/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1997, 1998, 1999, 2000 * Sleepycat Software. All rights reserved. */ #include "db_config.h" #ifndef lint static const char revid[] = "$Id: cxx_table.cpp,v 11.35 2001/01/11 18:19:49 bostic Exp $"; #endif /* not lint */ #include #include #include "db_cxx.h" #include "cxx_int.h" #include "db_int.h" #include "db_page.h" #include "db_ext.h" #include "common_ext.h" //////////////////////////////////////////////////////////////////////// // // // Db // // // //////////////////////////////////////////////////////////////////////// // A truism for the DbEnv object is that there is a valid // DB_ENV handle from the constructor until close(). // After the close, the DB handle is invalid and // no operations are permitted on the Db (other than // destructor). Leaving the Db handle open and not // doing a close is generally considered an error. // // We used to allow Db objects to be closed and reopened. // This implied always keeping a valid DB object, and // coordinating the open objects between Db/DbEnv turned // out to be overly complicated. Now we do not allow this. Db::Db(DbEnv *env, u_int32_t flags) : imp_(0) , env_(env) , construct_error_(0) , flags_(0) , construct_flags_(flags) { if (env_ == 0) flags_ |= DB_CXX_PRIVATE_ENV; initialize(); } // Note: if the user has not closed, we call _destroy_check // to warn against this non-safe programming practice. // We can't close, because the environment may already // be closed/destroyed. // Db::~Db() { DB *db; db = unwrap(this); if (db != NULL) { DbEnv::_destroy_check("Db", 0); cleanup(); } } // private method to initialize during constructor. // initialize must create a backing DB object, // and if that creates a new DB_ENV, it must be tied to a new DbEnv. // If there is an error, construct_error_ is set; this is examined // during open. // int Db::initialize() { u_int32_t cxx_flags; DB *db; int err; DB_ENV *cenv = unwrap(env_); cxx_flags = construct_flags_ & DB_CXX_NO_EXCEPTIONS; // Create a new underlying DB object. // We rely on the fact that if a NULL DB_ENV* is given, // one is allocated by DB. // if ((err = db_create(&db, cenv, construct_flags_ & ~cxx_flags)) != 0) { construct_error_ = err; return (err); } // Associate the DB with this object imp_ = wrap(db); db->cj_internal = this; // Create a new DbEnv from a DB_ENV* if it was created locally. // It is deleted in Db::close(). // if ((flags_ & DB_CXX_PRIVATE_ENV) != 0) env_ = new DbEnv(db->dbenv, cxx_flags); return (0); } // private method to cleanup after destructor or during close. // If the environment was created by this Db object, we optionally // delete it, or return it so the caller can delete it after // last use. // void Db::cleanup() { DB *db = unwrap(this); if (db != NULL) { // extra safety db->cj_internal = 0; imp_ = 0; // we must dispose of the DbEnv object if // we created it. This will be the case // if a NULL DbEnv was passed into the constructor. // The underlying DB_ENV object will be inaccessible // after the close, so we must clean it up now. // if ((flags_ & DB_CXX_PRIVATE_ENV) != 0) { env_->cleanup(); delete env_; env_ = 0; } } construct_error_ = 0; } // Return a tristate value corresponding to whether we should // throw exceptions on errors: // ON_ERROR_RETURN // ON_ERROR_THROW // ON_ERROR_UNKNOWN // int Db::error_policy() { if (env_ != NULL) return (env_->error_policy()); else { // If the env_ is null, that means that the user // did not attach an environment, so the correct error // policy can be deduced from constructor flags // for this Db. // if ((construct_flags_ & DB_CXX_NO_EXCEPTIONS) != 0) { return (ON_ERROR_RETURN); } else { return (ON_ERROR_THROW); } } } int Db::close(u_int32_t flags) { DB *db = unwrap(this); int err; // after a DB->close (no matter if success or failure), // the underlying DB object must not be accessed, // so we clean up in advance. // cleanup(); // It's safe to throw an error after the close, // since our error mechanism does not peer into // the DB* structures. // if ((err = db->close(db, flags)) != 0 && err != DB_INCOMPLETE) DB_ERROR("Db::close", err, error_policy()); return (err); } int Db::cursor(DbTxn *txnid, Dbc **cursorp, u_int32_t flags) { DB *db = unwrap(this); DBC *dbc = 0; int err; if ((err = db->cursor(db, unwrap(txnid), &dbc, flags)) != 0) { DB_ERROR("Db::cursor", err, error_policy()); return (err); } // The following cast implies that Dbc can be no larger than DBC *cursorp = (Dbc*)dbc; return (0); } int Db::del(DbTxn *txnid, Dbt *key, u_int32_t flags) { DB *db = unwrap(this); int err; if ((err = db->del(db, unwrap(txnid), key, flags)) != 0) { // DB_NOTFOUND is a "normal" return, so should not be // thrown as an error // if (err != DB_NOTFOUND) { DB_ERROR("Db::del", err, error_policy()); return (err); } } return (err); } void Db::err(int error, const char *format, ...) { va_list args; DB *db = unwrap(this); va_start(args, format); __db_real_err(db->dbenv, error, 1, 1, format, args); va_end(args); } void Db::errx(const char *format, ...) { va_list args; DB *db = unwrap(this); va_start(args, format); __db_real_err(db->dbenv, 0, 0, 1, format, args); va_end(args); } int Db::fd(int *fdp) { DB *db = unwrap(this); int err; if ((err = db->fd(db, fdp)) != 0) { DB_ERROR("Db::fd", err, error_policy()); return (err); } return (0); } // This is a 'glue' function declared as extern "C" so it will // be compatible with picky compilers that do not allow mixing // of function pointers to 'C' functions with function pointers // to C++ functions. // extern "C" void _db_feedback_intercept_c(DB *db, int opcode, int pct) { Db::_feedback_intercept(db, opcode, pct); } //static void Db::_feedback_intercept(DB *db, int opcode, int pct) { if (db == 0) { DB_ERROR("Db::feedback_callback", EINVAL, ON_ERROR_UNKNOWN); return; } Db *cxxdb = (Db *)db->cj_internal; if (cxxdb == 0) { DB_ERROR("Db::feedback_callback", EINVAL, ON_ERROR_UNKNOWN); return; } if (cxxdb->feedback_callback_ == 0) { DB_ERROR("Db::feedback_callback", EINVAL, cxxdb->error_policy()); return; } (*cxxdb->feedback_callback_)(cxxdb, opcode, pct); } int Db::set_feedback(void (*arg)(Db *, int, int)) { DB *db = unwrap(this); feedback_callback_ = arg; return ((*(db->set_feedback))(db, _db_feedback_intercept_c)); } // This is a 'glue' function declared as extern "C" so it will // be compatible with picky compilers that do not allow mixing // of function pointers to 'C' functions with function pointers // to C++ functions. // extern "C" int _db_append_recno_intercept_c(DB *db, DBT *data, db_recno_t recno) { return (Db::_append_recno_intercept(db, data, recno)); } //static int Db::_append_recno_intercept(DB *db, DBT *data, db_recno_t recno) { int err; if (db == 0) { DB_ERROR("Db::append_recno_callback", EINVAL, ON_ERROR_UNKNOWN); return (EINVAL); } Db *cxxdb = (Db *)db->cj_internal; if (cxxdb == 0) { DB_ERROR("Db::append_recno_callback", EINVAL, ON_ERROR_UNKNOWN); return (EINVAL); } if (cxxdb->append_recno_callback_ == 0) { DB_ERROR("Db::append_recno_callback", EINVAL, cxxdb->error_policy()); return (EINVAL); } // making these copies is slow but portable. // Another alternative is to cast the DBT* manufactured // by the C layer to a Dbt*. It 'should be' safe since // Dbt is a thin shell over DBT, adding no extra data, // but is nonportable, and could lead to errors if anything // were added to the Dbt class. // Dbt cxxdbt; memcpy((DBT *)&cxxdbt, data, sizeof(DBT)); err = (*cxxdb->append_recno_callback_)(cxxdb, &cxxdbt, recno); memcpy(data, (DBT *)&cxxdbt, sizeof(DBT)); return (err); } int Db::set_append_recno(int (*arg)(Db *, Dbt *, db_recno_t)) { DB *db = unwrap(this); append_recno_callback_ = arg; return ((*(db->set_append_recno))(db, _db_append_recno_intercept_c)); } int Db::get(DbTxn *txnid, Dbt *key, Dbt *value, u_int32_t flags) { DB *db = unwrap(this); int err; if ((err = db->get(db, unwrap(txnid), key, value, flags)) != 0) { // DB_NOTFOUND and DB_KEYEMPTY are "normal" returns, // so should not be thrown as an error // if (err != DB_NOTFOUND && err != DB_KEYEMPTY) { DB_ERROR("Db::get", err, error_policy()); return (err); } } return (err); } int Db::get_byteswapped() const { DB *db = (DB *)unwrapConst(this); return (db->get_byteswapped(db)); } DBTYPE Db::get_type() const { DB *db = (DB *)unwrapConst(this); return ((DBTYPE)db->get_type(db)); } int Db::join(Dbc **curslist, Dbc **cursorp, u_int32_t flags) { // Dbc is a "compatible" subclass of DBC - // that is, no virtual functions or even extra data members, // so this cast, although technically non-portable, // "should" always be okay. // DBC **list = (DBC **)(curslist); DB *db = unwrap(this); DBC *dbc = 0; int err; if ((err = db->join(db, list, &dbc, flags)) != 0) { DB_ERROR("Db::join_cursor", err, error_policy()); return (err); } *cursorp = (Dbc*)dbc; return (0); } int Db::key_range(DbTxn *txnid, Dbt *key, DB_KEY_RANGE *results, u_int32_t flags) { DB *db = unwrap(this); int err; if ((err = db->key_range(db, unwrap(txnid), key, results, flags)) != 0) { DB_ERROR("Db::key_range", err, error_policy()); return (err); } return (0); } // If an error occurred during the constructor, report it now. // Otherwise, call the underlying DB->open method. // int Db::open(const char *file, const char *database, DBTYPE type, u_int32_t flags, int mode) { int err; DB *db = unwrap(this); if ((err = construct_error_) != 0) DB_ERROR("Db::open", construct_error_, error_policy()); else if ((err = db->open(db, file, database, type, flags, mode)) != 0) DB_ERROR("Db::open", err, error_policy()); return (err); } int Db::put(DbTxn *txnid, Dbt *key, Dbt *value, u_int32_t flags) { int err; DB *db = unwrap(this); if ((err = db->put(db, unwrap(txnid), key, value, flags)) != 0) { // DB_KEYEXIST is a "normal" return, so should not be // thrown as an error // if (err != DB_KEYEXIST) { DB_ERROR("Db::put", err, error_policy()); return (err); } } return (err); } int Db::rename(const char *file, const char *database, const char *newname, u_int32_t flags) { int err = 0; DB *db = unwrap(this); if (!db) { DB_ERROR("Db::rename", EINVAL, error_policy()); return (EINVAL); } // after a DB->rename (no matter if success or failure), // the underlying DB object must not be accessed, // so we clean up in advance. // cleanup(); if ((err = db->rename(db, file, database, newname, flags)) != 0) { DB_ERROR("Db::rename", err, error_policy()); return (err); } return (0); } int Db::remove(const char *file, const char *database, u_int32_t flags) { int err = 0; DB *db = unwrap(this); if (!db) { DB_ERROR("Db::remove", EINVAL, error_policy()); return (EINVAL); } // after a DB->remove (no matter if success or failure), // the underlying DB object must not be accessed, // so we clean up in advance. // cleanup(); if ((err = db->remove(db, file, database, flags)) != 0) DB_ERROR("Db::remove", err, error_policy()); return (err); } int Db::stat(void *sp, db_malloc_fcn_type db_malloc_fcn, u_int32_t flags) { int err; DB *db = unwrap(this); if (!db) { DB_ERROR("Db::stat", EINVAL, error_policy()); return (EINVAL); } if ((err = db->stat(db, sp, db_malloc_fcn, flags)) != 0) { DB_ERROR("Db::stat", err, error_policy()); return (err); } return (0); } int Db::sync(u_int32_t flags) { int err; DB *db = unwrap(this); if (!db) { DB_ERROR("Db::sync", EINVAL, error_policy()); return (EINVAL); } if ((err = db->sync(db, flags)) != 0 && err != DB_INCOMPLETE) { DB_ERROR("Db::sync", err, error_policy()); return (err); } return (err); } int Db::upgrade(const char *name, u_int32_t flags) { int err; DB *db = unwrap(this); if (!db) { DB_ERROR("Db::upgrade", EINVAL, error_policy()); return (EINVAL); } if ((err = db->upgrade(db, name, flags)) != 0) { DB_ERROR("Db::upgrade", err, error_policy()); return (err); } return (0); } static int _verify_callback_cxx(void *handle, const void *str_arg) { char *str; ostream *out; str = (char *)str_arg; out = (ostream *)handle; (*out) << str; if (out->fail()) return (EIO); return (0); } // This is a 'glue' function declared as extern "C" so it will // be compatible with picky compilers that do not allow mixing // of function pointers to 'C' functions with function pointers // to C++ functions. // extern "C" int _verify_callback_c(void *handle, const void *str_arg) { return (_verify_callback_cxx(handle, str_arg)); } int Db::verify(const char *name, const char *subdb, ostream *ostr, u_int32_t flags) { int err; DB *db = unwrap(this); if (!db) { DB_ERROR("Db::verify", EINVAL, error_policy()); return (EINVAL); } if ((err = __db_verify_internal(db, name, subdb, ostr, _verify_callback_c, flags)) != 0) { DB_ERROR("Db::verify", err, error_policy()); return (err); } return (0); } // This is a variant of the DB_WO_ACCESS macro to define a simple set_ // method calling the underlying C method, but unlike a simple // set method, it may return an error or raise an exception. // Note this macro expects that input _argspec is an argument // list element (e.g. "char *arg") defined in terms of "arg". // #define DB_DB_ACCESS(_name, _argspec) \ \ int Db::set_##_name(_argspec) \ { \ int ret; \ DB *db = unwrap(this); \ \ if ((ret = (*(db->set_##_name))(db, arg)) != 0) { \ DB_ERROR("Db::set_" # _name, ret, error_policy()); \ } \ return (ret); \ } #define DB_DB_ACCESS_NORET(_name, _argspec) \ \ void Db::set_##_name(_argspec) \ { \ DB *db = unwrap(this); \ \ (*(db->set_##_name))(db, arg); \ return; \ } DB_DB_ACCESS(bt_compare, bt_compare_fcn_type arg) DB_DB_ACCESS(bt_maxkey, u_int32_t arg) DB_DB_ACCESS(bt_minkey, u_int32_t arg) DB_DB_ACCESS(bt_prefix, bt_prefix_fcn_type arg) DB_DB_ACCESS(dup_compare, dup_compare_fcn_type arg) DB_DB_ACCESS_NORET(errfile, FILE *arg) DB_DB_ACCESS_NORET(errpfx, const char *arg) DB_DB_ACCESS(flags, u_int32_t arg) DB_DB_ACCESS(h_ffactor, u_int32_t arg) DB_DB_ACCESS(h_hash, h_hash_fcn_type arg) DB_DB_ACCESS(h_nelem, u_int32_t arg) DB_DB_ACCESS(lorder, int arg) DB_DB_ACCESS(malloc, db_malloc_fcn_type arg) DB_DB_ACCESS(pagesize, u_int32_t arg) DB_DB_ACCESS(realloc, db_realloc_fcn_type arg) DB_DB_ACCESS(re_delim, int arg) DB_DB_ACCESS(re_len, u_int32_t arg) DB_DB_ACCESS(re_pad, int arg) DB_DB_ACCESS(re_source, char *arg) DB_DB_ACCESS(q_extentsize, u_int32_t arg) // Here are the set methods that don't fit the above mold. // void Db::set_errcall(void (*arg)(const char *, char *)) { env_->set_errcall(arg); } int Db::set_cachesize(u_int32_t gbytes, u_int32_t bytes, int ncache) { int ret; DB *db = unwrap(this); if ((ret = (*(db->set_cachesize))(db, gbytes, bytes, ncache)) != 0) { DB_ERROR("Db::set_cachesize", ret, error_policy()); } return (ret); } int Db::set_paniccall(void (*callback)(DbEnv *, int)) { return (env_->set_paniccall(callback)); } void Db::set_error_stream(ostream *error_stream) { env_->set_error_stream(error_stream); } //////////////////////////////////////////////////////////////////////// // // // Dbc // // // //////////////////////////////////////////////////////////////////////// // It's private, and should never be called, but VC4.0 needs it resolved // Dbc::~Dbc() { } int Dbc::close() { DBC *cursor = this; int err; if ((err = cursor->c_close(cursor)) != 0) { DB_ERROR("Db::close", err, ON_ERROR_UNKNOWN); return (err); } return (0); } int Dbc::count(db_recno_t *countp, u_int32_t flags_arg) { DBC *cursor = this; int err; if ((err = cursor->c_count(cursor, countp, flags_arg)) != 0) { DB_ERROR("Db::count", err, ON_ERROR_UNKNOWN); return (err); } return (0); } int Dbc::del(u_int32_t flags_arg) { DBC *cursor = this; int err; if ((err = cursor->c_del(cursor, flags_arg)) != 0) { // DB_KEYEMPTY is a "normal" return, so should not be // thrown as an error // if (err != DB_KEYEMPTY) { DB_ERROR("Db::del", err, ON_ERROR_UNKNOWN); return (err); } } return (err); } int Dbc::dup(Dbc** cursorp, u_int32_t flags_arg) { DBC *cursor = this; DBC *new_cursor = 0; int err; if ((err = cursor->c_dup(cursor, &new_cursor, flags_arg)) != 0) { DB_ERROR("Db::dup", err, ON_ERROR_UNKNOWN); return (err); } // The following cast implies that Dbc can be no larger than DBC *cursorp = (Dbc*)new_cursor; return (0); } int Dbc::get(Dbt* key, Dbt *data, u_int32_t flags_arg) { DBC *cursor = this; int err; if ((err = cursor->c_get(cursor, key, data, flags_arg)) != 0) { // DB_NOTFOUND and DB_KEYEMPTY are "normal" returns, // so should not be thrown as an error // if (err != DB_NOTFOUND && err != DB_KEYEMPTY) { DB_ERROR("Db::get", err, ON_ERROR_UNKNOWN); return (err); } } return (err); } int Dbc::put(Dbt* key, Dbt *data, u_int32_t flags_arg) { DBC *cursor = this; int err; if ((err = cursor->c_put(cursor, key, data, flags_arg)) != 0) { // DB_KEYEXIST is a "normal" return, so should not be // thrown as an error // if (err != DB_KEYEXIST) { DB_ERROR("Db::put", err, ON_ERROR_UNKNOWN); return (err); } } return (err); } //////////////////////////////////////////////////////////////////////// // // // Dbt // // // //////////////////////////////////////////////////////////////////////// Dbt::Dbt() { DBT *dbt = this; memset(dbt, 0, sizeof(DBT)); } Dbt::Dbt(void *data_arg, size_t size_arg) { DBT *dbt = this; memset(dbt, 0, sizeof(DBT)); set_data(data_arg); set_size(size_arg); } Dbt::~Dbt() { } Dbt::Dbt(const Dbt &that) { const DBT *from = &that; DBT *to = this; memcpy(to, from, sizeof(DBT)); } Dbt &Dbt::operator = (const Dbt &that) { if (this != &that) { const DBT *from = &that; DBT *to = this; memcpy(to, from, sizeof(DBT)); } return (*this); } DB_RW_ACCESS(Dbt, void *, data, data) DB_RW_ACCESS(Dbt, u_int32_t, size, size) DB_RW_ACCESS(Dbt, u_int32_t, ulen, ulen) DB_RW_ACCESS(Dbt, u_int32_t, dlen, dlen) DB_RW_ACCESS(Dbt, u_int32_t, doff, doff) DB_RW_ACCESS(Dbt, u_int32_t, flags, flags)