freebsd-skq/usr.sbin/nscd/mp_ws_query.c
ume e14f1c3b3b - Extend the nsswitch to support Services, Protocols and Rpc
databases.
- Make nsswitch support caching.

Submitted by:	Michael Bushkov <bushman__at__rsu.ru>
Sponsored by:	Google Summer of Code 2005
2006-04-28 12:03:38 +00:00

549 lines
17 KiB
C

/*-
* Copyright (c) 2005 Michael Bushkov <bushman@rsu.ru>
* 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.
*
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/socket.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/event.h>
#include <assert.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include "cachelib.h"
#include "config.h"
#include "debug.h"
#include "log.h"
#include "query.h"
#include "mp_ws_query.h"
#include "singletons.h"
static int on_mp_write_session_abandon_notification(struct query_state *);
static int on_mp_write_session_close_notification(struct query_state *);
static void on_mp_write_session_destroy(struct query_state *);
static int on_mp_write_session_mapper(struct query_state *);
/* int on_mp_write_session_request_read1(struct query_state *); */
static int on_mp_write_session_request_read2(struct query_state *);
static int on_mp_write_session_request_process(struct query_state *);
static int on_mp_write_session_response_write1(struct query_state *);
static int on_mp_write_session_write_request_read1(struct query_state *);
static int on_mp_write_session_write_request_read2(struct query_state *);
static int on_mp_write_session_write_request_process(struct query_state *);
static int on_mp_write_session_write_response_write1(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_write_session_destroy(struct query_state *qstate)
{
TRACE_IN(on_mp_write_session_destroy);
finalize_comm_element(&qstate->request);
finalize_comm_element(&qstate->response);
if (qstate->mdata != NULL) {
configuration_lock_entry(qstate->config_entry, CELT_MULTIPART);
abandon_cache_mp_write_session(
(cache_mp_write_session)qstate->mdata);
configuration_unlock_entry(qstate->config_entry,
CELT_MULTIPART);
}
TRACE_OUT(on_mp_write_session_destroy);
}
/*
* The functions below are used to process multipart write session initiation
* requests.
* - on_mp_write_session_request_read1 and on_mp_write_session_request_read2
* read the request itself
* - on_mp_write_session_request_process processes it
* - on_mp_write_session_response_write1 sends the response
*/
int
on_mp_write_session_request_read1(struct query_state *qstate)
{
struct cache_mp_write_session_request *c_mp_ws_request;
ssize_t result;
TRACE_IN(on_mp_write_session_request_read1);
if (qstate->kevent_watermark == 0)
qstate->kevent_watermark = sizeof(size_t);
else {
init_comm_element(&qstate->request,
CET_MP_WRITE_SESSION_REQUEST);
c_mp_ws_request = get_cache_mp_write_session_request(
&qstate->request);
result = qstate->read_func(qstate,
&c_mp_ws_request->entry_length, sizeof(size_t));
if (result != sizeof(size_t)) {
LOG_ERR_3("on_mp_write_session_request_read1",
"read failed");
TRACE_OUT(on_mp_write_session_request_read1);
return (-1);
}
if (BUFSIZE_INVALID(c_mp_ws_request->entry_length)) {
LOG_ERR_3("on_mp_write_session_request_read1",
"invalid entry_length value");
TRACE_OUT(on_mp_write_session_request_read1);
return (-1);
}
c_mp_ws_request->entry = (char *)malloc(
c_mp_ws_request->entry_length + 1);
assert(c_mp_ws_request->entry != NULL);
memset(c_mp_ws_request->entry, 0,
c_mp_ws_request->entry_length + 1);
qstate->kevent_watermark = c_mp_ws_request->entry_length;
qstate->process_func = on_mp_write_session_request_read2;
}
TRACE_OUT(on_mp_write_session_request_read1);
return (0);
}
static int
on_mp_write_session_request_read2(struct query_state *qstate)
{
struct cache_mp_write_session_request *c_mp_ws_request;
ssize_t result;
TRACE_IN(on_mp_write_session_request_read2);
c_mp_ws_request = get_cache_mp_write_session_request(&qstate->request);
result = qstate->read_func(qstate, c_mp_ws_request->entry,
c_mp_ws_request->entry_length);
if (result != qstate->kevent_watermark) {
LOG_ERR_3("on_mp_write_session_request_read2",
"read failed");
TRACE_OUT(on_mp_write_session_request_read2);
return (-1);
}
qstate->kevent_watermark = 0;
qstate->process_func = on_mp_write_session_request_process;
TRACE_OUT(on_mp_write_session_request_read2);
return (0);
}
static int
on_mp_write_session_request_process(struct query_state *qstate)
{
struct cache_mp_write_session_request *c_mp_ws_request;
struct cache_mp_write_session_response *c_mp_ws_response;
cache_mp_write_session ws;
cache_entry c_entry;
char *dec_cache_entry_name;
TRACE_IN(on_mp_write_session_request_process);
init_comm_element(&qstate->response, CET_MP_WRITE_SESSION_RESPONSE);
c_mp_ws_response = get_cache_mp_write_session_response(
&qstate->response);
c_mp_ws_request = get_cache_mp_write_session_request(&qstate->request);
qstate->config_entry = configuration_find_entry(
s_configuration, c_mp_ws_request->entry);
if (qstate->config_entry == NULL) {
c_mp_ws_response->error_code = ENOENT;
LOG_ERR_2("write_session_request",
"can't find configuration entry '%s'. "
"aborting request", c_mp_ws_request->entry);
goto fin;
}
if (qstate->config_entry->enabled == 0) {
c_mp_ws_response->error_code = EACCES;
LOG_ERR_2("write_session_request",
"configuration entry '%s' is disabled",
c_mp_ws_request->entry);
goto fin;
}
if (qstate->config_entry->perform_actual_lookups != 0) {
c_mp_ws_response->error_code = EOPNOTSUPP;
LOG_ERR_2("write_session_request",
"entry '%s' performs lookups by itself: "
"can't write to it", c_mp_ws_request->entry);
goto fin;
} else {
#ifdef NS_CACHED_EID_CHECKING
if (check_query_eids(qstate) != 0) {
c_mp_ws_response->error_code = EPERM;
goto fin;
}
#endif
}
/*
* All multipart entries are separated by their name decorations.
* For one configuration entry there will be a lot of multipart
* cache entries - each with its own decorated name.
*/
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_ENTRY)
c_entry = register_new_mp_cache_entry(qstate,
dec_cache_entry_name);
free(dec_cache_entry_name);
assert(c_entry != NULL);
configuration_lock_entry(qstate->config_entry, CELT_MULTIPART);
ws = open_cache_mp_write_session(c_entry);
if (ws == INVALID_CACHE_MP_WRITE_SESSION)
c_mp_ws_response->error_code = -1;
else {
qstate->mdata = ws;
qstate->destroy_func = on_mp_write_session_destroy;
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);
fin:
qstate->process_func = on_mp_write_session_response_write1;
qstate->kevent_watermark = sizeof(int);
qstate->kevent_filter = EVFILT_WRITE;
TRACE_OUT(on_mp_write_session_request_process);
return (0);
}
static int
on_mp_write_session_response_write1(struct query_state *qstate)
{
struct cache_mp_write_session_response *c_mp_ws_response;
ssize_t result;
TRACE_IN(on_mp_write_session_response_write1);
c_mp_ws_response = get_cache_mp_write_session_response(
&qstate->response);
result = qstate->write_func(qstate, &c_mp_ws_response->error_code,
sizeof(int));
if (result != sizeof(int)) {
LOG_ERR_3("on_mp_write_session_response_write1",
"write failed");
TRACE_OUT(on_mp_write_session_response_write1);
return (-1);
}
if (c_mp_ws_response->error_code == 0) {
qstate->kevent_watermark = sizeof(int);
qstate->process_func = on_mp_write_session_mapper;
qstate->kevent_filter = EVFILT_READ;
} else {
qstate->kevent_watermark = 0;
qstate->process_func = NULL;
}
TRACE_OUT(on_mp_write_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_write_session_mapper(struct query_state *qstate)
{
ssize_t result;
int elem_type;
TRACE_IN(on_mp_write_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_write_session_mapper",
"read failed");
TRACE_OUT(on_mp_write_session_mapper);
return (-1);
}
switch (elem_type) {
case CET_MP_WRITE_SESSION_WRITE_REQUEST:
qstate->kevent_watermark = sizeof(size_t);
qstate->process_func =
on_mp_write_session_write_request_read1;
break;
case CET_MP_WRITE_SESSION_ABANDON_NOTIFICATION:
qstate->kevent_watermark = 0;
qstate->process_func =
on_mp_write_session_abandon_notification;
break;
case CET_MP_WRITE_SESSION_CLOSE_NOTIFICATION:
qstate->kevent_watermark = 0;
qstate->process_func =
on_mp_write_session_close_notification;
break;
default:
qstate->kevent_watermark = 0;
qstate->process_func = NULL;
LOG_ERR_2("on_mp_write_session_mapper",
"unknown element type");
TRACE_OUT(on_mp_write_session_mapper);
return (-1);
}
}
TRACE_OUT(on_mp_write_session_mapper);
return (0);
}
/*
* The functions below are used to process multipart write sessions write
* requests.
* - on_mp_write_session_write_request_read1 and
* on_mp_write_session_write_request_read2 read the request itself
* - on_mp_write_session_write_request_process processes it
* - on_mp_write_session_write_response_write1 sends the response
*/
static int
on_mp_write_session_write_request_read1(struct query_state *qstate)
{
struct cache_mp_write_session_write_request *write_request;
ssize_t result;
TRACE_IN(on_mp_write_session_write_request_read1);
init_comm_element(&qstate->request,
CET_MP_WRITE_SESSION_WRITE_REQUEST);
write_request = get_cache_mp_write_session_write_request(
&qstate->request);
result = qstate->read_func(qstate, &write_request->data_size,
sizeof(size_t));
if (result != sizeof(size_t)) {
LOG_ERR_3("on_mp_write_session_write_request_read1",
"read failed");
TRACE_OUT(on_mp_write_session_write_request_read1);
return (-1);
}
if (BUFSIZE_INVALID(write_request->data_size)) {
LOG_ERR_3("on_mp_write_session_write_request_read1",
"invalid data_size value");
TRACE_OUT(on_mp_write_session_write_request_read1);
return (-1);
}
write_request->data = (char *)malloc(write_request->data_size);
assert(write_request->data != NULL);
memset(write_request->data, 0, write_request->data_size);
qstate->kevent_watermark = write_request->data_size;
qstate->process_func = on_mp_write_session_write_request_read2;
TRACE_OUT(on_mp_write_session_write_request_read1);
return (0);
}
static int
on_mp_write_session_write_request_read2(struct query_state *qstate)
{
struct cache_mp_write_session_write_request *write_request;
ssize_t result;
TRACE_IN(on_mp_write_session_write_request_read2);
write_request = get_cache_mp_write_session_write_request(
&qstate->request);
result = qstate->read_func(qstate, write_request->data,
write_request->data_size);
if (result != qstate->kevent_watermark) {
LOG_ERR_3("on_mp_write_session_write_request_read2",
"read failed");
TRACE_OUT(on_mp_write_session_write_request_read2);
return (-1);
}
qstate->kevent_watermark = 0;
qstate->process_func = on_mp_write_session_write_request_process;
TRACE_OUT(on_mp_write_session_write_request_read2);
return (0);
}
static int
on_mp_write_session_write_request_process(struct query_state *qstate)
{
struct cache_mp_write_session_write_request *write_request;
struct cache_mp_write_session_write_response *write_response;
TRACE_IN(on_mp_write_session_write_request_process);
init_comm_element(&qstate->response,
CET_MP_WRITE_SESSION_WRITE_RESPONSE);
write_response = get_cache_mp_write_session_write_response(
&qstate->response);
write_request = get_cache_mp_write_session_write_request(
&qstate->request);
configuration_lock_entry(qstate->config_entry, CELT_MULTIPART);
write_response->error_code = cache_mp_write(
(cache_mp_write_session)qstate->mdata,
write_request->data,
write_request->data_size);
configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART);
qstate->kevent_watermark = sizeof(int);
qstate->process_func = on_mp_write_session_write_response_write1;
qstate->kevent_filter = EVFILT_WRITE;
TRACE_OUT(on_mp_write_session_write_request_process);
return (0);
}
static int
on_mp_write_session_write_response_write1(struct query_state *qstate)
{
struct cache_mp_write_session_write_response *write_response;
ssize_t result;
TRACE_IN(on_mp_write_session_write_response_write1);
write_response = get_cache_mp_write_session_write_response(
&qstate->response);
result = qstate->write_func(qstate, &write_response->error_code,
sizeof(int));
if (result != sizeof(int)) {
LOG_ERR_3("on_mp_write_session_write_response_write1",
"write failed");
TRACE_OUT(on_mp_write_session_write_response_write1);
return (-1);
}
if (write_response->error_code == 0) {
finalize_comm_element(&qstate->request);
finalize_comm_element(&qstate->response);
qstate->kevent_watermark = sizeof(int);
qstate->process_func = on_mp_write_session_mapper;
qstate->kevent_filter = EVFILT_READ;
} else {
qstate->kevent_watermark = 0;
qstate->process_func = 0;
}
TRACE_OUT(on_mp_write_session_write_response_write1);
return (0);
}
/*
* Handles abandon notifications. Destroys the session by calling the
* abandon_cache_mp_write_session.
*/
static int
on_mp_write_session_abandon_notification(struct query_state *qstate)
{
TRACE_IN(on_mp_write_session_abandon_notification);
configuration_lock_entry(qstate->config_entry, CELT_MULTIPART);
abandon_cache_mp_write_session((cache_mp_write_session)qstate->mdata);
configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART);
qstate->mdata = INVALID_CACHE_MP_WRITE_SESSION;
qstate->kevent_watermark = 0;
qstate->process_func = NULL;
TRACE_OUT(on_mp_write_session_abandon_notification);
return (0);
}
/*
* Handles close notifications. Commits the session by calling
* the close_cache_mp_write_session.
*/
static int
on_mp_write_session_close_notification(struct query_state *qstate)
{
TRACE_IN(on_mp_write_session_close_notification);
configuration_lock_entry(qstate->config_entry, CELT_MULTIPART);
close_cache_mp_write_session((cache_mp_write_session)qstate->mdata);
configuration_unlock_entry(qstate->config_entry, CELT_MULTIPART);
qstate->mdata = INVALID_CACHE_MP_WRITE_SESSION;
qstate->kevent_watermark = 0;
qstate->process_func = NULL;
TRACE_OUT(on_mp_write_session_close_notification);
return (0);
}
cache_entry register_new_mp_cache_entry(struct query_state *qstate,
const char *dec_cache_entry_name)
{
cache_entry c_entry;
char *en_bkp;
TRACE_IN(register_new_mp_cache_entry);
c_entry = INVALID_CACHE_ENTRY;
configuration_lock_entry(qstate->config_entry, CELT_MULTIPART);
configuration_lock_wrlock(s_configuration);
en_bkp = qstate->config_entry->mp_cache_params.entry_name;
qstate->config_entry->mp_cache_params.entry_name =
(char *)dec_cache_entry_name;
register_cache_entry(s_cache, (struct cache_entry_params *)
&qstate->config_entry->mp_cache_params);
qstate->config_entry->mp_cache_params.entry_name = en_bkp;
configuration_unlock(s_configuration);
configuration_lock_rdlock(s_configuration);
c_entry = find_cache_entry(s_cache,
dec_cache_entry_name);
configuration_unlock(s_configuration);
configuration_entry_add_mp_cache_entry(qstate->config_entry,
c_entry);
configuration_unlock_entry(qstate->config_entry,
CELT_MULTIPART);
TRACE_OUT(register_new_mp_cache_entry);
return (c_entry);
}