/*- * Copyright (c) 2005 Michael Bushkov * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD: src/usr.sbin/nscd/mp_rs_query.c,v 1.4 2008/10/12 00:44:27 delphij Exp $ */ #include #include #include #include #include #include #include #include #include #include "cachelib.h" #include "config.h" #include "debug.h" #include "log.h" #include "query.h" #include "mp_rs_query.h" #include "mp_ws_query.h" #include "singletons.h" static int on_mp_read_session_close_notification(struct query_state *); static void on_mp_read_session_destroy(struct query_state *); static int on_mp_read_session_mapper(struct query_state *); /* int on_mp_read_session_request_read1(struct query_state *); */ static int on_mp_read_session_request_read2(struct query_state *); static int on_mp_read_session_request_process(struct query_state *); static int on_mp_read_session_response_write1(struct query_state *); static int on_mp_read_session_read_request_process(struct query_state *); static int on_mp_read_session_read_response_write1(struct query_state *); static int on_mp_read_session_read_response_write2(struct query_state *); /* * This function is used as the query_state's destroy_func to make the * proper cleanup in case of errors. */ static void on_mp_read_session_destroy(struct query_state *qstate) { TRACE_IN(on_mp_read_session_destroy); finalize_comm_element(&qstate->request); finalize_comm_element(&qstate->response); if (qstate->mdata != NULL) { configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); close_cache_mp_read_session( (cache_mp_read_session)qstate->mdata); configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); } TRACE_OUT(on_mp_read_session_destroy); } /* * The functions below are used to process multipart read session initiation * requests. * - on_mp_read_session_request_read1 and on_mp_read_session_request_read2 read * the request itself * - on_mp_read_session_request_process processes it * - on_mp_read_session_response_write1 sends the response */ int on_mp_read_session_request_read1(struct query_state *qstate) { struct cache_mp_read_session_request *c_mp_rs_request; ssize_t result; TRACE_IN(on_mp_read_session_request_read1); if (qstate->kevent_watermark == 0) qstate->kevent_watermark = sizeof(size_t); else { init_comm_element(&qstate->request, CET_MP_READ_SESSION_REQUEST); c_mp_rs_request = get_cache_mp_read_session_request( &qstate->request); result = qstate->read_func(qstate, &c_mp_rs_request->entry_length, sizeof(size_t)); if (result != sizeof(size_t)) { TRACE_OUT(on_mp_read_session_request_read1); return (-1); } if (BUFSIZE_INVALID(c_mp_rs_request->entry_length)) { TRACE_OUT(on_mp_read_session_request_read1); return (-1); } c_mp_rs_request->entry = (char *)calloc(1, c_mp_rs_request->entry_length + 1); assert(c_mp_rs_request->entry != NULL); qstate->kevent_watermark = c_mp_rs_request->entry_length; qstate->process_func = on_mp_read_session_request_read2; } TRACE_OUT(on_mp_read_session_request_read1); return (0); } static int on_mp_read_session_request_read2(struct query_state *qstate) { struct cache_mp_read_session_request *c_mp_rs_request; ssize_t result; TRACE_IN(on_mp_read_session_request_read2); c_mp_rs_request = get_cache_mp_read_session_request(&qstate->request); result = qstate->read_func(qstate, c_mp_rs_request->entry, c_mp_rs_request->entry_length); if (result != qstate->kevent_watermark) { LOG_ERR_3("on_mp_read_session_request_read2", "read failed"); TRACE_OUT(on_mp_read_session_request_read2); return (-1); } qstate->kevent_watermark = 0; qstate->process_func = on_mp_read_session_request_process; TRACE_OUT(on_mp_read_session_request_read2); return (0); } static int on_mp_read_session_request_process(struct query_state *qstate) { struct cache_mp_read_session_request *c_mp_rs_request; struct cache_mp_read_session_response *c_mp_rs_response; cache_mp_read_session rs; cache_entry c_entry; char *dec_cache_entry_name; char *buffer; size_t buffer_size; cache_mp_write_session ws; struct agent *lookup_agent; struct multipart_agent *mp_agent; void *mdata; int res; TRACE_IN(on_mp_read_session_request_process); init_comm_element(&qstate->response, CET_MP_READ_SESSION_RESPONSE); c_mp_rs_response = get_cache_mp_read_session_response( &qstate->response); c_mp_rs_request = get_cache_mp_read_session_request(&qstate->request); qstate->config_entry = configuration_find_entry( s_configuration, c_mp_rs_request->entry); if (qstate->config_entry == NULL) { c_mp_rs_response->error_code = ENOENT; LOG_ERR_2("read_session_request", "can't find configuration entry '%s'." " aborting request", c_mp_rs_request->entry); goto fin; } if (qstate->config_entry->enabled == 0) { c_mp_rs_response->error_code = EACCES; LOG_ERR_2("read_session_request", "configuration entry '%s' is disabled", c_mp_rs_request->entry); goto fin; } if (qstate->config_entry->perform_actual_lookups != 0) dec_cache_entry_name = strdup( qstate->config_entry->mp_cache_params.entry_name); else { #ifdef NS_NSCD_EID_CHECKING if (check_query_eids(qstate) != 0) { c_mp_rs_response->error_code = EPERM; goto fin; } #endif asprintf(&dec_cache_entry_name, "%s%s", qstate->eid_str, qstate->config_entry->mp_cache_params.entry_name); } assert(dec_cache_entry_name != NULL); configuration_lock_rdlock(s_configuration); c_entry = find_cache_entry(s_cache, dec_cache_entry_name); configuration_unlock(s_configuration); if ((c_entry == INVALID_CACHE) && (qstate->config_entry->perform_actual_lookups != 0)) c_entry = register_new_mp_cache_entry(qstate, dec_cache_entry_name); free(dec_cache_entry_name); if (c_entry != INVALID_CACHE_ENTRY) { configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); rs = open_cache_mp_read_session(c_entry); configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); if ((rs == INVALID_CACHE_MP_READ_SESSION) && (qstate->config_entry->perform_actual_lookups != 0)) { lookup_agent = find_agent(s_agent_table, c_mp_rs_request->entry, MULTIPART_AGENT); if ((lookup_agent != NULL) && (lookup_agent->type == MULTIPART_AGENT)) { mp_agent = (struct multipart_agent *) lookup_agent; mdata = mp_agent->mp_init_func(); /* * Multipart agents read the whole snapshot * of the data at one time. */ configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); ws = open_cache_mp_write_session(c_entry); configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); if (ws != NULL) { do { buffer = NULL; res = mp_agent->mp_lookup_func(&buffer, &buffer_size, mdata); if ((res & NS_TERMINATE) && (buffer != NULL)) { configuration_lock_entry( qstate->config_entry, CELT_MULTIPART); if (cache_mp_write(ws, buffer, buffer_size) != 0) { abandon_cache_mp_write_session(ws); ws = NULL; } configuration_unlock_entry( qstate->config_entry, CELT_MULTIPART); free(buffer); buffer = NULL; } else { configuration_lock_entry( qstate->config_entry, CELT_MULTIPART); close_cache_mp_write_session(ws); configuration_unlock_entry( qstate->config_entry, CELT_MULTIPART); free(buffer); buffer = NULL; } } while ((res & NS_TERMINATE) && (ws != NULL)); } configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); rs = open_cache_mp_read_session(c_entry); configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); } } if (rs == INVALID_CACHE_MP_READ_SESSION) c_mp_rs_response->error_code = -1; else { qstate->mdata = rs; qstate->destroy_func = on_mp_read_session_destroy; configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); if ((qstate->config_entry->mp_query_timeout.tv_sec != 0) || (qstate->config_entry->mp_query_timeout.tv_usec != 0)) memcpy(&qstate->timeout, &qstate->config_entry->mp_query_timeout, sizeof(struct timeval)); configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); } } else c_mp_rs_response->error_code = -1; fin: qstate->process_func = on_mp_read_session_response_write1; qstate->kevent_watermark = sizeof(int); qstate->kevent_filter = EVFILT_WRITE; TRACE_OUT(on_mp_read_session_request_process); return (0); } static int on_mp_read_session_response_write1(struct query_state *qstate) { struct cache_mp_read_session_response *c_mp_rs_response; ssize_t result; TRACE_IN(on_mp_read_session_response_write1); c_mp_rs_response = get_cache_mp_read_session_response( &qstate->response); result = qstate->write_func(qstate, &c_mp_rs_response->error_code, sizeof(int)); if (result != sizeof(int)) { LOG_ERR_3("on_mp_read_session_response_write1", "write failed"); TRACE_OUT(on_mp_read_session_response_write1); return (-1); } if (c_mp_rs_response->error_code == 0) { qstate->kevent_watermark = sizeof(int); qstate->process_func = on_mp_read_session_mapper; qstate->kevent_filter = EVFILT_READ; } else { qstate->kevent_watermark = 0; qstate->process_func = NULL; } TRACE_OUT(on_mp_read_session_response_write1); return (0); } /* * Mapper function is used to avoid multiple connections for each session * write or read requests. After processing the request, it does not close * the connection, but waits for the next request. */ static int on_mp_read_session_mapper(struct query_state *qstate) { ssize_t result; int elem_type; TRACE_IN(on_mp_read_session_mapper); if (qstate->kevent_watermark == 0) { qstate->kevent_watermark = sizeof(int); } else { result = qstate->read_func(qstate, &elem_type, sizeof(int)); if (result != sizeof(int)) { LOG_ERR_3("on_mp_read_session_mapper", "read failed"); TRACE_OUT(on_mp_read_session_mapper); return (-1); } switch (elem_type) { case CET_MP_READ_SESSION_READ_REQUEST: qstate->kevent_watermark = 0; qstate->process_func = on_mp_read_session_read_request_process; break; case CET_MP_READ_SESSION_CLOSE_NOTIFICATION: qstate->kevent_watermark = 0; qstate->process_func = on_mp_read_session_close_notification; break; default: qstate->kevent_watermark = 0; qstate->process_func = NULL; LOG_ERR_3("on_mp_read_session_mapper", "unknown element type"); TRACE_OUT(on_mp_read_session_mapper); return (-1); } } TRACE_OUT(on_mp_read_session_mapper); return (0); } /* * The functions below are used to process multipart read sessions read * requests. User doesn't have to pass any kind of data, besides the * request identificator itself. So we don't need any XXX_read functions and * start with the XXX_process function. * - on_mp_read_session_read_request_process processes it * - on_mp_read_session_read_response_write1 and * on_mp_read_session_read_response_write2 sends the response */ static int on_mp_read_session_read_request_process(struct query_state *qstate) { struct cache_mp_read_session_read_response *read_response; TRACE_IN(on_mp_read_session_response_process); init_comm_element(&qstate->response, CET_MP_READ_SESSION_READ_RESPONSE); read_response = get_cache_mp_read_session_read_response( &qstate->response); configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); read_response->error_code = cache_mp_read( (cache_mp_read_session)qstate->mdata, NULL, &read_response->data_size); if (read_response->error_code == 0) { read_response->data = (char *)malloc(read_response->data_size); assert(read_response != NULL); read_response->error_code = cache_mp_read( (cache_mp_read_session)qstate->mdata, read_response->data, &read_response->data_size); } configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); if (read_response->error_code == 0) qstate->kevent_watermark = sizeof(size_t) + sizeof(int); else qstate->kevent_watermark = sizeof(int); qstate->process_func = on_mp_read_session_read_response_write1; qstate->kevent_filter = EVFILT_WRITE; TRACE_OUT(on_mp_read_session_response_process); return (0); } static int on_mp_read_session_read_response_write1(struct query_state *qstate) { struct cache_mp_read_session_read_response *read_response; ssize_t result; TRACE_IN(on_mp_read_session_read_response_write1); read_response = get_cache_mp_read_session_read_response( &qstate->response); result = qstate->write_func(qstate, &read_response->error_code, sizeof(int)); if (read_response->error_code == 0) { result += qstate->write_func(qstate, &read_response->data_size, sizeof(size_t)); if (result != qstate->kevent_watermark) { TRACE_OUT(on_mp_read_session_read_response_write1); LOG_ERR_3("on_mp_read_session_read_response_write1", "write failed"); return (-1); } qstate->kevent_watermark = read_response->data_size; qstate->process_func = on_mp_read_session_read_response_write2; } else { if (result != qstate->kevent_watermark) { LOG_ERR_3("on_mp_read_session_read_response_write1", "write failed"); TRACE_OUT(on_mp_read_session_read_response_write1); return (-1); } qstate->kevent_watermark = 0; qstate->process_func = NULL; } TRACE_OUT(on_mp_read_session_read_response_write1); return (0); } static int on_mp_read_session_read_response_write2(struct query_state *qstate) { struct cache_mp_read_session_read_response *read_response; ssize_t result; TRACE_IN(on_mp_read_session_read_response_write2); read_response = get_cache_mp_read_session_read_response( &qstate->response); result = qstate->write_func(qstate, read_response->data, read_response->data_size); if (result != qstate->kevent_watermark) { LOG_ERR_3("on_mp_read_session_read_response_write2", "write failed"); TRACE_OUT(on_mp_read_session_read_response_write2); return (-1); } finalize_comm_element(&qstate->request); finalize_comm_element(&qstate->response); qstate->kevent_watermark = sizeof(int); qstate->process_func = on_mp_read_session_mapper; qstate->kevent_filter = EVFILT_READ; TRACE_OUT(on_mp_read_session_read_response_write2); return (0); } /* * Handles session close notification by calling close_cache_mp_read_session * function. */ static int on_mp_read_session_close_notification(struct query_state *qstate) { TRACE_IN(on_mp_read_session_close_notification); configuration_lock_entry(qstate->config_entry, CELT_MULTIPART); close_cache_mp_read_session((cache_mp_read_session)qstate->mdata); configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART); qstate->mdata = NULL; qstate->kevent_watermark = 0; qstate->process_func = NULL; TRACE_OUT(on_mp_read_session_close_notification); return (0); }