ret != SQLITE_ROW) {
sqlite3_finalize(pragma_read_stmt);
error = Untranslated(strprintf("SQLiteDatabase: Failed to fetch %s: %s", description, sqlite3_errstr(ret)));
return std::nullopt;
}
int result = sqlite3_column_int(pragma_read_stmt, 0);
sqlite3_finalize(pragma_read_stmt);
return result;
}
static void SetPragma(sqlite3* db, const std::string& key, const std::string& value, const std::string& err_msg)
{
std::string stmt_text = strprintf("PRAGMA %s = %s", key, value);
int ret = sqlite3_exec(db, stmt_text.c_str(), nullptr, nullptr, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: %s: %s\n", err_msg, sqlite3_errstr(ret)));
}
}
Mutex SQLiteDatabase::g_sqlite_mutex;
int SQLiteDatabase::g_sqlite_count = 0;
SQLiteDatabase::SQLiteDatabase(const fs::path& dir_path, const fs::path& file_path, const DatabaseOptions& options, bool mock)
: WalletDatabase(), m_mock(mock), m_dir_path(fs::PathToString(dir_path)), m_file_path(fs::PathToString(file_path)), m_write_semaphore(1), m_use_unsafe_sync(options.use_unsafe_sync)
{
{
LOCK(g_sqlite_mutex);
LogPrintf("Using SQLite Version %s\n", SQLiteDatabaseVersion());
LogPrintf("Using wallet %s\n", m_dir_path);
if (++g_sqlite_count == 1) {
// Setup logging
int ret = sqlite3_config(SQLITE_CONFIG_LOG, ErrorLogCallback, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to setup error log: %s\n", sqlite3_errstr(ret)));
}
// Force serialized threading mode
ret = sqlite3_config(SQLITE_CONFIG_SERIALIZED);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to configure serialized threading mode: %s\n", sqlite3_errstr(ret)));
}
}
int ret = sqlite3_initialize(); // This is a no-op if sqlite3 is already initialized
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to initialize SQLite: %s\n", sqlite3_errstr(ret)));
}
}
try {
Open();
} catch (const std::runtime_error&) {
// If open fails, cleanup this object and rethrow the exception
Cleanup();
throw;
}
}
void SQLiteBatch::SetupSQLStatements()
{
const std::vector<std::pair<sqlite3_stmt**, const char*>> statements{
{&m_read_stmt, "SELECT value FROM main WHERE key = ?"},
{&m_insert_stmt, "INSERT INTO main VALUES(?, ?)"},
{&m_overwrite_stmt, "INSERT or REPLACE into main values(?, ?)"},
{&m_delete_stmt, "DELETE FROM main WHERE key = ?"},
{&m_delete_prefix_stmt, "DELETE FROM main WHERE instr(key, ?) = 1"},
};
for (const auto& [stmt_prepared, stmt_text] : statements) {
if (*stmt_prepared == nullptr) {
int res = sqlite3_prepare_v2(m_database.m_db, stmt_text, -1, stmt_prepared, nullptr);
if (res != SQLITE_OK) {
throw std::runtime_error(strprintf(
"SQLiteDatabase: Failed to setup SQL statements: %s\n", sqlite3_errstr(res)));
}
}
}
}
SQLiteDatabase::~SQLiteDatabase()
{
Cleanup();
}
void SQLiteDatabase::Cleanup() noexcept
{
AssertLockNotHeld(g_sqlite_mutex);
Close();
LOCK(g_sqlite_mutex);
if (--g_sqlite_count == 0) {
int ret = sqlite3_shutdown();
if (ret != SQLITE_OK) {
LogPrintf("SQLiteDatabase: Failed to shutdown SQLite: %s\n", sqlite3_errstr(ret));
}
}
}
bool SQLiteDatabase::Verify(bilingual_str& error)
{
assert(m_db);
// Check the application ID matches our network magic
auto read_result = ReadPragmaInteger(m_db, "application_id", "the application id", error);
if (!read_result.has_value()) return false;
uint32_t app_id = static_cast<uint32_t>(read_result.value());
uint32_t net_magic = ReadBE32(Params().MessageStart().data());
if (app_id != net_magic) {
error = strprintf(_("SQLiteDatabase: Unexpected application id. Expected %u, got %u"), net_magic, app_id);
return false;
}
// Check our schema version
read_result = ReadPragmaInteger(m_db, "user_version", "sqlite wallet schema version", error);
if (!read_result.has_value()) return false;
int32_t user_ver = read_result.value();
if (user_ver != WALLET_SCHEMA_VERSION) {
error = strprintf(_("SQLiteDatabase: Unknown sqlite wallet schema version %d. Only version %d is supported"), user_ver, WALLET_SCHEMA_VERSION);
return false;
}
sqlite3_stmt* stmt{nullptr};
int ret = sqlite3_prepare_v2(m_db, "PRAGMA integrity_check", -1, &stmt, nullptr);
if (ret != SQLITE_OK) {
sqlite3_finalize(stmt);
error = strprintf(_("SQLiteDatabase: Failed to prepare statement to verify database: %s"), sqlite3_errstr(ret));
return false;
}
while (true) {
ret = sqlite3_step(stmt);
if (ret == SQLITE_DONE) {
break;
}
if (ret != SQLITE_ROW) {
error = strprintf(_("SQLiteDatabase: Failed to execute statement to verify database: %s"), sqlite3_errstr(ret));
break;
}
const char* msg = (const char*)sqlite3_column_text(stmt, 0);
if (!msg) {
error = strprintf(_("SQLiteDatabase: Failed to read database verification error: %s"), sqlite3_errstr(ret));
break;
}
std::string str_msg(msg);
if (str_msg == "ok") {
continue;
}
if (error.empty()) {
error = _("Failed to verify database") + Untranslated("\n");
}
error += Untranslated(strprintf("%s\n", str_msg));
}
sqlite3_finalize(stmt);
return error.empty();
}
void SQLiteDatabase::Open()
{
int flags = SQLITE_OPEN_FULLMUTEX | SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE;
if (m_mock) {
flags |= SQLITE_OPEN_MEMORY; // In memory database for mock db
}
if (m_db == nullptr) {
if (!m_mock) {
TryCreateDirectories(fs::PathFromString(m_dir_path));
}
int ret = sqlite3_open_v2(m_file_path.c_str(), &m_db, flags, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to open database: %s\n", sqlite3_errstr(ret)));
}
ret = sqlite3_extended_result_codes(m_db, 1);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to enable extended result codes: %s\n", sqlite3_errstr(ret)));
}
// Trace SQL statements if tracing is enabled with -debug=walletdb -loglevel=walletdb:trace
if (LogAcceptCategory(BCLog::WALLETDB, BCLog::Level::Trace)) {
ret = sqlite3_trace_v2(m_db, SQLITE_TRACE_STMT, TraceSqlCallback, this);
if (ret != SQLITE_OK) {
LogPrintf("Failed to enable SQL tracing for %s\n", Filename());
}
}
}
if (sqlite3_db_readonly(m_db, "main") != 0) {
throw std::runtime_error("SQLiteDatabase: Database opened in readonly mode but read-write permissions are needed");
}
// Acquire an exclusive lock on the database
// First change the locking mode to exclusive
SetPragma(m_db, "locking_mode", "exclusive", "Unable to change database locking mode to exclusive");
// Now begin a transaction to acquire the exclusive lock. This lock won't be released until we close because of the exclusive locking mode.
int ret = sqlite3_exec(m_db, "BEGIN EXCLUSIVE TRANSACTION", nullptr, nullptr, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error("SQLiteDatabase: Unable to obtain an exclusive lock on the database, is it being used by another instance of " PACKAGE_NAME "?\n");
}
ret = sqlite3_exec(m_db, "COMMIT", nullptr, nullptr, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Unable to end exclusive lock transaction: %s\n", sqlite3_errstr(ret)));
}
// Enable fullfsync for the platforms that use it
SetPragma(m_db, "fullfsync", "true", "Failed to enable fullfsync");
if (m_use_unsafe_sync) {
// Use normal synchronous mode for the journal
LogPrintf("WARNING SQLite is configured to not wait for data to be flushed to disk. Data loss and corruption may occur.\n");
SetPragma(m_db, "synchronous", "OFF", "Failed to set synchronous mode to OFF");
}
// Make the table for our key-value pairs
// First check that the main table exists
sqlite3_stmt* check_main_stmt{nullptr};
ret = sqlite3_prepare_v2(m_db, "SELECT name FROM sqlite_master WHERE type='table' AND name='main'", -1, &check_main_stmt, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to prepare statement to check table existence: %s\n", sqlite3_errstr(ret)));
}
ret = sqlite3_step(check_main_stmt);
if (sqlite3_finalize(check_main_stmt) != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to finalize statement checking table existence: %s\n", sqlite3_errstr(ret)));
}
bool table_exists;
if (ret == SQLITE_DONE) {
table_exists = false;
} else if (ret == SQLITE_ROW) {
table_exists = true;
} else {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to execute statement to check table existence: %s\n", sqlite3_errstr(ret)));
}
// Do the db setup things because the table doesn't exist only when we are creating a new wallet
if (!table_exists) {
ret = sqlite3_exec(m_db, "CREATE TABLE main(key BLOB PRIMARY KEY NOT NULL, value BLOB NOT NULL)", nullptr, nullptr, nullptr);
if (ret != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to create new database: %s\n", sqlite3_errstr(ret)));
}
// Set the application id
uint32_t app_id = ReadBE32(Params().MessageStart().data());
SetPragma(m_db, "application_id", strprintf("%d", static_cast<int32_t>(app_id)),
"Failed to set the application id");
// Set the user version
SetPragma(m_db, "user_version", strprintf("%d", WALLET_SCHEMA_VERSION),
"Failed to set the wallet schema version");
}
}
bool SQLiteDatabase::Rewrite(const char* skip)
{
// Rewrite the database using the VACUUM command: https://sqlite.org/lang_vacuum.html
int ret = sqlite3_exec(m_db, "VACUUM", nullptr, nullptr, nullptr);
return ret == SQLITE_OK;
}
bool SQLiteDatabase::Backup(const std::string& dest) const
{
sqlite3* db_copy;
int res = sqlite3_open(dest.c_str(), &db_copy);
if (res != SQLITE_OK) {
sqlite3_close(db_copy);
return false;
}
sqlite3_backup* backup = sqlite3_backup_init(db_copy, "main", m_db, "main");
if (!backup) {
LogPrintf("%s: Unable to begin backup: %s\n", __func__, sqlite3_errmsg(m_db));
sqlite3_close(db_copy);
return false;
}
// Specifying -1 will copy all of the pages
res = sqlite3_backup_step(backup, -1);
if (res != SQLITE_DONE) {
LogPrintf("%s: Unable to backup: %s\n", __func__, sqlite3_errstr(res));
sqlite3_backup_finish(backup);
sqlite3_close(db_copy);
return false;
}
res = sqlite3_backup_finish(backup);
sqlite3_close(db_copy);
return res == SQLITE_OK;
}
void SQLiteDatabase::Close()
{
int res = sqlite3_close(m_db);
if (res != SQLITE_OK) {
throw std::runtime_error(strprintf("SQLiteDatabase: Failed to close database: %s\n", sqlite3_errstr(res)));
}
m_db = nullptr;
}
bool SQLiteDatabase::HasActiveTxn()
{
// 'sqlite3_get_autocommit' returns true by default, and false if a transaction has begun and not been committed or rolled back.
return m_db && sqlite3_get_autocommit(m_db) == 0;
}
int SQliteExecHandler::Exec(SQLiteDatabase& database, const std::string& statement)
{
return sqlite3_exec(database.m_db, statement.data(), nullptr, nullptr, nullptr);
}
std::unique_ptr<DatabaseBatch> SQLiteDatabase::MakeBatch(bool flush_on_close)
{
// We ignore flush_on_close because we don't do manual flushing for SQLite
return std::make_unique<SQLiteBatch>(*this);
}
SQLiteBatch::SQLiteBatch(SQLiteDatabase& database)
: m_database(database)
{
// Make sure we have a db handle
assert(m_database.m_db);
SetupSQLStatements();
}
void SQLiteBatch::Close()
{
bool force_conn_refresh = false;
// If we began a transaction, and it wasn't committed, abort the transaction in progress
if (m_txn) {
if (TxnAbort()) {
LogPrintf("SQLiteBatch: Batch closed unexpectedly without the transaction being explicitly committed or aborted\n");
} else {
// If transaction cannot be aborted, it means there is a bug or there has been data corruption. Try to recover in this case
// by closing and reopening the database. Closing the database should also ensure that any changes made since the transaction
// was opened will be rolled back and future transactions can succeed without committing old data.
force_conn_refresh = true;
LogPrintf("SQLiteBatch: Batch closed and failed to abort transaction, resetting db connection..\n");
}
}
// Free all of the prepared statements
const std::vector<std::pair<sqlite3_stmt**, const char*>> statements{
{&m_read_stmt, "read"},
{&m_insert_stmt, "insert"},
{&m_overwrite_stmt, "overwrite"},
{&m_delete_stmt, "delete"},
{&m_delete_prefix_stmt, "delete prefix"},
};
for (const auto& [stmt_prepared, stmt_description] : statements) {
int res = sqlite3_finalize(*stmt_prepared);
if (res != SQLITE_OK) {
LogPrintf("SQLiteBatch: Batch closed but could not finalize %s statement: %s\n",
stmt_description, sqlite3_errstr(res));
}
*stmt_prepared = nullptr;
}
if (force_conn_refresh) {
m_database.Close();
try {
m_database.Open();
// If TxnAbort failed and we refreshed the connection, the semaphore was not released, so release it here to avoid deadlocks on future writes.
m_database.m_write_semaphore.post();
} catch (const std::runtime_error&) {
// If open fails, cleanup this object and rethrow the exception
m_database.Close();
throw;
}
}
}
bool SQLiteBatch::ReadKey(DataStream&& key, DataStream& value)
{
if (!m_database.m_db) return false;
assert(m_read_stmt);
// Bind: leftmost parameter in statement is index 1
if (!BindBlobToStatement(m_read_stmt, 1, key, "key")) return false;
int res = sqlite3_step(m_read_stmt);
if (res != SQLITE_ROW) {
if (res != SQLITE_DONE) {
// SQLITE_DONE means "not found", don't log an error in that case.
LogPrintf("%s: Unable to execute statement: %s\n", __func__, sqlite3_errstr(res));
}
sqlite3_clear_bindings(m_read_stmt);
sqlite3_reset(m_read_stmt);
return false;
}
// Leftmost column in result is index 0
value.clear();
value.write(SpanFromBlob(m_read_stmt, 0));
sqlite3_clear_bindings(m_read_stmt);
sqlite3_reset(m_read_stmt);
return true;
}
bool SQLiteBatch::WriteKey(DataStream&& key, DataStream&& value, bool overwrite)
{
if (!m_database.m_db) return false;
assert(m_insert_stmt && m_overwrite_stmt);
sqlite3_stmt* stmt;
if (overwrite) {
stmt = m_overwrite_stmt;
} else {
stmt = m_insert_stmt;
}
// Bind: leftmost parameter in statement is index 1
// Insert index 1 is key, 2 is value
if (!BindBlobToStatement(stmt, 1, key, "key")) return false;
if (!BindBlobToStatement(stmt, 2, value, "value")) return false;
// Acquire semaphore if not previously acquired when creating a transaction.
if (!m_txn) m_database.m_write_semaphore.wait();
// Execute
int res = sqlite3_step(stmt);
sqlite3_clear_bindings(stmt);
sqlite3_reset(stmt);
if (res != SQLITE_DONE) {
LogPrintf("%s: Unable to execute statement: %s\n", __func__, sqlite3_errstr(res));
}
if (!m_txn) m_database.m_write_semaphore.post();
return res == SQLITE_DONE;
}
bool SQLiteBatch::ExecStatement(sqlite3_stmt* stmt, Span<const std::byte> blob)
{
if (!m_database.m_db) return false;
assert(stmt);
// Bind: leftmost parameter in statement is index 1
if (!BindBlobToStatement(stmt, 1, blob, "key")) return false;
// Acquire semaphore if not previously acquired when creating a transaction.
if (!m_txn) m_database.m_write_semaphore.wait();
// Execute
int res = sqlite3_step(stmt);
sqlite3_clear_bindings(stmt);
sqlite3_reset(stmt);
if (res != SQLITE_DONE) {
LogPrintf("%s: Unable to execute statement: %s\n", __func__, sqlite3_errstr(res));
}
if (!m_txn) m_database.m_write_semaphore.post();
return res == SQLITE_DONE;
}
bool SQLiteBatch::EraseKey(DataStream&& key)
{
return ExecStatement(m_delete_stmt, key);
}
bool SQLiteBatch::ErasePrefix(Span<const std::byte> prefix)
{
return ExecStatement(m_delete_prefix_stmt, prefix);
}
bool SQLiteBatch::HasKey(DataStream&& key)
{
if (!m_database.m_db) return false;
assert(m_read_stmt);
// Bind: leftmost parameter in statement is index 1
if (!BindBlobToStatement(m_read_stmt, 1, key, "key")) return false;
int res = sqlite3_step(m_read_stmt);
sqlite3_clear_bindings(m_read_stmt);
sqlite3_reset(m_read_stmt);
return res == SQLITE_ROW;
}
DatabaseCursor::Status SQLiteCursor::Next(DataStream& key, DataStream& value)
{
int res = sqlite3_step(m_cursor_stmt);
if (res == SQLITE_DONE) {
return Status::DONE;
}
if (res != SQLITE_ROW) {
LogPrintf("%s: Unable to execute cursor step: %s\n", __func__, sqlite3_errstr(res));
return Status::FAIL;
}
key.clear();
value.clear();
// Leftmost column in result is index 0
key.write(SpanFromBlob(m_cursor_stmt, 0));
value.write(SpanFromBlob(m_cursor_stmt, 1));
return Status::MORE;
}
SQLiteCursor::~SQLiteCursor()
{
sqlite3_clear_bindings(m_cursor_stmt);
sqlite3_reset(m_cursor_stmt);
int res = sqlite3_finalize(m_cursor_stmt);
if (res != SQLITE_OK) {
LogPrintf("%s: cursor closed but could not finalize cursor statement: %s\n",
__func__, sqlite3_errstr(res));
}
}
std::unique_ptr<DatabaseCursor> SQLiteBatch::GetNewCursor()
{
if (!m_database.m_db) return nullptr;
auto cursor = std::make_unique<SQLiteCursor>();
const char* stmt_text = "SELECT key, value FROM main";
int res = sqlite3_prepare_v2(m_database.m_db, stmt_text, -1, &cursor->m_cursor_stmt, nullptr);
if (res != SQLITE_OK) {
throw std::runtime_error(strprintf(
"%s: Failed to setup cursor SQL statement: %s\n", __func__, sqlite3_errstr(res)));
}
return cursor;
}
std::unique_ptr<DatabaseCursor> SQLiteBatch::GetNewPrefixCursor(Span<const std::byte> prefix)
{
if (!m_database.m_db) return nullptr;
// To get just the records we want, the SQL statement does a comparison of the binary data
// where the data must be greater than or equal to the prefix, and less than
// the prefix incremented by one (when interpreted as an integer)
std::vector<std::byte> start_range(prefix.begin(), prefix.end());
std::vector<std::byte> end_range(prefix.begin(), prefix.end());
auto it = end_range.rbegin();
for (; it != end_range.rend(); ++it) {
if (*it == std::byte(std::numeric_limits<unsigned char>::max())) {
*it = std::byte(0);
continue;
}
*it = std::byte(std::to_integer<unsigned char>(*it) + 1);
break;
}
if (it == end_range.rend()) {
// If the prefix is all 0xff bytes, clear end_range as we won't need it
end_range.clear();
}
auto cursor = std::make_unique<SQLiteCursor>(start_range, end_range);
if (!cursor) return nullptr;
const char* stmt_text = end_range.empty() ? "SELECT key, value FROM main WHERE key >= ?" :
"SELECT key, value FROM main WHERE key >= ? AND key < ?";
int res = sqlite3_prepare_v2(m_database.m_db, stmt_text, -1, &cursor->m_cursor_stmt, nullptr);
if (res != SQLITE_OK) {
throw std::runtime_error(strprintf(
"SQLiteDatabase: Failed to setup cursor SQL statement: %s\n", sqlite3_errstr(res)));
}
if (!BindBlobToStatement(cursor->m_cursor_stmt, 1, cursor->m_prefix_range_start, "prefix_start")) return nullptr;
if (!end_range.empty()) {
if (!BindBlobToStatement(cursor->m_cursor_stmt, 2, cursor->m_prefix_range_end, "prefix_end")) return nullptr;
}
return cursor;
}
bool SQLiteBatch::TxnBegin()
{
if (!m_database.m_db || m_txn) return false;
m_database.m_write_semaphore.wait();
Assert(!m_database.HasActiveTxn());
int res = Assert(m_exec_handler)->Exec(m_database, "BEGIN TRANSACTION");
if (res != SQLITE_OK) {
LogPrintf("SQLiteBatch: Failed to begin the transaction\n");
m_database.m_write_semaphore.post();
} else {
m_txn = true;
}
return res == SQLITE_OK;
}
bool SQLiteBatch::TxnCommit()
{
if (!m_database.m_db || !m_txn) return false;
Assert(m_database.HasActiveTxn());
int res = Assert(m_exec_handler)->Exec(m_database, "COMMIT TRANSACTION");
if (res != SQLITE_OK) {
LogPrintf("SQLiteBatch: Failed to commit the transaction\n");
} else {
m_txn = false;
m_database.m_write_semaphore.post();
}
return res == SQLITE_OK;
}
bool SQLiteBatch::TxnAbort()
{
if (!m_database.m_db || !m_txn) return false;
Assert(m_database.HasActiveTxn());
int res = Assert(m_exec_handler)->Exec(m_database, "ROLLBACK TRANSACTION");
if (res != SQLITE_OK) {
LogPrintf("SQLiteBatch: Failed to abort the transaction\n");
} else {
m_txn = false;
m_database.m_write_semaphore.post();
}
return res == SQLITE_OK;
}
std::unique_ptr<SQLiteDatabase> MakeSQLiteDatabase(const fs::path& path, const DatabaseOptions& options, DatabaseStatus& status, bilingual_str& error)
{
try {
fs::path data_file = SQLiteDataFile(path);
auto db = std::make_unique<SQLiteDatabase>(data_file.parent_path(), data_file, options);
if (options.verify && !db->Verify(error)) {
status = DatabaseStatus::FAILED_VERIFY;
return nullptr;
}
status = DatabaseStatus::SUCCESS;
return db;
} catch (const std::runtime_error& e) {
status = DatabaseStatus::FAILED_LOAD;
error = Untranslated(e.what());
return nullptr;
}
}
std::string SQLiteDatabaseVersion()
{
return std::string(sqlite3_libversion());
}
} // namespace wallet