#include "sqlite.hh" #include "globals.hh" #include "util.hh" #include #include namespace nix { SQLiteError::SQLiteError(const char *path, const char *errMsg, int errNo, int extendedErrNo, int offset, hintformat && hf) : Error(""), path(path), errMsg(errMsg), errNo(errNo), extendedErrNo(extendedErrNo), offset(offset) { auto offsetStr = (offset == -1) ? "" : "at offset " + std::to_string(offset) + ": "; err.msg = hintfmt("%s: %s%s, %s (in '%s')", normaltxt(hf.str()), offsetStr, sqlite3_errstr(extendedErrNo), errMsg, path ? path : "(in-memory)"); } [[noreturn]] void SQLiteError::throw_(sqlite3 * db, hintformat && hf) { int err = sqlite3_errcode(db); int exterr = sqlite3_extended_errcode(db); int offset = sqlite3_error_offset(db); auto path = sqlite3_db_filename(db, nullptr); auto errMsg = sqlite3_errmsg(db); if (err == SQLITE_BUSY || err == SQLITE_PROTOCOL) { auto exp = SQLiteBusy(path, errMsg, err, exterr, offset, std::move(hf)); exp.err.msg = hintfmt( err == SQLITE_PROTOCOL ? "SQLite database '%s' is busy (SQLITE_PROTOCOL)" : "SQLite database '%s' is busy", path ? path : "(in-memory)"); throw exp; } else throw SQLiteError(path, errMsg, err, exterr, offset, std::move(hf)); } static void traceSQL(void * x, const char * sql) { // wacky delimiters: // so that we're quite unambiguous without escaping anything // notice instead of trace: // so that this can be enabled without getting the firehose in our face. notice("SQL<[%1%]>", sql); }; SQLite::SQLite(const Path & path, SQLiteOpenMode mode) { // useSQLiteWAL also indicates what virtual file system we need. Using // `unix-dotfile` is needed on NFS file systems and on Windows' Subsystem // for Linux (WSL) where useSQLiteWAL should be false by default. const char *vfs = settings.useSQLiteWAL ? 0 : "unix-dotfile"; int flags = mode == SQLiteOpenMode::ReadOnly ? SQLITE_OPEN_READONLY : SQLITE_OPEN_READWRITE; if (mode == SQLiteOpenMode::Normal) flags |= SQLITE_OPEN_CREATE; int ret = sqlite3_open_v2(path.c_str(), &db, flags, vfs); if (ret != SQLITE_OK) { const char * err = sqlite3_errstr(ret); throw Error("cannot open SQLite database '%s': %s", path, err); } if (sqlite3_busy_timeout(db, 60 * 60 * 1000) != SQLITE_OK) SQLiteError::throw_(db, "setting timeout"); if (getEnv("NIX_DEBUG_SQLITE_TRACES") == "1") { // To debug sqlite statements; trace all of them sqlite3_trace(db, &traceSQL, nullptr); } exec("pragma foreign_keys = 1"); } SQLite::~SQLite() { try { if (db && sqlite3_close(db) != SQLITE_OK) SQLiteError::throw_(db, "closing database"); } catch (...) { ignoreException(); } } void SQLite::isCache() { exec("pragma synchronous = off"); exec("pragma main.journal_mode = truncate"); } void SQLite::exec(const std::string & stmt) { retrySQLite([&]() { if (sqlite3_exec(db, stmt.c_str(), 0, 0, 0) != SQLITE_OK) SQLiteError::throw_(db, "executing SQLite statement '%s'", stmt); }); } uint64_t SQLite::getLastInsertedRowId() { return sqlite3_last_insert_rowid(db); } void SQLiteStmt::create(sqlite3 * db, const std::string & sql) { checkInterrupt(); assert(!stmt); if (sqlite3_prepare_v2(db, sql.c_str(), -1, &stmt, 0) != SQLITE_OK) SQLiteError::throw_(db, "creating statement '%s'", sql); this->db = db; this->sql = sql; } SQLiteStmt::~SQLiteStmt() { try { if (stmt && sqlite3_finalize(stmt) != SQLITE_OK) SQLiteError::throw_(db, "finalizing statement '%s'", sql); } catch (...) { ignoreException(); } } SQLiteStmt::Use::Use(SQLiteStmt & stmt) : stmt(stmt) { assert(stmt.stmt); /* Note: sqlite3_reset() returns the error code for the most recent call to sqlite3_step(). So ignore it. */ sqlite3_reset(stmt); } SQLiteStmt::Use::~Use() { sqlite3_reset(stmt); } SQLiteStmt::Use & SQLiteStmt::Use::operator () (std::string_view value, bool notNull) { if (notNull) { if (sqlite3_bind_text(stmt, curArg++, value.data(), -1, SQLITE_TRANSIENT) != SQLITE_OK) SQLiteError::throw_(stmt.db, "binding argument"); } else bind(); return *this; } SQLiteStmt::Use & SQLiteStmt::Use::operator () (const unsigned char * data, size_t len, bool notNull) { if (notNull) { if (sqlite3_bind_blob(stmt, curArg++, data, len, SQLITE_TRANSIENT) != SQLITE_OK) SQLiteError::throw_(stmt.db, "binding argument"); } else bind(); return *this; } SQLiteStmt::Use & SQLiteStmt::Use::operator () (int64_t value, bool notNull) { if (notNull) { if (sqlite3_bind_int64(stmt, curArg++, value) != SQLITE_OK) SQLiteError::throw_(stmt.db, "binding argument"); } else bind(); return *this; } SQLiteStmt::Use & SQLiteStmt::Use::bind() { if (sqlite3_bind_null(stmt, curArg++) != SQLITE_OK) SQLiteError::throw_(stmt.db, "binding argument"); return *this; } int SQLiteStmt::Use::step() { return sqlite3_step(stmt); } void SQLiteStmt::Use::exec() { int r = step(); assert(r != SQLITE_ROW); if (r != SQLITE_DONE) SQLiteError::throw_(stmt.db, fmt("executing SQLite statement '%s'", sqlite3_expanded_sql(stmt.stmt))); } bool SQLiteStmt::Use::next() { int r = step(); if (r != SQLITE_DONE && r != SQLITE_ROW) SQLiteError::throw_(stmt.db, fmt("executing SQLite query '%s'", sqlite3_expanded_sql(stmt.stmt))); return r == SQLITE_ROW; } std::string SQLiteStmt::Use::getStr(int col) { auto s = (const char *) sqlite3_column_text(stmt, col); assert(s); return s; } int64_t SQLiteStmt::Use::getInt(int col) { // FIXME: detect nulls? return sqlite3_column_int64(stmt, col); } bool SQLiteStmt::Use::isNull(int col) { return sqlite3_column_type(stmt, col) == SQLITE_NULL; } SQLiteTxn::SQLiteTxn(sqlite3 * db) { this->db = db; if (sqlite3_exec(db, "begin;", 0, 0, 0) != SQLITE_OK) SQLiteError::throw_(db, "starting transaction"); active = true; } void SQLiteTxn::commit() { if (sqlite3_exec(db, "commit;", 0, 0, 0) != SQLITE_OK) SQLiteError::throw_(db, "committing transaction"); active = false; } SQLiteTxn::~SQLiteTxn() { try { if (active && sqlite3_exec(db, "rollback;", 0, 0, 0) != SQLITE_OK) SQLiteError::throw_(db, "aborting transaction"); } catch (...) { ignoreException(); } } void handleSQLiteBusy(const SQLiteBusy & e, time_t & nextWarning) { time_t now = time(0); if (now > nextWarning) { nextWarning = now + 10; logWarning({ .msg = hintfmt(e.what()) }); } /* Sleep for a while since retrying the transaction right away is likely to fail again. */ checkInterrupt(); struct timespec t; t.tv_sec = 0; t.tv_nsec = (random() % 100) * 1000 * 1000; /* <= 0.1s */ nanosleep(&t, 0); } }