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haproxy/src/session.c
Willy Tarreau 38d5892634 OPTIM/MINOR: mark the source address as already known on accept() 
Commit 986a9d2d12 moved the source address from the stream interface
to the session, but it did not set the flag on the connection to
report that the source address is known. Thus when logs are enabled,
we had a call to getpeername() which is redundant with the result
from accept(). This patch simply sets the flag.
2013-11-16 00:17:59 +01:00

3293 lines
109 KiB
C
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/*
* Session management functions.
*
* Copyright 2000-2012 Willy Tarreau <w@1wt.eu>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*
*/
#include <stdlib.h>
#include <unistd.h>
#include <fcntl.h>
#include <common/config.h>
#include <common/buffer.h>
#include <common/debug.h>
#include <common/memory.h>
#include <types/capture.h>
#include <types/global.h>
#include <proto/acl.h>
#include <proto/arg.h>
#include <proto/backend.h>
#include <proto/channel.h>
#include <proto/checks.h>
#include <proto/connection.h>
#include <proto/dumpstats.h>
#include <proto/fd.h>
#include <proto/freq_ctr.h>
#include <proto/frontend.h>
#include <proto/hdr_idx.h>
#include <proto/listener.h>
#include <proto/log.h>
#include <proto/raw_sock.h>
#include <proto/session.h>
#include <proto/pipe.h>
#include <proto/proto_http.h>
#include <proto/proto_tcp.h>
#include <proto/proxy.h>
#include <proto/queue.h>
#include <proto/server.h>
#include <proto/sample.h>
#include <proto/stick_table.h>
#include <proto/stream_interface.h>
#include <proto/task.h>
struct pool_head *pool2_session;
struct list sessions;
static int conn_session_complete(struct connection *conn);
static int conn_session_update(struct connection *conn);
static struct task *expire_mini_session(struct task *t);
int session_complete(struct session *s);
/* data layer callbacks for an embryonic session */
struct data_cb sess_conn_cb = {
.recv = NULL,
.send = NULL,
.wake = conn_session_update,
.init = conn_session_complete,
};
/* This function is called from the protocol layer accept() in order to
* instanciate a new embryonic session on behalf of a given listener and
* frontend. It returns a positive value upon success, 0 if the connection
* can be ignored, or a negative value upon critical failure. The accepted
* file descriptor is closed if we return <= 0.
*/
int session_accept(struct listener *l, int cfd, struct sockaddr_storage *addr)
{
struct proxy *p = l->frontend;
struct session *s;
struct task *t;
int ret;
ret = -1; /* assume unrecoverable error by default */
if (unlikely((s = pool_alloc2(pool2_session)) == NULL))
goto out_close;
if (unlikely((s->si[0].conn = pool_alloc2(pool2_connection)) == NULL))
goto out_fail_conn0;
if (unlikely((s->si[1].conn = pool_alloc2(pool2_connection)) == NULL))
goto out_fail_conn1;
/* minimum session initialization required for an embryonic session is
* fairly low. We need very little to execute L4 ACLs, then we need a
* task to make the client-side connection live on its own.
* - flags
* - stick-entry tracking
*/
s->flags = 0;
s->logs.logwait = p->to_log;
s->logs.level = 0;
memset(s->stkctr, 0, sizeof(s->stkctr));
s->listener = l;
s->fe = p;
/* OK, we're keeping the session, so let's properly initialize the session */
s->si[0].conn->t.sock.fd = cfd;
s->si[0].conn->ctrl = l->proto;
s->si[0].conn->flags = CO_FL_NONE | CO_FL_ADDR_FROM_SET;
s->si[0].conn->err_code = CO_ER_NONE;
s->si[0].conn->addr.from = *addr;
s->si[0].conn->target = &l->obj_type;
s->logs.accept_date = date; /* user-visible date for logging */
s->logs.tv_accept = now; /* corrected date for internal use */
s->uniq_id = totalconn;
p->feconn++;
/* This session was accepted, count it now */
if (p->feconn > p->fe_counters.conn_max)
p->fe_counters.conn_max = p->feconn;
proxy_inc_fe_conn_ctr(l, p);
/* now evaluate the tcp-request layer4 rules. Since we expect to be able
* to abort right here as soon as possible, we check the rules before
* even initializing the stream interfaces.
*/
if ((l->options & LI_O_TCP_RULES) && !tcp_exec_req_rules(s)) {
/* let's do a no-linger now to close with a single RST. */
setsockopt(cfd, SOL_SOCKET, SO_LINGER, (struct linger *) &nolinger, sizeof(struct linger));
ret = 0; /* successful termination */
goto out_free_session;
}
#ifndef USE_ACCEPT4
/* Adjust some socket options if the connection was accepted by a plain
* accept() syscall.
*/
if (unlikely(fcntl(cfd, F_SETFL, O_NONBLOCK) == -1))
goto out_free_session;
#endif
/* monitor-net and health mode are processed immediately after TCP
* connection rules. This way it's possible to block them, but they
* never use the lower data layers, they send directly over the socket,
* as they were designed for. We first flush the socket receive buffer
* in order to avoid emission of an RST by the system. We ignore any
* error.
*/
if (unlikely((p->mode == PR_MODE_HEALTH) ||
((l->options & LI_O_CHK_MONNET) &&
addr->ss_family == AF_INET &&
(((struct sockaddr_in *)addr)->sin_addr.s_addr & p->mon_mask.s_addr) == p->mon_net.s_addr))) {
/* we have 4 possibilities here :
* - HTTP mode, from monitoring address => send "HTTP/1.0 200 OK"
* - HEALTH mode with HTTP check => send "HTTP/1.0 200 OK"
* - HEALTH mode without HTTP check => just send "OK"
* - TCP mode from monitoring address => just close
*/
if (l->proto->drain)
l->proto->drain(cfd);
if (p->mode == PR_MODE_HTTP ||
(p->mode == PR_MODE_HEALTH && (p->options2 & PR_O2_CHK_ANY) == PR_O2_HTTP_CHK))
send(cfd, "HTTP/1.0 200 OK\r\n\r\n", 19, MSG_DONTWAIT|MSG_NOSIGNAL|MSG_MORE);
else if (p->mode == PR_MODE_HEALTH)
send(cfd, "OK\n", 3, MSG_DONTWAIT|MSG_NOSIGNAL|MSG_MORE);
ret = 0;
goto out_free_session;
}
/* wait for a PROXY protocol header */
if (l->options & LI_O_ACC_PROXY) {
s->si[0].conn->flags |= CO_FL_ACCEPT_PROXY;
conn_sock_want_recv(s->si[0].conn);
}
if (unlikely((t = task_new()) == NULL))
goto out_free_session;
t->context = s;
t->nice = l->nice;
s->task = t;
/* Add the various callbacks. Right now the transport layer is present
* but not initialized. Also note we need to be careful as the stream
* int is not initialized yet.
*/
conn_prepare(s->si[0].conn, &sess_conn_cb, l->proto, l->xprt, s);
/* finish initialization of the accepted file descriptor */
fd_insert(cfd);
fdtab[cfd].owner = s->si[0].conn;
fdtab[cfd].iocb = conn_fd_handler;
conn_data_want_recv(s->si[0].conn);
if (conn_xprt_init(s->si[0].conn) < 0)
goto out_free_task;
/* OK, now either we have a pending handshake to execute with and
* then we must return to the I/O layer, or we can proceed with the
* end of the session initialization. In case of handshake, we also
* set the I/O timeout to the frontend's client timeout.
*/
if (s->si[0].conn->flags & CO_FL_HANDSHAKE) {
t->process = expire_mini_session;
t->expire = tick_add_ifset(now_ms, p->timeout.client);
task_queue(t);
s->si[0].conn->flags |= CO_FL_INIT_DATA | CO_FL_WAKE_DATA;
return 1;
}
/* OK let's complete session initialization since there is no handshake */
s->si[0].conn->flags |= CO_FL_CONNECTED;
ret = session_complete(s);
if (ret > 0)
return ret;
/* Error unrolling */
out_free_task:
task_free(t);
out_free_session:
p->feconn--;
if (s->stkctr[0].entry || s->stkctr[1].entry)
session_store_counters(s);
pool_free2(pool2_connection, s->si[1].conn);
out_fail_conn1:
pool_free2(pool2_connection, s->si[0].conn);
out_fail_conn0:
pool_free2(pool2_session, s);
out_close:
if (ret < 0 && l->xprt == &raw_sock && p->mode == PR_MODE_HTTP) {
/* critical error, no more memory, try to emit a 500 response */
struct chunk *err_msg = &p->errmsg[HTTP_ERR_500];
if (!err_msg->str)
err_msg = &http_err_chunks[HTTP_ERR_500];
send(cfd, err_msg->str, err_msg->len, MSG_DONTWAIT|MSG_NOSIGNAL);
}
if (fdtab[cfd].owner)
fd_delete(cfd);
else
close(cfd);
return ret;
}
/* prepare the trash with a log prefix for session <s> */
static void prepare_mini_sess_log_prefix(struct session *s)
{
struct tm tm;
char pn[INET6_ADDRSTRLEN];
int ret;
char *end;
ret = addr_to_str(&s->si[0].conn->addr.from, pn, sizeof(pn));
if (ret <= 0)
chunk_printf(&trash, "unknown [");
else if (ret == AF_UNIX)
chunk_printf(&trash, "%s:%d [", pn, s->listener->luid);
else
chunk_printf(&trash, "%s:%d [", pn, get_host_port(&s->si[0].conn->addr.from));
get_localtime(s->logs.accept_date.tv_sec, &tm);
end = date2str_log(trash.str + trash.len, &tm, &(s->logs.accept_date), trash.size - trash.len);
trash.len = end - trash.str;
if (s->listener->name)
chunk_appendf(&trash, "] %s/%s", s->fe->id, s->listener->name);
else
chunk_appendf(&trash, "] %s/%d", s->fe->id, s->listener->luid);
}
/* This function kills an existing embryonic session. It stops the connection's
* transport layer, releases assigned resources, resumes the listener if it was
* disabled and finally kills the file descriptor.
*/
static void kill_mini_session(struct session *s)
{
int level = LOG_INFO;
struct connection *conn = s->si[0].conn;
unsigned int log = s->logs.logwait;
const char *err_msg;
if (s->fe->options2 & PR_O2_LOGERRORS)
level = LOG_ERR;
if (log && (s->fe->options & PR_O_NULLNOLOG)) {
/* with "option dontlognull", we don't log connections with no transfer */
if (!conn->err_code ||
conn->err_code == CO_ER_PRX_EMPTY || conn->err_code == CO_ER_PRX_ABORT ||
conn->err_code == CO_ER_SSL_EMPTY || conn->err_code == CO_ER_SSL_ABORT)
log = 0;
}
if (log) {
if (!conn->err_code && (s->task->state & TASK_WOKEN_TIMER)) {
if (conn->flags & CO_FL_ACCEPT_PROXY)
conn->err_code = CO_ER_PRX_TIMEOUT;
else if (conn->flags & CO_FL_SSL_WAIT_HS)
conn->err_code = CO_ER_SSL_TIMEOUT;
}
prepare_mini_sess_log_prefix(s);
err_msg = conn_err_code_str(conn);
if (err_msg)
send_log(s->fe, level, "%s: %s\n", trash.str, err_msg);
else
send_log(s->fe, level, "%s: unknown connection error (code=%d flags=%08x)\n",
trash.str, conn->err_code, conn->flags);
}
/* kill the connection now */
conn_full_close(s->si[0].conn);
s->fe->feconn--;
session_store_counters(s);
if (!(s->listener->options & LI_O_UNLIMITED))
actconn--;
jobs--;
s->listener->nbconn--;
if (s->listener->state == LI_FULL)
resume_listener(s->listener);
/* Dequeues all of the listeners waiting for a resource */
if (!LIST_ISEMPTY(&global_listener_queue))
dequeue_all_listeners(&global_listener_queue);
if (!LIST_ISEMPTY(&s->fe->listener_queue) &&
(!s->fe->fe_sps_lim || freq_ctr_remain(&s->fe->fe_sess_per_sec, s->fe->fe_sps_lim, 0) > 0))
dequeue_all_listeners(&s->fe->listener_queue);
task_delete(s->task);
task_free(s->task);
pool_free2(pool2_connection, s->si[1].conn);
pool_free2(pool2_connection, s->si[0].conn);
pool_free2(pool2_session, s);
}
/* Finish initializing a session from a connection, or kills it if the
* connection shows and error. Returns <0 if the connection was killed.
*/
static int conn_session_complete(struct connection *conn)
{
struct session *s = conn->owner;
if (!(conn->flags & CO_FL_ERROR) && (session_complete(s) > 0)) {
conn->flags &= ~CO_FL_INIT_DATA;
return 0;
}
/* kill the connection now */
kill_mini_session(s);
return -1;
}
/* Update an embryonic session status. The connection is killed in case of
* error, and <0 will be returned. Otherwise it does nothing.
*/
static int conn_session_update(struct connection *conn)
{
if (conn->flags & CO_FL_ERROR) {
kill_mini_session(conn->owner);
return -1;
}
return 0;
}
/* Manages embryonic sessions timeout. It is only called when the timeout
* strikes and performs the required cleanup.
*/
static struct task *expire_mini_session(struct task *t)
{
struct session *s = t->context;
if (!(t->state & TASK_WOKEN_TIMER))
return t;
kill_mini_session(s);
return NULL;
}
/* This function is called from the I/O handler which detects the end of
* handshake, in order to complete initialization of a valid session. It must
* be called with an embryonic session. It returns a positive value upon
* success, 0 if the connection can be ignored, or a negative value upon
* critical failure. The accepted file descriptor is closed if we return <= 0.
*/
int session_complete(struct session *s)
{
struct listener *l = s->listener;
struct proxy *p = s->fe;
struct http_txn *txn;
struct task *t = s->task;
int ret;
int i;
ret = -1; /* assume unrecoverable error by default */
/* OK, we're keeping the session, so let's properly initialize the session */
LIST_ADDQ(&sessions, &s->list);
LIST_INIT(&s->back_refs);
si_takeover_conn(&s->si[0], l->proto, l->xprt);
s->flags |= SN_INITIALIZED;
s->unique_id = NULL;
t->process = l->handler;
t->context = s;
t->expire = TICK_ETERNITY;
/* Note: initially, the session's backend points to the frontend.
* This changes later when switching rules are executed or
* when the default backend is assigned.
*/
s->be = s->fe;
s->req = s->rep = NULL; /* will be allocated later */
s->comp_algo = NULL;
/* Let's count a session now */
proxy_inc_fe_sess_ctr(l, p);
for (i = 0; i < MAX_SESS_STKCTR; i++) {
void *ptr;
if (!s->stkctr[i].entry)
continue;
ptr = stktable_data_ptr(s->stkctr[i].table, s->stkctr[i].entry, STKTABLE_DT_SESS_CNT);
if (ptr)
stktable_data_cast(ptr, sess_cnt)++;
ptr = stktable_data_ptr(s->stkctr[i].table, s->stkctr[i].entry, STKTABLE_DT_SESS_RATE);
if (ptr)
update_freq_ctr_period(&stktable_data_cast(ptr, sess_rate),
s->stkctr[i].table->data_arg[STKTABLE_DT_SESS_RATE].u, 1);
}
/* this part should be common with other protocols */
s->si[0].owner = t;
s->si[0].state = s->si[0].prev_state = SI_ST_EST;
s->si[0].err_type = SI_ET_NONE;
s->si[0].err_loc = NULL;
s->si[0].release = NULL;
s->si[0].send_proxy_ofs = 0;
s->si[0].exp = TICK_ETERNITY;
s->si[0].flags = SI_FL_NONE;
if (likely(s->fe->options2 & PR_O2_INDEPSTR))
s->si[0].flags |= SI_FL_INDEP_STR;
/* pre-initialize the other side's stream interface to an INIT state. The
* callbacks will be initialized before attempting to connect.
*/
s->si[1].conn->t.sock.fd = -1; /* just to help with debugging */
s->si[1].conn->flags = CO_FL_NONE;
s->si[1].conn->err_code = CO_ER_NONE;
s->si[1].owner = t;
s->si[1].state = s->si[1].prev_state = SI_ST_INI;
s->si[1].err_type = SI_ET_NONE;
s->si[1].conn_retries = 0; /* used for logging too */
s->si[1].err_loc = NULL;
s->si[1].release = NULL;
s->si[1].send_proxy_ofs = 0;
s->si[1].conn->target = NULL;
si_prepare_embedded(&s->si[1]);
s->si[1].exp = TICK_ETERNITY;
s->si[1].flags = SI_FL_NONE;
if (likely(s->fe->options2 & PR_O2_INDEPSTR))
s->si[1].flags |= SI_FL_INDEP_STR;
session_init_srv_conn(s);
s->target = NULL;
s->pend_pos = NULL;
/* init store persistence */
s->store_count = 0;
if (unlikely((s->req = pool_alloc2(pool2_channel)) == NULL))
goto out_free_task; /* no memory */
if (unlikely((s->req->buf = pool_alloc2(pool2_buffer)) == NULL))
goto out_free_req; /* no memory */
if (unlikely((s->rep = pool_alloc2(pool2_channel)) == NULL))
goto out_free_req_buf; /* no memory */
if (unlikely((s->rep->buf = pool_alloc2(pool2_buffer)) == NULL))
goto out_free_rep; /* no memory */
/* initialize the request buffer */
s->req->buf->size = global.tune.bufsize;
channel_init(s->req);
s->req->prod = &s->si[0];
s->req->cons = &s->si[1];
s->si[0].ib = s->si[1].ob = s->req;
s->req->flags |= CF_READ_ATTACHED; /* the producer is already connected */
/* activate default analysers enabled for this listener */
s->req->analysers = l->analysers;
s->req->wto = TICK_ETERNITY;
s->req->rto = TICK_ETERNITY;
s->req->rex = TICK_ETERNITY;
s->req->wex = TICK_ETERNITY;
s->req->analyse_exp = TICK_ETERNITY;
/* initialize response buffer */
s->rep->buf->size = global.tune.bufsize;
channel_init(s->rep);
s->rep->prod = &s->si[1];
s->rep->cons = &s->si[0];
s->si[0].ob = s->si[1].ib = s->rep;
s->rep->analysers = 0;
if (s->fe->options2 & PR_O2_NODELAY) {
s->req->flags |= CF_NEVER_WAIT;
s->rep->flags |= CF_NEVER_WAIT;
}
s->rep->rto = TICK_ETERNITY;
s->rep->wto = TICK_ETERNITY;
s->rep->rex = TICK_ETERNITY;
s->rep->wex = TICK_ETERNITY;
s->rep->analyse_exp = TICK_ETERNITY;
txn = &s->txn;
/* Those variables will be checked and freed if non-NULL in
* session.c:session_free(). It is important that they are
* properly initialized.
*/
txn->sessid = NULL;
txn->srv_cookie = NULL;
txn->cli_cookie = NULL;
txn->uri = NULL;
txn->req.cap = NULL;
txn->rsp.cap = NULL;
txn->hdr_idx.v = NULL;
txn->hdr_idx.size = txn->hdr_idx.used = 0;
txn->req.flags = 0;
txn->rsp.flags = 0;
/* the HTTP messages need to know what buffer they're associated with */
txn->req.chn = s->req;
txn->rsp.chn = s->rep;
/* finish initialization of the accepted file descriptor */
conn_data_want_recv(s->si[0].conn);
if (p->accept && (ret = p->accept(s)) <= 0) {
/* Either we had an unrecoverable error (<0) or work is
* finished (=0, eg: monitoring), in both situations,
* we can release everything and close.
*/
goto out_free_rep_buf;
}
/* if logs require transport layer information, note it on the connection */
if (s->logs.logwait & LW_XPRT)
s->si[0].conn->flags |= CO_FL_XPRT_TRACKED;
/* we want the connection handler to notify the stream interface about updates. */
s->si[0].conn->flags |= CO_FL_WAKE_DATA;
/* it is important not to call the wakeup function directly but to
* pass through task_wakeup(), because this one knows how to apply
* priorities to tasks.
*/
task_wakeup(t, TASK_WOKEN_INIT);
return 1;
/* Error unrolling */
out_free_rep_buf:
pool_free2(pool2_buffer, s->rep->buf);
out_free_rep:
pool_free2(pool2_channel, s->rep);
out_free_req_buf:
pool_free2(pool2_buffer, s->req->buf);
out_free_req:
pool_free2(pool2_channel, s->req);
out_free_task:
return ret;
}
/*
* frees the context associated to a session. It must have been removed first.
*/
static void session_free(struct session *s)
{
struct http_txn *txn = &s->txn;
struct proxy *fe = s->fe;
struct bref *bref, *back;
int i;
if (s->pend_pos)
pendconn_free(s->pend_pos);
if (objt_server(s->target)) { /* there may be requests left pending in queue */
if (s->flags & SN_CURR_SESS) {
s->flags &= ~SN_CURR_SESS;
objt_server(s->target)->cur_sess--;
}
if (may_dequeue_tasks(objt_server(s->target), s->be))
process_srv_queue(objt_server(s->target));
}
if (unlikely(s->srv_conn)) {
/* the session still has a reserved slot on a server, but
* it should normally be only the same as the one above,
* so this should not happen in fact.
*/
sess_change_server(s, NULL);
}
if (s->flags & SN_COMP_READY)
s->comp_algo->end(&s->comp_ctx);
s->comp_algo = NULL;
s->flags &= ~SN_COMP_READY;
if (s->req->pipe)
put_pipe(s->req->pipe);
if (s->rep->pipe)
put_pipe(s->rep->pipe);
pool_free2(pool2_buffer, s->req->buf);
pool_free2(pool2_buffer, s->rep->buf);
pool_free2(pool2_channel, s->req);
pool_free2(pool2_channel, s->rep);
http_end_txn(s);
/* ensure the client-side transport layer is destroyed */
s->si[0].conn->flags &= ~CO_FL_XPRT_TRACKED;
conn_full_close(s->si[0].conn);
for (i = 0; i < s->store_count; i++) {
if (!s->store[i].ts)
continue;
stksess_free(s->store[i].table, s->store[i].ts);
s->store[i].ts = NULL;
}
pool_free2(pool2_hdr_idx, txn->hdr_idx.v);
if (fe) {
pool_free2(fe->rsp_cap_pool, txn->rsp.cap);
pool_free2(fe->req_cap_pool, txn->req.cap);
}
session_store_counters(s);
list_for_each_entry_safe(bref, back, &s->back_refs, users) {
/* we have to unlink all watchers. We must not relink them if
* this session was the last one in the list.
*/
LIST_DEL(&bref->users);
LIST_INIT(&bref->users);
if (s->list.n != &sessions)
LIST_ADDQ(&LIST_ELEM(s->list.n, struct session *, list)->back_refs, &bref->users);
bref->ref = s->list.n;
}
LIST_DEL(&s->list);
pool_free2(pool2_connection, s->si[1].conn);
pool_free2(pool2_connection, s->si[0].conn);
pool_free2(pool2_session, s);
/* We may want to free the maximum amount of pools if the proxy is stopping */
if (fe && unlikely(fe->state == PR_STSTOPPED)) {
pool_flush2(pool2_buffer);
pool_flush2(pool2_channel);
pool_flush2(pool2_hdr_idx);
pool_flush2(pool2_requri);
pool_flush2(pool2_capture);
pool_flush2(pool2_session);
pool_flush2(fe->req_cap_pool);
pool_flush2(fe->rsp_cap_pool);
}
}
/* perform minimal intializations, report 0 in case of error, 1 if OK. */
int init_session()
{
LIST_INIT(&sessions);
pool2_session = create_pool("session", sizeof(struct session), MEM_F_SHARED);
return pool2_session != NULL;
}
void session_process_counters(struct session *s)
{
unsigned long long bytes;
void *ptr;
int i;
if (s->req) {
bytes = s->req->total - s->logs.bytes_in;
s->logs.bytes_in = s->req->total;
if (bytes) {
s->fe->fe_counters.bytes_in += bytes;
s->be->be_counters.bytes_in += bytes;
if (objt_server(s->target))
objt_server(s->target)->counters.bytes_in += bytes;
if (s->listener->counters)
s->listener->counters->bytes_in += bytes;
for (i = 0; i < MAX_SESS_STKCTR; i++) {
if (!s->stkctr[i].entry)
continue;
ptr = stktable_data_ptr(s->stkctr[i].table,
s->stkctr[i].entry,
STKTABLE_DT_BYTES_IN_CNT);
if (ptr)
stktable_data_cast(ptr, bytes_in_cnt) += bytes;
ptr = stktable_data_ptr(s->stkctr[i].table,
s->stkctr[i].entry,
STKTABLE_DT_BYTES_IN_RATE);
if (ptr)
update_freq_ctr_period(&stktable_data_cast(ptr, bytes_in_rate),
s->stkctr[i].table->data_arg[STKTABLE_DT_BYTES_IN_RATE].u, bytes);
}
}
}
if (s->rep) {
bytes = s->rep->total - s->logs.bytes_out;
s->logs.bytes_out = s->rep->total;
if (bytes) {
s->fe->fe_counters.bytes_out += bytes;
s->be->be_counters.bytes_out += bytes;
if (objt_server(s->target))
objt_server(s->target)->counters.bytes_out += bytes;
if (s->listener->counters)
s->listener->counters->bytes_out += bytes;
for (i = 0; i < MAX_SESS_STKCTR; i++) {
if (!s->stkctr[i].entry)
continue;
ptr = stktable_data_ptr(s->stkctr[i].table,
s->stkctr[i].entry,
STKTABLE_DT_BYTES_OUT_CNT);
if (ptr)
stktable_data_cast(ptr, bytes_out_cnt) += bytes;
ptr = stktable_data_ptr(s->stkctr[i].table,
s->stkctr[i].entry,
STKTABLE_DT_BYTES_OUT_RATE);
if (ptr)
update_freq_ctr_period(&stktable_data_cast(ptr, bytes_out_rate),
s->stkctr[i].table->data_arg[STKTABLE_DT_BYTES_OUT_RATE].u, bytes);
}
}
}
}
/* This function is called with (si->state == SI_ST_CON) meaning that a
* connection was attempted and that the file descriptor is already allocated.
* We must check for establishment, error and abort. Possible output states
* are SI_ST_EST (established), SI_ST_CER (error), SI_ST_DIS (abort), and
* SI_ST_CON (no change). The function returns 0 if it switches to SI_ST_CER,
* otherwise 1.
*/
static int sess_update_st_con_tcp(struct session *s, struct stream_interface *si)
{
struct channel *req = si->ob;
struct channel *rep = si->ib;
/* If we got an error, or if nothing happened and the connection timed
* out, we must give up. The CER state handler will take care of retry
* attempts and error reports.
*/
if (unlikely(si->flags & (SI_FL_EXP|SI_FL_ERR))) {
if (unlikely(si->ob->flags & CF_WRITE_PARTIAL)) {
/* Some data were sent past the connection establishment,
* so we need to pretend we're established to log correctly
* and let later states handle the failure.
*/
s->logs.t_connect = tv_ms_elapsed(&s->logs.tv_accept, &now);
si->exp = TICK_ETERNITY;
si->state = SI_ST_EST;
si->err_type = SI_ET_DATA_ERR;
si->ib->flags |= CF_READ_ERROR | CF_WRITE_ERROR;
si->err_loc = objt_server(s->target);
return 1;
}
si->exp = TICK_ETERNITY;
si->state = SI_ST_CER;
si->conn->flags &= ~CO_FL_XPRT_TRACKED;
conn_full_close(si->conn);
if (si->release)
si->release(si);
if (si->err_type)
return 0;
si->err_loc = objt_server(s->target);
if (si->flags & SI_FL_ERR)
si->err_type = SI_ET_CONN_ERR;
else
si->err_type = SI_ET_CONN_TO;
return 0;
}
/* OK, maybe we want to abort */
if (!(req->flags & CF_WRITE_PARTIAL) &&
unlikely((rep->flags & CF_SHUTW) ||
((req->flags & CF_SHUTW_NOW) && /* FIXME: this should not prevent a connection from establishing */
((!(req->flags & CF_WRITE_ACTIVITY) && channel_is_empty(req)) ||
s->be->options & PR_O_ABRT_CLOSE)))) {
/* give up */
si_shutw(si);
si->err_type |= SI_ET_CONN_ABRT;
si->err_loc = objt_server(s->target);
if (s->srv_error)
s->srv_error(s, si);
return 1;
}
/* we need to wait a bit more if there was no activity either */
if (!(req->flags & CF_WRITE_ACTIVITY))
return 1;
/* OK, this means that a connection succeeded. The caller will be
* responsible for handling the transition from CON to EST.
*/
s->logs.t_connect = tv_ms_elapsed(&s->logs.tv_accept, &now);
si->exp = TICK_ETERNITY;
si->state = SI_ST_EST;
si->err_type = SI_ET_NONE;
si->err_loc = NULL;
return 1;
}
/* This function is called with (si->state == SI_ST_CER) meaning that a
* previous connection attempt has failed and that the file descriptor
* has already been released. Possible causes include asynchronous error
* notification and time out. Possible output states are SI_ST_CLO when
* retries are exhausted, SI_ST_TAR when a delay is wanted before a new
* connection attempt, SI_ST_ASS when it's wise to retry on the same server,
* and SI_ST_REQ when an immediate redispatch is wanted. The buffers are
* marked as in error state. It returns 0.
*/
static int sess_update_st_cer(struct session *s, struct stream_interface *si)
{
/* we probably have to release last session from the server */
if (objt_server(s->target)) {
health_adjust(objt_server(s->target), HANA_STATUS_L4_ERR);
if (s->flags & SN_CURR_SESS) {
s->flags &= ~SN_CURR_SESS;
objt_server(s->target)->cur_sess--;
}
}
/* ensure that we have enough retries left */
si->conn_retries--;
if (si->conn_retries < 0) {
if (!si->err_type) {
si->err_type = SI_ET_CONN_ERR;
si->err_loc = objt_server(s->target);
}
if (objt_server(s->target))
objt_server(s->target)->counters.failed_conns++;
s->be->be_counters.failed_conns++;
sess_change_server(s, NULL);
if (may_dequeue_tasks(objt_server(s->target), s->be))
process_srv_queue(objt_server(s->target));
/* shutw is enough so stop a connecting socket */
si_shutw(si);
si->ob->flags |= CF_WRITE_ERROR;
si->ib->flags |= CF_READ_ERROR;
si->state = SI_ST_CLO;
if (s->srv_error)
s->srv_error(s, si);
return 0;
}
/* If the "redispatch" option is set on the backend, we are allowed to
* retry on another server for the last retry. In order to achieve this,
* we must mark the session unassigned, and eventually clear the DIRECT
* bit to ignore any persistence cookie. We won't count a retry nor a
* redispatch yet, because this will depend on what server is selected.
*/
if (objt_server(s->target) && si->conn_retries == 0 &&
s->be->options & PR_O_REDISP && !(s->flags & SN_FORCE_PRST)) {
sess_change_server(s, NULL);
if (may_dequeue_tasks(objt_server(s->target), s->be))
process_srv_queue(objt_server(s->target));
s->flags &= ~(SN_DIRECT | SN_ASSIGNED | SN_ADDR_SET);
si->state = SI_ST_REQ;
} else {
if (objt_server(s->target))
objt_server(s->target)->counters.retries++;
s->be->be_counters.retries++;
si->state = SI_ST_ASS;
}
if (si->flags & SI_FL_ERR) {
/* The error was an asynchronous connection error, and we will
* likely have to retry connecting to the same server, most
* likely leading to the same result. To avoid this, we wait
* one second before retrying.
*/
if (!si->err_type)
si->err_type = SI_ET_CONN_ERR;
si->state = SI_ST_TAR;
si->exp = tick_add(now_ms, MS_TO_TICKS(1000));
return 0;
}
return 0;
}
/*
* This function handles the transition between the SI_ST_CON state and the
* SI_ST_EST state. It must only be called after switching from SI_ST_CON (or
* SI_ST_INI) to SI_ST_EST, but only when a ->proto is defined.
*/
static void sess_establish(struct session *s, struct stream_interface *si)
{
struct channel *req = si->ob;
struct channel *rep = si->ib;
if (objt_server(s->target))
health_adjust(objt_server(s->target), HANA_STATUS_L4_OK);
if (s->be->mode == PR_MODE_TCP) { /* let's allow immediate data connection in this case */
/* if the user wants to log as soon as possible, without counting
* bytes from the server, then this is the right moment. */
if (!LIST_ISEMPTY(&s->fe->logformat) && !(s->logs.logwait & LW_BYTES)) {
s->logs.t_close = s->logs.t_connect; /* to get a valid end date */
s->do_log(s);
}
}
else {
s->txn.rsp.msg_state = HTTP_MSG_RPBEFORE;
/* reset hdr_idx which was already initialized by the request.
* right now, the http parser does it.
* hdr_idx_init(&s->txn.hdr_idx);
*/
}
rep->analysers |= s->fe->fe_rsp_ana | s->be->be_rsp_ana;
rep->flags |= CF_READ_ATTACHED; /* producer is now attached */
if (si_ctrl(si)) {
/* real connections have timeouts */
req->wto = s->be->timeout.server;
rep->rto = s->be->timeout.server;
}
req->wex = TICK_ETERNITY;
}
/* Update stream interface status for input states SI_ST_ASS, SI_ST_QUE, SI_ST_TAR.
* Other input states are simply ignored.
* Possible output states are SI_ST_CLO, SI_ST_TAR, SI_ST_ASS, SI_ST_REQ, SI_ST_CON.
* Flags must have previously been updated for timeouts and other conditions.
*/
static void sess_update_stream_int(struct session *s, struct stream_interface *si)
{
struct server *srv = objt_server(s->target);
DPRINTF(stderr,"[%u] %s: sess=%p rq=%p, rp=%p, exp(r,w)=%u,%u rqf=%08x rpf=%08x rqh=%d rqt=%d rph=%d rpt=%d cs=%d ss=%d\n",
now_ms, __FUNCTION__,
s,
s->req, s->rep,
s->req->rex, s->rep->wex,
s->req->flags, s->rep->flags,
s->req->buf->i, s->req->buf->o, s->rep->buf->i, s->rep->buf->o, s->rep->cons->state, s->req->cons->state);
if (si->state == SI_ST_ASS) {
/* Server assigned to connection request, we have to try to connect now */
int conn_err;
conn_err = connect_server(s);
srv = objt_server(s->target);
if (conn_err == SN_ERR_NONE) {
/* state = SI_ST_CON now */
if (srv)
srv_inc_sess_ctr(srv);
return;
}
/* We have received a synchronous error. We might have to
* abort, retry immediately or redispatch.
*/
if (conn_err == SN_ERR_INTERNAL) {
if (!si->err_type) {
si->err_type = SI_ET_CONN_OTHER;
si->err_loc = srv;
}
if (srv)
srv_inc_sess_ctr(srv);
if (srv)
srv->counters.failed_conns++;
s->be->be_counters.failed_conns++;
/* release other sessions waiting for this server */
sess_change_server(s, NULL);
if (may_dequeue_tasks(srv, s->be))
process_srv_queue(srv);
/* Failed and not retryable. */
si_shutr(si);
si_shutw(si);
si->ob->flags |= CF_WRITE_ERROR;
s->logs.t_queue = tv_ms_elapsed(&s->logs.tv_accept, &now);
/* no session was ever accounted for this server */
si->state = SI_ST_CLO;
if (s->srv_error)
s->srv_error(s, si);
return;
}
/* We are facing a retryable error, but we don't want to run a
* turn-around now, as the problem is likely a source port
* allocation problem, so we want to retry now.
*/
si->state = SI_ST_CER;
si->flags &= ~SI_FL_ERR;
sess_update_st_cer(s, si);
/* now si->state is one of SI_ST_CLO, SI_ST_TAR, SI_ST_ASS, SI_ST_REQ */
return;
}
else if (si->state == SI_ST_QUE) {
/* connection request was queued, check for any update */
if (!s->pend_pos) {
/* The connection is not in the queue anymore. Either
* we have a server connection slot available and we
* go directly to the assigned state, or we need to
* load-balance first and go to the INI state.
*/
si->exp = TICK_ETERNITY;
if (unlikely(!(s->flags & SN_ASSIGNED)))
si->state = SI_ST_REQ;
else {
s->logs.t_queue = tv_ms_elapsed(&s->logs.tv_accept, &now);
si->state = SI_ST_ASS;
}
return;
}
/* Connection request still in queue... */
if (si->flags & SI_FL_EXP) {
/* ... and timeout expired */
si->exp = TICK_ETERNITY;
s->logs.t_queue = tv_ms_elapsed(&s->logs.tv_accept, &now);
if (srv)
srv->counters.failed_conns++;
s->be->be_counters.failed_conns++;
si_shutr(si);
si_shutw(si);
si->ob->flags |= CF_WRITE_TIMEOUT;
if (!si->err_type)
si->err_type = SI_ET_QUEUE_TO;
si->state = SI_ST_CLO;
if (s->srv_error)
s->srv_error(s, si);
return;
}
/* Connection remains in queue, check if we have to abort it */
if ((si->ob->flags & (CF_READ_ERROR)) ||
((si->ob->flags & CF_SHUTW_NOW) && /* empty and client aborted */
(channel_is_empty(si->ob) || s->be->options & PR_O_ABRT_CLOSE))) {
/* give up */
si->exp = TICK_ETERNITY;
s->logs.t_queue = tv_ms_elapsed(&s->logs.tv_accept, &now);
si_shutr(si);
si_shutw(si);
si->err_type |= SI_ET_QUEUE_ABRT;
si->state = SI_ST_CLO;
if (s->srv_error)
s->srv_error(s, si);
return;
}
/* Nothing changed */
return;
}
else if (si->state == SI_ST_TAR) {
/* Connection request might be aborted */
if ((si->ob->flags & (CF_READ_ERROR)) ||
((si->ob->flags & CF_SHUTW_NOW) && /* empty and client aborted */
(channel_is_empty(si->ob) || s->be->options & PR_O_ABRT_CLOSE))) {
/* give up */
si->exp = TICK_ETERNITY;
si_shutr(si);
si_shutw(si);
si->err_type |= SI_ET_CONN_ABRT;
si->state = SI_ST_CLO;
if (s->srv_error)
s->srv_error(s, si);
return;
}
if (!(si->flags & SI_FL_EXP))
return; /* still in turn-around */
si->exp = TICK_ETERNITY;
/* we keep trying on the same server as long as the session is
* marked "assigned".
* FIXME: Should we force a redispatch attempt when the server is down ?
*/
if (s->flags & SN_ASSIGNED)
si->state = SI_ST_ASS;
else
si->state = SI_ST_REQ;
return;
}
}
/* Set correct session termination flags in case no analyser has done it. It
* also counts a failed request if the server state has not reached the request
* stage.
*/
static void sess_set_term_flags(struct session *s)
{
if (!(s->flags & SN_FINST_MASK)) {
if (s->si[1].state < SI_ST_REQ) {
s->fe->fe_counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
s->flags |= SN_FINST_R;
}
else if (s->si[1].state == SI_ST_QUE)
s->flags |= SN_FINST_Q;
else if (s->si[1].state < SI_ST_EST)
s->flags |= SN_FINST_C;
else if (s->si[1].state == SI_ST_EST || s->si[1].prev_state == SI_ST_EST)
s->flags |= SN_FINST_D;
else
s->flags |= SN_FINST_L;
}
}
/* This function initiates a server connection request on a stream interface
* already in SI_ST_REQ state. Upon success, the state goes to SI_ST_ASS,
* indicating that a server has been assigned. It may also return SI_ST_QUE,
* or SI_ST_CLO upon error.
*/
static void sess_prepare_conn_req(struct session *s, struct stream_interface *si)
{
DPRINTF(stderr,"[%u] %s: sess=%p rq=%p, rp=%p, exp(r,w)=%u,%u rqf=%08x rpf=%08x rqh=%d rqt=%d rph=%d rpt=%d cs=%d ss=%d\n",
now_ms, __FUNCTION__,
s,
s->req, s->rep,
s->req->rex, s->rep->wex,
s->req->flags, s->rep->flags,
s->req->buf->i, s->req->buf->o, s->rep->buf->i, s->rep->buf->o, s->rep->cons->state, s->req->cons->state);
if (si->state != SI_ST_REQ)
return;
/* Try to assign a server */
if (srv_redispatch_connect(s) != 0) {
/* We did not get a server. Either we queued the
* connection request, or we encountered an error.
*/
if (si->state == SI_ST_QUE)
return;
/* we did not get any server, let's check the cause */
si_shutr(si);
si_shutw(si);
si->ob->flags |= CF_WRITE_ERROR;
if (!si->err_type)
si->err_type = SI_ET_CONN_OTHER;
si->state = SI_ST_CLO;
if (s->srv_error)
s->srv_error(s, si);
return;
}
/* The server is assigned */
s->logs.t_queue = tv_ms_elapsed(&s->logs.tv_accept, &now);
si->state = SI_ST_ASS;
}
/* This stream analyser checks the switching rules and changes the backend
* if appropriate. The default_backend rule is also considered, then the
* target backend's forced persistence rules are also evaluated last if any.
* It returns 1 if the processing can continue on next analysers, or zero if it
* either needs more data or wants to immediately abort the request.
*/
static int process_switching_rules(struct session *s, struct channel *req, int an_bit)
{
struct persist_rule *prst_rule;
req->analysers &= ~an_bit;
req->analyse_exp = TICK_ETERNITY;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bh=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
req,
req->rex, req->wex,
req->flags,
req->buf->i,
req->analysers);
/* now check whether we have some switching rules for this request */
if (!(s->flags & SN_BE_ASSIGNED)) {
struct switching_rule *rule;
list_for_each_entry(rule, &s->fe->switching_rules, list) {
int ret;
ret = acl_exec_cond(rule->cond, s->fe, s, &s->txn, SMP_OPT_DIR_REQ|SMP_OPT_FINAL);
ret = acl_pass(ret);
if (rule->cond->pol == ACL_COND_UNLESS)
ret = !ret;
if (ret) {
if (!session_set_backend(s, rule->be.backend))
goto sw_failed;
break;
}
}
/* To ensure correct connection accounting on the backend, we
* have to assign one if it was not set (eg: a listen). This
* measure also takes care of correctly setting the default
* backend if any.
*/
if (!(s->flags & SN_BE_ASSIGNED))
if (!session_set_backend(s, s->fe->defbe.be ? s->fe->defbe.be : s->be))
goto sw_failed;
}
/* we don't want to run the TCP or HTTP filters again if the backend has not changed */
if (s->fe == s->be) {
s->req->analysers &= ~AN_REQ_INSPECT_BE;
s->req->analysers &= ~AN_REQ_HTTP_PROCESS_BE;
}
/* as soon as we know the backend, we must check if we have a matching forced or ignored
* persistence rule, and report that in the session.
*/
list_for_each_entry(prst_rule, &s->be->persist_rules, list) {
int ret = 1;
if (prst_rule->cond) {
ret = acl_exec_cond(prst_rule->cond, s->be, s, &s->txn, SMP_OPT_DIR_REQ|SMP_OPT_FINAL);
ret = acl_pass(ret);
if (prst_rule->cond->pol == ACL_COND_UNLESS)
ret = !ret;
}
if (ret) {
/* no rule, or the rule matches */
if (prst_rule->type == PERSIST_TYPE_FORCE) {
s->flags |= SN_FORCE_PRST;
} else {
s->flags |= SN_IGNORE_PRST;
}
break;
}
}
return 1;
sw_failed:
/* immediately abort this request in case of allocation failure */
channel_abort(s->req);
channel_abort(s->rep);
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_RESOURCE;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
s->txn.status = 500;
s->req->analysers = 0;
s->req->analyse_exp = TICK_ETERNITY;
return 0;
}
/* This stream analyser works on a request. It applies all use-server rules on
* it then returns 1. The data must already be present in the buffer otherwise
* they won't match. It always returns 1.
*/
static int process_server_rules(struct session *s, struct channel *req, int an_bit)
{
struct proxy *px = s->be;
struct server_rule *rule;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bl=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
req,
req->rex, req->wex,
req->flags,
req->buf->i + req->buf->o,
req->analysers);
if (!(s->flags & SN_ASSIGNED)) {
list_for_each_entry(rule, &px->server_rules, list) {
int ret;
ret = acl_exec_cond(rule->cond, s->be, s, &s->txn, SMP_OPT_DIR_REQ|SMP_OPT_FINAL);
ret = acl_pass(ret);
if (rule->cond->pol == ACL_COND_UNLESS)
ret = !ret;
if (ret) {
struct server *srv = rule->srv.ptr;
if ((srv->state & SRV_RUNNING) ||
(px->options & PR_O_PERSIST) ||
(s->flags & SN_FORCE_PRST)) {
s->flags |= SN_DIRECT | SN_ASSIGNED;
s->target = &srv->obj_type;
break;
}
/* if the server is not UP, let's go on with next rules
* just in case another one is suited.
*/
}
}
}
req->analysers &= ~an_bit;
req->analyse_exp = TICK_ETERNITY;
return 1;
}
/* This stream analyser works on a request. It applies all sticking rules on
* it then returns 1. The data must already be present in the buffer otherwise
* they won't match. It always returns 1.
*/
static int process_sticking_rules(struct session *s, struct channel *req, int an_bit)
{
struct proxy *px = s->be;
struct sticking_rule *rule;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bh=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
req,
req->rex, req->wex,
req->flags,
req->buf->i,
req->analysers);
list_for_each_entry(rule, &px->sticking_rules, list) {
int ret = 1 ;
int i;
for (i = 0; i < s->store_count; i++) {
if (rule->table.t == s->store[i].table)
break;
}
if (i != s->store_count)
continue;
if (rule->cond) {
ret = acl_exec_cond(rule->cond, px, s, &s->txn, SMP_OPT_DIR_REQ|SMP_OPT_FINAL);
ret = acl_pass(ret);
if (rule->cond->pol == ACL_COND_UNLESS)
ret = !ret;
}
if (ret) {
struct stktable_key *key;
key = stktable_fetch_key(rule->table.t, px, s, &s->txn, SMP_OPT_DIR_REQ|SMP_OPT_FINAL, rule->expr);
if (!key)
continue;
if (rule->flags & STK_IS_MATCH) {
struct stksess *ts;
if ((ts = stktable_lookup_key(rule->table.t, key)) != NULL) {
if (!(s->flags & SN_ASSIGNED)) {
struct eb32_node *node;
void *ptr;
/* srv found in table */
ptr = stktable_data_ptr(rule->table.t, ts, STKTABLE_DT_SERVER_ID);
node = eb32_lookup(&px->conf.used_server_id, stktable_data_cast(ptr, server_id));
if (node) {
struct server *srv;
srv = container_of(node, struct server, conf.id);
if ((srv->state & SRV_RUNNING) ||
(px->options & PR_O_PERSIST) ||
(s->flags & SN_FORCE_PRST)) {
s->flags |= SN_DIRECT | SN_ASSIGNED;
s->target = &srv->obj_type;
}
}
}
stktable_touch(rule->table.t, ts, 1);
}
}
if (rule->flags & STK_IS_STORE) {
if (s->store_count < (sizeof(s->store) / sizeof(s->store[0]))) {
struct stksess *ts;
ts = stksess_new(rule->table.t, key);
if (ts) {
s->store[s->store_count].table = rule->table.t;
s->store[s->store_count++].ts = ts;
}
}
}
}
}
req->analysers &= ~an_bit;
req->analyse_exp = TICK_ETERNITY;
return 1;
}
/* This stream analyser works on a response. It applies all store rules on it
* then returns 1. The data must already be present in the buffer otherwise
* they won't match. It always returns 1.
*/
static int process_store_rules(struct session *s, struct channel *rep, int an_bit)
{
struct proxy *px = s->be;
struct sticking_rule *rule;
int i;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bh=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
rep,
rep->rex, rep->wex,
rep->flags,
rep->buf->i,
rep->analysers);
list_for_each_entry(rule, &px->storersp_rules, list) {
int ret = 1 ;
int storereqidx = -1;
for (i = 0; i < s->store_count; i++) {
if (rule->table.t == s->store[i].table) {
if (!(s->store[i].flags))
storereqidx = i;
break;
}
}
if ((i != s->store_count) && (storereqidx == -1))
continue;
if (rule->cond) {
ret = acl_exec_cond(rule->cond, px, s, &s->txn, SMP_OPT_DIR_RES|SMP_OPT_FINAL);
ret = acl_pass(ret);
if (rule->cond->pol == ACL_COND_UNLESS)
ret = !ret;
}
if (ret) {
struct stktable_key *key;
key = stktable_fetch_key(rule->table.t, px, s, &s->txn, SMP_OPT_DIR_RES|SMP_OPT_FINAL, rule->expr);
if (!key)
continue;
if (storereqidx != -1) {
stksess_setkey(s->store[storereqidx].table, s->store[storereqidx].ts, key);
s->store[storereqidx].flags = 1;
}
else if (s->store_count < (sizeof(s->store) / sizeof(s->store[0]))) {
struct stksess *ts;
ts = stksess_new(rule->table.t, key);
if (ts) {
s->store[s->store_count].table = rule->table.t;
s->store[s->store_count].flags = 1;
s->store[s->store_count++].ts = ts;
}
}
}
}
/* process store request and store response */
for (i = 0; i < s->store_count; i++) {
struct stksess *ts;
void *ptr;
if (objt_server(s->target) && objt_server(s->target)->state & SRV_NON_STICK) {
stksess_free(s->store[i].table, s->store[i].ts);
s->store[i].ts = NULL;
continue;
}
ts = stktable_lookup(s->store[i].table, s->store[i].ts);
if (ts) {
/* the entry already existed, we can free ours */
stktable_touch(s->store[i].table, ts, 1);
stksess_free(s->store[i].table, s->store[i].ts);
}
else
ts = stktable_store(s->store[i].table, s->store[i].ts, 1);
s->store[i].ts = NULL;
ptr = stktable_data_ptr(s->store[i].table, ts, STKTABLE_DT_SERVER_ID);
stktable_data_cast(ptr, server_id) = objt_server(s->target)->puid;
}
s->store_count = 0; /* everything is stored */
rep->analysers &= ~an_bit;
rep->analyse_exp = TICK_ETERNITY;
return 1;
}
/* This macro is very specific to the function below. See the comments in
* process_session() below to understand the logic and the tests.
*/
#define UPDATE_ANALYSERS(real, list, back, flag) { \
list = (((list) & ~(flag)) | ~(back)) & (real); \
back = real; \
if (!(list)) \
break; \
if (((list) ^ ((list) & ((list) - 1))) < (flag)) \
continue; \
}
/* Processes the client, server, request and response jobs of a session task,
* then puts it back to the wait queue in a clean state, or cleans up its
* resources if it must be deleted. Returns in <next> the date the task wants
* to be woken up, or TICK_ETERNITY. In order not to call all functions for
* nothing too many times, the request and response buffers flags are monitored
* and each function is called only if at least another function has changed at
* least one flag it is interested in.
*/
struct task *process_session(struct task *t)
{
struct server *srv;
struct session *s = t->context;
unsigned int rqf_last, rpf_last;
unsigned int rq_prod_last, rq_cons_last;
unsigned int rp_cons_last, rp_prod_last;
unsigned int req_ana_back;
//DPRINTF(stderr, "%s:%d: cs=%d ss=%d(%d) rqf=0x%08x rpf=0x%08x\n", __FUNCTION__, __LINE__,
// s->si[0].state, s->si[1].state, s->si[1].err_type, s->req->flags, s->rep->flags);
/* this data may be no longer valid, clear it */
memset(&s->txn.auth, 0, sizeof(s->txn.auth));
/* This flag must explicitly be set every time */
s->req->flags &= ~CF_READ_NOEXP;
/* Keep a copy of req/rep flags so that we can detect shutdowns */
rqf_last = s->req->flags & ~CF_MASK_ANALYSER;
rpf_last = s->rep->flags & ~CF_MASK_ANALYSER;
/* we don't want the stream interface functions to recursively wake us up */
if (s->req->prod->owner == t)
s->req->prod->flags |= SI_FL_DONT_WAKE;
if (s->req->cons->owner == t)
s->req->cons->flags |= SI_FL_DONT_WAKE;
/* 1a: Check for low level timeouts if needed. We just set a flag on
* stream interfaces when their timeouts have expired.
*/
if (unlikely(t->state & TASK_WOKEN_TIMER)) {
stream_int_check_timeouts(&s->si[0]);
stream_int_check_timeouts(&s->si[1]);
/* check channel timeouts, and close the corresponding stream interfaces
* for future reads or writes. Note: this will also concern upper layers
* but we do not touch any other flag. We must be careful and correctly
* detect state changes when calling them.
*/
channel_check_timeouts(s->req);
if (unlikely((s->req->flags & (CF_SHUTW|CF_WRITE_TIMEOUT)) == CF_WRITE_TIMEOUT)) {
s->req->cons->flags |= SI_FL_NOLINGER;
si_shutw(s->req->cons);
}
if (unlikely((s->req->flags & (CF_SHUTR|CF_READ_TIMEOUT)) == CF_READ_TIMEOUT)) {
if (s->req->prod->flags & SI_FL_NOHALF)
s->req->prod->flags |= SI_FL_NOLINGER;
si_shutr(s->req->prod);
}
channel_check_timeouts(s->rep);
if (unlikely((s->rep->flags & (CF_SHUTW|CF_WRITE_TIMEOUT)) == CF_WRITE_TIMEOUT)) {
s->rep->cons->flags |= SI_FL_NOLINGER;
si_shutw(s->rep->cons);
}
if (unlikely((s->rep->flags & (CF_SHUTR|CF_READ_TIMEOUT)) == CF_READ_TIMEOUT)) {
if (s->rep->prod->flags & SI_FL_NOHALF)
s->rep->prod->flags |= SI_FL_NOLINGER;
si_shutr(s->rep->prod);
}
/* Once in a while we're woken up because the task expires. But
* this does not necessarily mean that a timeout has been reached.
* So let's not run a whole session processing if only an expiration
* timeout needs to be refreshed.
*/
if (!((s->req->flags | s->rep->flags) &
(CF_SHUTR|CF_READ_ACTIVITY|CF_READ_TIMEOUT|CF_SHUTW|
CF_WRITE_ACTIVITY|CF_WRITE_TIMEOUT|CF_ANA_TIMEOUT)) &&
!((s->si[0].flags | s->si[1].flags) & (SI_FL_EXP|SI_FL_ERR)) &&
((t->state & TASK_WOKEN_ANY) == TASK_WOKEN_TIMER))
goto update_exp_and_leave;
}
/* 1b: check for low-level errors reported at the stream interface.
* First we check if it's a retryable error (in which case we don't
* want to tell the buffer). Otherwise we report the error one level
* upper by setting flags into the buffers. Note that the side towards
* the client cannot have connect (hence retryable) errors. Also, the
* connection setup code must be able to deal with any type of abort.
*/
srv = objt_server(s->target);
if (unlikely(s->si[0].flags & SI_FL_ERR)) {
if (s->si[0].state == SI_ST_EST || s->si[0].state == SI_ST_DIS) {
si_shutr(&s->si[0]);
si_shutw(&s->si[0]);
stream_int_report_error(&s->si[0]);
if (!(s->req->analysers) && !(s->rep->analysers)) {
s->be->be_counters.cli_aborts++;
s->fe->fe_counters.cli_aborts++;
if (srv)
srv->counters.cli_aborts++;
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLICL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_D;
}
}
}
if (unlikely(s->si[1].flags & SI_FL_ERR)) {
if (s->si[1].state == SI_ST_EST || s->si[1].state == SI_ST_DIS) {
si_shutr(&s->si[1]);
si_shutw(&s->si[1]);
stream_int_report_error(&s->si[1]);
s->be->be_counters.failed_resp++;
if (srv)
srv->counters.failed_resp++;
if (!(s->req->analysers) && !(s->rep->analysers)) {
s->be->be_counters.srv_aborts++;
s->fe->fe_counters.srv_aborts++;
if (srv)
srv->counters.srv_aborts++;
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_SRVCL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_D;
}
}
/* note: maybe we should process connection errors here ? */
}
if (s->si[1].state == SI_ST_CON) {
/* we were trying to establish a connection on the server side,
* maybe it succeeded, maybe it failed, maybe we timed out, ...
*/
if (unlikely(!sess_update_st_con_tcp(s, &s->si[1])))
sess_update_st_cer(s, &s->si[1]);
else if (s->si[1].state == SI_ST_EST)
sess_establish(s, &s->si[1]);
/* state is now one of SI_ST_CON (still in progress), SI_ST_EST
* (established), SI_ST_DIS (abort), SI_ST_CLO (last error),
* SI_ST_ASS/SI_ST_TAR/SI_ST_REQ for retryable errors.
*/
}
rq_prod_last = s->si[0].state;
rq_cons_last = s->si[1].state;
rp_cons_last = s->si[0].state;
rp_prod_last = s->si[1].state;
resync_stream_interface:
/* Check for connection closure */
DPRINTF(stderr,
"[%u] %s:%d: task=%p s=%p, sfl=0x%08x, rq=%p, rp=%p, exp(r,w)=%u,%u rqf=%08x rpf=%08x rqh=%d rqt=%d rph=%d rpt=%d cs=%d ss=%d, cet=0x%x set=0x%x retr=%d\n",
now_ms, __FUNCTION__, __LINE__,
t,
s, s->flags,
s->req, s->rep,
s->req->rex, s->rep->wex,
s->req->flags, s->rep->flags,
s->req->buf->i, s->req->buf->o, s->rep->buf->i, s->rep->buf->o, s->rep->cons->state, s->req->cons->state,
s->rep->cons->err_type, s->req->cons->err_type,
s->req->cons->conn_retries);
/* nothing special to be done on client side */
if (unlikely(s->req->prod->state == SI_ST_DIS))
s->req->prod->state = SI_ST_CLO;
/* When a server-side connection is released, we have to count it and
* check for pending connections on this server.
*/
if (unlikely(s->req->cons->state == SI_ST_DIS)) {
s->req->cons->state = SI_ST_CLO;
srv = objt_server(s->target);
if (srv) {
if (s->flags & SN_CURR_SESS) {
s->flags &= ~SN_CURR_SESS;
srv->cur_sess--;
}
sess_change_server(s, NULL);
if (may_dequeue_tasks(srv, s->be))
process_srv_queue(srv);
}
}
/*
* Note: of the transient states (REQ, CER, DIS), only REQ may remain
* at this point.
*/
resync_request:
/* Analyse request */
if (((s->req->flags & ~rqf_last) & CF_MASK_ANALYSER) ||
((s->req->flags ^ rqf_last) & CF_MASK_STATIC) ||
s->si[0].state != rq_prod_last ||
s->si[1].state != rq_cons_last) {
unsigned int flags = s->req->flags;
if (s->req->prod->state >= SI_ST_EST) {
int max_loops = global.tune.maxpollevents;
unsigned int ana_list;
unsigned int ana_back;
/* it's up to the analysers to stop new connections,
* disable reading or closing. Note: if an analyser
* disables any of these bits, it is responsible for
* enabling them again when it disables itself, so
* that other analysers are called in similar conditions.
*/
channel_auto_read(s->req);
channel_auto_connect(s->req);
channel_auto_close(s->req);
/* We will call all analysers for which a bit is set in
* s->req->analysers, following the bit order from LSB
* to MSB. The analysers must remove themselves from
* the list when not needed. Any analyser may return 0
* to break out of the loop, either because of missing
* data to take a decision, or because it decides to
* kill the session. We loop at least once through each
* analyser, and we may loop again if other analysers
* are added in the middle.
*
* We build a list of analysers to run. We evaluate all
* of these analysers in the order of the lower bit to
* the higher bit. This ordering is very important.
* An analyser will often add/remove other analysers,
* including itself. Any changes to itself have no effect
* on the loop. If it removes any other analysers, we
* want those analysers not to be called anymore during
* this loop. If it adds an analyser that is located
* after itself, we want it to be scheduled for being
* processed during the loop. If it adds an analyser
* which is located before it, we want it to switch to
* it immediately, even if it has already been called
* once but removed since.
*
* In order to achieve this, we compare the analyser
* list after the call with a copy of it before the
* call. The work list is fed with analyser bits that
* appeared during the call. Then we compare previous
* work list with the new one, and check the bits that
* appeared. If the lowest of these bits is lower than
* the current bit, it means we have enabled a previous
* analyser and must immediately loop again.
*/
ana_list = ana_back = s->req->analysers;
while (ana_list && max_loops--) {
/* Warning! ensure that analysers are always placed in ascending order! */
if (ana_list & AN_REQ_INSPECT_FE) {
if (!tcp_inspect_request(s, s->req, AN_REQ_INSPECT_FE))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_INSPECT_FE);
}
if (ana_list & AN_REQ_WAIT_HTTP) {
if (!http_wait_for_request(s, s->req, AN_REQ_WAIT_HTTP))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_WAIT_HTTP);
}
if (ana_list & AN_REQ_HTTP_PROCESS_FE) {
if (!http_process_req_common(s, s->req, AN_REQ_HTTP_PROCESS_FE, s->fe))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_HTTP_PROCESS_FE);
}
if (ana_list & AN_REQ_SWITCHING_RULES) {
if (!process_switching_rules(s, s->req, AN_REQ_SWITCHING_RULES))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_SWITCHING_RULES);
}
if (ana_list & AN_REQ_INSPECT_BE) {
if (!tcp_inspect_request(s, s->req, AN_REQ_INSPECT_BE))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_INSPECT_BE);
}
if (ana_list & AN_REQ_HTTP_PROCESS_BE) {
if (!http_process_req_common(s, s->req, AN_REQ_HTTP_PROCESS_BE, s->be))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_HTTP_PROCESS_BE);
}
if (ana_list & AN_REQ_HTTP_TARPIT) {
if (!http_process_tarpit(s, s->req, AN_REQ_HTTP_TARPIT))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_HTTP_TARPIT);
}
if (ana_list & AN_REQ_SRV_RULES) {
if (!process_server_rules(s, s->req, AN_REQ_SRV_RULES))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_SRV_RULES);
}
if (ana_list & AN_REQ_HTTP_INNER) {
if (!http_process_request(s, s->req, AN_REQ_HTTP_INNER))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_HTTP_INNER);
}
if (ana_list & AN_REQ_HTTP_BODY) {
if (!http_process_request_body(s, s->req, AN_REQ_HTTP_BODY))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_HTTP_BODY);
}
if (ana_list & AN_REQ_PRST_RDP_COOKIE) {
if (!tcp_persist_rdp_cookie(s, s->req, AN_REQ_PRST_RDP_COOKIE))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_PRST_RDP_COOKIE);
}
if (ana_list & AN_REQ_STICKING_RULES) {
if (!process_sticking_rules(s, s->req, AN_REQ_STICKING_RULES))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_STICKING_RULES);
}
if (ana_list & AN_REQ_HTTP_XFER_BODY) {
if (!http_request_forward_body(s, s->req, AN_REQ_HTTP_XFER_BODY))
break;
UPDATE_ANALYSERS(s->req->analysers, ana_list, ana_back, AN_REQ_HTTP_XFER_BODY);
}
break;
}
}
rq_prod_last = s->si[0].state;
rq_cons_last = s->si[1].state;
s->req->flags &= ~CF_WAKE_ONCE;
rqf_last = s->req->flags;
if ((s->req->flags ^ flags) & CF_MASK_STATIC)
goto resync_request;
}
/* we'll monitor the request analysers while parsing the response,
* because some response analysers may indirectly enable new request
* analysers (eg: HTTP keep-alive).
*/
req_ana_back = s->req->analysers;
resync_response:
/* Analyse response */
if (((s->rep->flags & ~rpf_last) & CF_MASK_ANALYSER) ||
(s->rep->flags ^ rpf_last) & CF_MASK_STATIC ||
s->si[0].state != rp_cons_last ||
s->si[1].state != rp_prod_last) {
unsigned int flags = s->rep->flags;
if ((s->rep->flags & CF_MASK_ANALYSER) &&
(s->rep->analysers & AN_REQ_WAIT_HTTP)) {
/* Due to HTTP pipelining, the HTTP request analyser might be waiting
* for some free space in the response buffer, so we might need to call
* it when something changes in the response buffer, but still we pass
* it the request buffer. Note that the SI state might very well still
* be zero due to us returning a flow of redirects!
*/
s->rep->analysers &= ~AN_REQ_WAIT_HTTP;
s->req->flags |= CF_WAKE_ONCE;
}
if (s->rep->prod->state >= SI_ST_EST) {
int max_loops = global.tune.maxpollevents;
unsigned int ana_list;
unsigned int ana_back;
/* it's up to the analysers to stop disable reading or
* closing. Note: if an analyser disables any of these
* bits, it is responsible for enabling them again when
* it disables itself, so that other analysers are called
* in similar conditions.
*/
channel_auto_read(s->rep);
channel_auto_close(s->rep);
/* We will call all analysers for which a bit is set in
* s->rep->analysers, following the bit order from LSB
* to MSB. The analysers must remove themselves from
* the list when not needed. Any analyser may return 0
* to break out of the loop, either because of missing
* data to take a decision, or because it decides to
* kill the session. We loop at least once through each
* analyser, and we may loop again if other analysers
* are added in the middle.
*/
ana_list = ana_back = s->rep->analysers;
while (ana_list && max_loops--) {
/* Warning! ensure that analysers are always placed in ascending order! */
if (ana_list & AN_RES_INSPECT) {
if (!tcp_inspect_response(s, s->rep, AN_RES_INSPECT))
break;
UPDATE_ANALYSERS(s->rep->analysers, ana_list, ana_back, AN_RES_INSPECT);
}
if (ana_list & AN_RES_WAIT_HTTP) {
if (!http_wait_for_response(s, s->rep, AN_RES_WAIT_HTTP))
break;
UPDATE_ANALYSERS(s->rep->analysers, ana_list, ana_back, AN_RES_WAIT_HTTP);
}
if (ana_list & AN_RES_STORE_RULES) {
if (!process_store_rules(s, s->rep, AN_RES_STORE_RULES))
break;
UPDATE_ANALYSERS(s->rep->analysers, ana_list, ana_back, AN_RES_STORE_RULES);
}
if (ana_list & AN_RES_HTTP_PROCESS_BE) {
if (!http_process_res_common(s, s->rep, AN_RES_HTTP_PROCESS_BE, s->be))
break;
UPDATE_ANALYSERS(s->rep->analysers, ana_list, ana_back, AN_RES_HTTP_PROCESS_BE);
}
if (ana_list & AN_RES_HTTP_XFER_BODY) {
if (!http_response_forward_body(s, s->rep, AN_RES_HTTP_XFER_BODY))
break;
UPDATE_ANALYSERS(s->rep->analysers, ana_list, ana_back, AN_RES_HTTP_XFER_BODY);
}
break;
}
}
rp_cons_last = s->si[0].state;
rp_prod_last = s->si[1].state;
rpf_last = s->rep->flags;
if ((s->rep->flags ^ flags) & CF_MASK_STATIC)
goto resync_response;
}
/* maybe someone has added some request analysers, so we must check and loop */
if (s->req->analysers & ~req_ana_back)
goto resync_request;
if ((s->req->flags & ~rqf_last) & CF_MASK_ANALYSER)
goto resync_request;
/* FIXME: here we should call protocol handlers which rely on
* both buffers.
*/
/*
* Now we propagate unhandled errors to the session. Normally
* we're just in a data phase here since it means we have not
* seen any analyser who could set an error status.
*/
srv = objt_server(s->target);
if (unlikely(!(s->flags & SN_ERR_MASK))) {
if (s->req->flags & (CF_READ_ERROR|CF_READ_TIMEOUT|CF_WRITE_ERROR|CF_WRITE_TIMEOUT)) {
/* Report it if the client got an error or a read timeout expired */
s->req->analysers = 0;
if (s->req->flags & CF_READ_ERROR) {
s->be->be_counters.cli_aborts++;
s->fe->fe_counters.cli_aborts++;
if (srv)
srv->counters.cli_aborts++;
s->flags |= SN_ERR_CLICL;
}
else if (s->req->flags & CF_READ_TIMEOUT) {
s->be->be_counters.cli_aborts++;
s->fe->fe_counters.cli_aborts++;
if (srv)
srv->counters.cli_aborts++;
s->flags |= SN_ERR_CLITO;
}
else if (s->req->flags & CF_WRITE_ERROR) {
s->be->be_counters.srv_aborts++;
s->fe->fe_counters.srv_aborts++;
if (srv)
srv->counters.srv_aborts++;
s->flags |= SN_ERR_SRVCL;
}
else {
s->be->be_counters.srv_aborts++;
s->fe->fe_counters.srv_aborts++;
if (srv)
srv->counters.srv_aborts++;
s->flags |= SN_ERR_SRVTO;
}
sess_set_term_flags(s);
}
else if (s->rep->flags & (CF_READ_ERROR|CF_READ_TIMEOUT|CF_WRITE_ERROR|CF_WRITE_TIMEOUT)) {
/* Report it if the server got an error or a read timeout expired */
s->rep->analysers = 0;
if (s->rep->flags & CF_READ_ERROR) {
s->be->be_counters.srv_aborts++;
s->fe->fe_counters.srv_aborts++;
if (srv)
srv->counters.srv_aborts++;
s->flags |= SN_ERR_SRVCL;
}
else if (s->rep->flags & CF_READ_TIMEOUT) {
s->be->be_counters.srv_aborts++;
s->fe->fe_counters.srv_aborts++;
if (srv)
srv->counters.srv_aborts++;
s->flags |= SN_ERR_SRVTO;
}
else if (s->rep->flags & CF_WRITE_ERROR) {
s->be->be_counters.cli_aborts++;
s->fe->fe_counters.cli_aborts++;
if (srv)
srv->counters.cli_aborts++;
s->flags |= SN_ERR_CLICL;
}
else {
s->be->be_counters.cli_aborts++;
s->fe->fe_counters.cli_aborts++;
if (srv)
srv->counters.cli_aborts++;
s->flags |= SN_ERR_CLITO;
}
sess_set_term_flags(s);
}
}
/*
* Here we take care of forwarding unhandled data. This also includes
* connection establishments and shutdown requests.
*/
/* If noone is interested in analysing data, it's time to forward
* everything. We configure the buffer to forward indefinitely.
* Note that we're checking CF_SHUTR_NOW as an indication of a possible
* recent call to channel_abort().
*/
if (!s->req->analysers &&
!(s->req->flags & (CF_SHUTW|CF_SHUTR_NOW)) &&
(s->req->prod->state >= SI_ST_EST) &&
(s->req->to_forward != CHN_INFINITE_FORWARD)) {
/* This buffer is freewheeling, there's no analyser
* attached to it. If any data are left in, we'll permit them to
* move.
*/
channel_auto_read(s->req);
channel_auto_connect(s->req);
channel_auto_close(s->req);
buffer_flush(s->req->buf);
/* We'll let data flow between the producer (if still connected)
* to the consumer (which might possibly not be connected yet).
*/
if (!(s->req->flags & (CF_SHUTR|CF_SHUTW_NOW)))
channel_forward(s->req, CHN_INFINITE_FORWARD);
}
/* check if it is wise to enable kernel splicing to forward request data */
if (!(s->req->flags & (CF_KERN_SPLICING|CF_SHUTR)) &&
s->req->to_forward &&
(global.tune.options & GTUNE_USE_SPLICE) &&
(s->si[0].conn->xprt && s->si[0].conn->xprt->rcv_pipe && s->si[0].conn->xprt->snd_pipe) &&
(s->si[1].conn->xprt && s->si[1].conn->xprt->rcv_pipe && s->si[1].conn->xprt->snd_pipe) &&
(pipes_used < global.maxpipes) &&
(((s->fe->options2|s->be->options2) & PR_O2_SPLIC_REQ) ||
(((s->fe->options2|s->be->options2) & PR_O2_SPLIC_AUT) &&
(s->req->flags & CF_STREAMER_FAST)))) {
s->req->flags |= CF_KERN_SPLICING;
}
/* reflect what the L7 analysers have seen last */
rqf_last = s->req->flags;
/*
* Now forward all shutdown requests between both sides of the buffer
*/
/* first, let's check if the request buffer needs to shutdown(write), which may
* happen either because the input is closed or because we want to force a close
* once the server has begun to respond.
*/
if (unlikely((s->req->flags & (CF_SHUTW|CF_SHUTW_NOW|CF_AUTO_CLOSE|CF_SHUTR)) ==
(CF_AUTO_CLOSE|CF_SHUTR)))
channel_shutw_now(s->req);
/* shutdown(write) pending */
if (unlikely((s->req->flags & (CF_SHUTW|CF_SHUTW_NOW)) == CF_SHUTW_NOW &&
channel_is_empty(s->req))) {
if (s->req->flags & CF_READ_ERROR)
s->req->cons->flags |= SI_FL_NOLINGER;
si_shutw(s->req->cons);
}
/* shutdown(write) done on server side, we must stop the client too */
if (unlikely((s->req->flags & (CF_SHUTW|CF_SHUTR|CF_SHUTR_NOW)) == CF_SHUTW &&
!s->req->analysers))
channel_shutr_now(s->req);
/* shutdown(read) pending */
if (unlikely((s->req->flags & (CF_SHUTR|CF_SHUTR_NOW)) == CF_SHUTR_NOW)) {
if (s->req->prod->flags & SI_FL_NOHALF)
s->req->prod->flags |= SI_FL_NOLINGER;
si_shutr(s->req->prod);
}
/* it's possible that an upper layer has requested a connection setup or abort.
* There are 2 situations where we decide to establish a new connection :
* - there are data scheduled for emission in the buffer
* - the CF_AUTO_CONNECT flag is set (active connection)
*/
if (s->req->cons->state == SI_ST_INI) {
if (!(s->req->flags & CF_SHUTW)) {
if ((s->req->flags & CF_AUTO_CONNECT) || !channel_is_empty(s->req)) {
/* If we have an applet without a connect method, we immediately
* switch to the connected state, otherwise we perform a connection
* request.
*/
s->req->cons->state = SI_ST_REQ; /* new connection requested */
s->req->cons->conn_retries = s->be->conn_retries;
if (unlikely(obj_type(s->req->cons->conn->target) == OBJ_TYPE_APPLET &&
!(si_ctrl(s->req->cons) && si_ctrl(s->req->cons)->connect))) {
s->req->cons->state = SI_ST_EST; /* connection established */
s->rep->flags |= CF_READ_ATTACHED; /* producer is now attached */
s->req->wex = TICK_ETERNITY;
}
}
}
else {
s->req->cons->state = SI_ST_CLO; /* shutw+ini = abort */
channel_shutw_now(s->req); /* fix buffer flags upon abort */
channel_shutr_now(s->rep);
}
}
/* we may have a pending connection request, or a connection waiting
* for completion.
*/
if (s->si[1].state >= SI_ST_REQ && s->si[1].state < SI_ST_CON) {
do {
/* nb: step 1 might switch from QUE to ASS, but we first want
* to give a chance to step 2 to perform a redirect if needed.
*/
if (s->si[1].state != SI_ST_REQ)
sess_update_stream_int(s, &s->si[1]);
if (s->si[1].state == SI_ST_REQ) {
sess_prepare_conn_req(s, &s->si[1]);
/* Now we can add the server name to a header (if requested) */
/* check for HTTP mode and proxy server_name_hdr_name != NULL */
if ((s->flags & SN_BE_ASSIGNED) &&
(s->be->mode == PR_MODE_HTTP) &&
(s->be->server_id_hdr_name != NULL && s->target)) {
http_send_name_header(&s->txn, s->be, objt_server(s->target)->id);
}
}
srv = objt_server(s->target);
if (s->si[1].state == SI_ST_ASS && srv && srv->rdr_len && (s->flags & SN_REDIRECTABLE))
http_perform_server_redirect(s, &s->si[1]);
} while (s->si[1].state == SI_ST_ASS);
}
/* Benchmarks have shown that it's optimal to do a full resync now */
if (s->req->prod->state == SI_ST_DIS || s->req->cons->state == SI_ST_DIS)
goto resync_stream_interface;
/* otherwise we want to check if we need to resync the req buffer or not */
if ((s->req->flags ^ rqf_last) & CF_MASK_STATIC)
goto resync_request;
/* perform output updates to the response buffer */
/* If noone is interested in analysing data, it's time to forward
* everything. We configure the buffer to forward indefinitely.
* Note that we're checking CF_SHUTR_NOW as an indication of a possible
* recent call to channel_abort().
*/
if (!s->rep->analysers &&
!(s->rep->flags & (CF_SHUTW|CF_SHUTR_NOW)) &&
(s->rep->prod->state >= SI_ST_EST) &&
(s->rep->to_forward != CHN_INFINITE_FORWARD)) {
/* This buffer is freewheeling, there's no analyser
* attached to it. If any data are left in, we'll permit them to
* move.
*/
channel_auto_read(s->rep);
channel_auto_close(s->rep);
buffer_flush(s->rep->buf);
/* We'll let data flow between the producer (if still connected)
* to the consumer.
*/
if (!(s->rep->flags & (CF_SHUTR|CF_SHUTW_NOW)))
channel_forward(s->rep, CHN_INFINITE_FORWARD);
/* if we have no analyser anymore in any direction and have a
* tunnel timeout set, use it now.
*/
if (!s->req->analysers && s->be->timeout.tunnel) {
s->req->rto = s->req->wto = s->rep->rto = s->rep->wto =
s->be->timeout.tunnel;
s->req->rex = s->req->wex = s->rep->rex = s->rep->wex =
tick_add(now_ms, s->be->timeout.tunnel);
}
}
/* check if it is wise to enable kernel splicing to forward response data */
if (!(s->rep->flags & (CF_KERN_SPLICING|CF_SHUTR)) &&
s->rep->to_forward &&
(global.tune.options & GTUNE_USE_SPLICE) &&
(s->si[0].conn->xprt && s->si[0].conn->xprt->rcv_pipe && s->si[0].conn->xprt->snd_pipe) &&
(s->si[1].conn->xprt && s->si[1].conn->xprt->rcv_pipe && s->si[1].conn->xprt->snd_pipe) &&
(pipes_used < global.maxpipes) &&
(((s->fe->options2|s->be->options2) & PR_O2_SPLIC_RTR) ||
(((s->fe->options2|s->be->options2) & PR_O2_SPLIC_AUT) &&
(s->rep->flags & CF_STREAMER_FAST)))) {
s->rep->flags |= CF_KERN_SPLICING;
}
/* reflect what the L7 analysers have seen last */
rpf_last = s->rep->flags;
/*
* Now forward all shutdown requests between both sides of the buffer
*/
/*
* FIXME: this is probably where we should produce error responses.
*/
/* first, let's check if the response buffer needs to shutdown(write) */
if (unlikely((s->rep->flags & (CF_SHUTW|CF_SHUTW_NOW|CF_AUTO_CLOSE|CF_SHUTR)) ==
(CF_AUTO_CLOSE|CF_SHUTR)))
channel_shutw_now(s->rep);
/* shutdown(write) pending */
if (unlikely((s->rep->flags & (CF_SHUTW|CF_SHUTW_NOW)) == CF_SHUTW_NOW &&
channel_is_empty(s->rep)))
si_shutw(s->rep->cons);
/* shutdown(write) done on the client side, we must stop the server too */
if (unlikely((s->rep->flags & (CF_SHUTW|CF_SHUTR|CF_SHUTR_NOW)) == CF_SHUTW) &&
!s->rep->analysers)
channel_shutr_now(s->rep);
/* shutdown(read) pending */
if (unlikely((s->rep->flags & (CF_SHUTR|CF_SHUTR_NOW)) == CF_SHUTR_NOW)) {
if (s->rep->prod->flags & SI_FL_NOHALF)
s->rep->prod->flags |= SI_FL_NOLINGER;
si_shutr(s->rep->prod);
}
if (s->req->prod->state == SI_ST_DIS || s->req->cons->state == SI_ST_DIS)
goto resync_stream_interface;
if (s->req->flags != rqf_last)
goto resync_request;
if ((s->rep->flags ^ rpf_last) & CF_MASK_STATIC)
goto resync_response;
/* we're interested in getting wakeups again */
s->req->prod->flags &= ~SI_FL_DONT_WAKE;
s->req->cons->flags &= ~SI_FL_DONT_WAKE;
/* This is needed only when debugging is enabled, to indicate
* client-side or server-side close. Please note that in the unlikely
* event where both sides would close at once, the sequence is reported
* on the server side first.
*/
if (unlikely((global.mode & MODE_DEBUG) &&
(!(global.mode & MODE_QUIET) ||
(global.mode & MODE_VERBOSE)))) {
if (s->si[1].state == SI_ST_CLO &&
s->si[1].prev_state == SI_ST_EST) {
chunk_printf(&trash, "%08x:%s.srvcls[%04x:%04x]\n",
s->uniq_id, s->be->id,
(unsigned short)s->si[0].conn->t.sock.fd,
(unsigned short)s->si[1].conn->t.sock.fd);
if (write(1, trash.str, trash.len) < 0) /* shut gcc warning */;
}
if (s->si[0].state == SI_ST_CLO &&
s->si[0].prev_state == SI_ST_EST) {
chunk_printf(&trash, "%08x:%s.clicls[%04x:%04x]\n",
s->uniq_id, s->be->id,
(unsigned short)s->si[0].conn->t.sock.fd,
(unsigned short)s->si[1].conn->t.sock.fd);
if (write(1, trash.str, trash.len) < 0) /* shut gcc warning */;
}
}
if (likely((s->rep->cons->state != SI_ST_CLO) ||
(s->req->cons->state > SI_ST_INI && s->req->cons->state < SI_ST_CLO))) {
if ((s->fe->options & PR_O_CONTSTATS) && (s->flags & SN_BE_ASSIGNED))
session_process_counters(s);
if (s->rep->cons->state == SI_ST_EST && obj_type(s->rep->cons->conn->target) != OBJ_TYPE_APPLET)
si_update(s->rep->cons);
if (s->req->cons->state == SI_ST_EST && obj_type(s->req->cons->conn->target) != OBJ_TYPE_APPLET)
si_update(s->req->cons);
s->req->flags &= ~(CF_READ_NULL|CF_READ_PARTIAL|CF_WRITE_NULL|CF_WRITE_PARTIAL|CF_READ_ATTACHED);
s->rep->flags &= ~(CF_READ_NULL|CF_READ_PARTIAL|CF_WRITE_NULL|CF_WRITE_PARTIAL|CF_READ_ATTACHED);
s->si[0].prev_state = s->si[0].state;
s->si[1].prev_state = s->si[1].state;
s->si[0].flags &= ~(SI_FL_ERR|SI_FL_EXP);
s->si[1].flags &= ~(SI_FL_ERR|SI_FL_EXP);
/* Trick: if a request is being waiting for the server to respond,
* and if we know the server can timeout, we don't want the timeout
* to expire on the client side first, but we're still interested
* in passing data from the client to the server (eg: POST). Thus,
* we can cancel the client's request timeout if the server's
* request timeout is set and the server has not yet sent a response.
*/
if ((s->rep->flags & (CF_AUTO_CLOSE|CF_SHUTR)) == 0 &&
(tick_isset(s->req->wex) || tick_isset(s->rep->rex))) {
s->req->flags |= CF_READ_NOEXP;
s->req->rex = TICK_ETERNITY;
}
/* Call the stream interfaces' I/O handlers when embedded.
* Note that this one may wake the task up again.
*/
if (obj_type(s->req->cons->conn->target) == OBJ_TYPE_APPLET ||
obj_type(s->rep->cons->conn->target) == OBJ_TYPE_APPLET) {
if (objt_applet(s->req->cons->conn->target))
objt_applet(s->req->cons->conn->target)->fct(s->req->cons);
if (objt_applet(s->rep->cons->conn->target))
objt_applet(s->rep->cons->conn->target)->fct(s->rep->cons);
if (task_in_rq(t)) {
/* If we woke up, we don't want to requeue the
* task to the wait queue, but rather requeue
* it into the runqueue ASAP.
*/
t->expire = TICK_ETERNITY;
return t;
}
}
update_exp_and_leave:
t->expire = tick_first(tick_first(s->req->rex, s->req->wex),
tick_first(s->rep->rex, s->rep->wex));
if (s->req->analysers)
t->expire = tick_first(t->expire, s->req->analyse_exp);
if (s->si[0].exp)
t->expire = tick_first(t->expire, s->si[0].exp);
if (s->si[1].exp)
t->expire = tick_first(t->expire, s->si[1].exp);
#ifdef DEBUG_FULL
fprintf(stderr,
"[%u] queuing with exp=%u req->rex=%u req->wex=%u req->ana_exp=%u"
" rep->rex=%u rep->wex=%u, si[0].exp=%u, si[1].exp=%u, cs=%d, ss=%d\n",
now_ms, t->expire, s->req->rex, s->req->wex, s->req->analyse_exp,
s->rep->rex, s->rep->wex, s->si[0].exp, s->si[1].exp, s->si[0].state, s->si[1].state);
#endif
#ifdef DEBUG_DEV
/* this may only happen when no timeout is set or in case of an FSM bug */
if (!tick_isset(t->expire))
ABORT_NOW();
#endif
return t; /* nothing more to do */
}
s->fe->feconn--;
if (s->flags & SN_BE_ASSIGNED)
s->be->beconn--;
if (!(s->listener->options & LI_O_UNLIMITED))
actconn--;
jobs--;
s->listener->nbconn--;
if (s->listener->state == LI_FULL)
resume_listener(s->listener);
/* Dequeues all of the listeners waiting for a resource */
if (!LIST_ISEMPTY(&global_listener_queue))
dequeue_all_listeners(&global_listener_queue);
if (!LIST_ISEMPTY(&s->fe->listener_queue) &&
(!s->fe->fe_sps_lim || freq_ctr_remain(&s->fe->fe_sess_per_sec, s->fe->fe_sps_lim, 0) > 0))
dequeue_all_listeners(&s->fe->listener_queue);
if (unlikely((global.mode & MODE_DEBUG) &&
(!(global.mode & MODE_QUIET) || (global.mode & MODE_VERBOSE)))) {
chunk_printf(&trash, "%08x:%s.closed[%04x:%04x]\n",
s->uniq_id, s->be->id,
(unsigned short)s->req->prod->conn->t.sock.fd,
(unsigned short)s->req->cons->conn->t.sock.fd);
if (write(1, trash.str, trash.len) < 0) /* shut gcc warning */;
}
s->logs.t_close = tv_ms_elapsed(&s->logs.tv_accept, &now);
session_process_counters(s);
if (s->txn.status) {
int n;
n = s->txn.status / 100;
if (n < 1 || n > 5)
n = 0;
if (s->fe->mode == PR_MODE_HTTP) {
s->fe->fe_counters.p.http.rsp[n]++;
if (s->comp_algo && (s->flags & SN_COMP_READY))
s->fe->fe_counters.p.http.comp_rsp++;
}
if ((s->flags & SN_BE_ASSIGNED) &&
(s->be->mode == PR_MODE_HTTP)) {
s->be->be_counters.p.http.rsp[n]++;
s->be->be_counters.p.http.cum_req++;
if (s->comp_algo && (s->flags & SN_COMP_READY))
s->be->be_counters.p.http.comp_rsp++;
}
}
/* let's do a final log if we need it */
if (!LIST_ISEMPTY(&s->fe->logformat) && s->logs.logwait &&
!(s->flags & SN_MONITOR) &&
(!(s->fe->options & PR_O_NULLNOLOG) || s->req->total)) {
s->do_log(s);
}
/* the task MUST not be in the run queue anymore */
session_free(s);
task_delete(t);
task_free(t);
return NULL;
}
/*
* This function adjusts sess->srv_conn and maintains the previous and new
* server's served session counts. Setting newsrv to NULL is enough to release
* current connection slot. This function also notifies any LB algo which might
* expect to be informed about any change in the number of active sessions on a
* server.
*/
void sess_change_server(struct session *sess, struct server *newsrv)
{
if (sess->srv_conn == newsrv)
return;
if (sess->srv_conn) {
sess->srv_conn->served--;
if (sess->srv_conn->proxy->lbprm.server_drop_conn)
sess->srv_conn->proxy->lbprm.server_drop_conn(sess->srv_conn);
session_del_srv_conn(sess);
}
if (newsrv) {
newsrv->served++;
if (newsrv->proxy->lbprm.server_take_conn)
newsrv->proxy->lbprm.server_take_conn(newsrv);
session_add_srv_conn(sess, newsrv);
}
}
/* Handle server-side errors for default protocols. It is called whenever a a
* connection setup is aborted or a request is aborted in queue. It sets the
* session termination flags so that the caller does not have to worry about
* them. It's installed as ->srv_error for the server-side stream_interface.
*/
void default_srv_error(struct session *s, struct stream_interface *si)
{
int err_type = si->err_type;
int err = 0, fin = 0;
if (err_type & SI_ET_QUEUE_ABRT) {
err = SN_ERR_CLICL;
fin = SN_FINST_Q;
}
else if (err_type & SI_ET_CONN_ABRT) {
err = SN_ERR_CLICL;
fin = SN_FINST_C;
}
else if (err_type & SI_ET_QUEUE_TO) {
err = SN_ERR_SRVTO;
fin = SN_FINST_Q;
}
else if (err_type & SI_ET_QUEUE_ERR) {
err = SN_ERR_SRVCL;
fin = SN_FINST_Q;
}
else if (err_type & SI_ET_CONN_TO) {
err = SN_ERR_SRVTO;
fin = SN_FINST_C;
}
else if (err_type & SI_ET_CONN_ERR) {
err = SN_ERR_SRVCL;
fin = SN_FINST_C;
}
else /* SI_ET_CONN_OTHER and others */ {
err = SN_ERR_INTERNAL;
fin = SN_FINST_C;
}
if (!(s->flags & SN_ERR_MASK))
s->flags |= err;
if (!(s->flags & SN_FINST_MASK))
s->flags |= fin;
}
/* kill a session and set the termination flags to <why> (one of SN_ERR_*) */
void session_shutdown(struct session *session, int why)
{
if (session->req->flags & (CF_SHUTW|CF_SHUTW_NOW))
return;
channel_shutw_now(session->req);
channel_shutr_now(session->rep);
session->task->nice = 1024;
if (!(session->flags & SN_ERR_MASK))
session->flags |= why;
task_wakeup(session->task, TASK_WOKEN_OTHER);
}
/************************************************************************/
/* All supported ACL keywords must be declared here. */
/************************************************************************/
/* Returns a pointer to a stkctr depending on the fetch keyword name.
* It is designed to be called as sc[0-9]_* sc_* or src_* exclusively.
* sc[0-9]_* will return a pointer to the respective field in the
* session <l4>. sc_* requires an UINT argument specifying the stick
* counter number. src_* will fill a locally allocated structure with
* the table and entry corresponding to what is specified with src_*.
* NULL may be returned if the designated stkctr is not tracked. For
* the sc_* and sc[0-9]_* forms, an optional table argument may be
* passed. When present, the currently tracked key is then looked up
* in the specified table instead of the current table. The purpose is
* to be able to convery multiple values per key (eg: have gpc0 from
* multiple tables).
*/
static struct stkctr *
smp_fetch_sc_stkctr(struct session *l4, const struct arg *args, const char *kw)
{
static struct stkctr stkctr;
unsigned int num = kw[2] - '0';
int arg = 0;
if (num == '_' - '0') {
/* sc_* variant, args[0] = ctr# (mandatory) */
num = args[arg++].data.uint;
if (num >= MAX_SESS_STKCTR)
return NULL;
}
else if (num > 9) { /* src_* variant, args[0] = table */
struct stktable_key *key = addr_to_stktable_key(&l4->si[0].conn->addr.from);
if (!key)
return NULL;
stkctr.table = &args->data.prx->table;
stkctr.entry = stktable_lookup_key(stkctr.table, key);
return &stkctr;
}
/* Here, <num> contains the counter number from 0 to 9 for
* the sc[0-9]_ form, or even higher using sc_(num) if needed.
* args[arg] is the first optional argument.
*/
if (unlikely(args[arg].type == ARGT_TAB)) {
/* an alternate table was specified, let's look up the same key there */
stkctr.table = &args[arg].data.prx->table;
stkctr.entry = stktable_lookup(stkctr.table, l4->stkctr[num].entry);
return &stkctr;
}
return l4->stkctr[num].entry ? &l4->stkctr[num] : NULL;
}
/* set return a boolean indicating if the requested session counter is
* currently being tracked or not.
* Supports being called as "sc[0-9]_tracked" only.
*/
static int
smp_fetch_sc_tracked(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_BOOL;
smp->data.uint = !!l4->stkctr[kw[2] - '0'].entry;
return 1;
}
/* set <smp> to the General Purpose Counter 0 value from the session's tracked
* frontend counters or from the src.
* Supports being called as "sc[0-9]_get_gpc0" or "src_get_gpc0" only. Value
* zero is returned if the key is new.
*/
static int
smp_fetch_sc_get_gpc0(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_GPC0);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, gpc0);
}
return 1;
}
/* set <smp> to the General Purpose Counter 0's event rate from the session's
* tracked frontend counters or from the src.
* Supports being called as "sc[0-9]_gpc0_rate" or "src_gpc0_rate" only.
* Value zero is returned if the key is new.
*/
static int
smp_fetch_sc_gpc0_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_GPC0_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, gpc0_rate),
stkctr->table->data_arg[STKTABLE_DT_GPC0_RATE].u);
}
return 1;
}
/* Increment the General Purpose Counter 0 value from the session's tracked
* frontend counters and return it into temp integer.
* Supports being called as "sc[0-9]_inc_gpc0" or "src_inc_gpc0" only.
*/
static int
smp_fetch_sc_inc_gpc0(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr;
/* First, update gpc0_rate if it's tracked. Second, update its
* gpc0 if tracked. Returns gpc0's value otherwise the curr_ctr.
*/
ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_GPC0_RATE);
if (ptr) {
update_freq_ctr_period(&stktable_data_cast(ptr, gpc0_rate),
stkctr->table->data_arg[STKTABLE_DT_GPC0_RATE].u, 1);
smp->data.uint = (&stktable_data_cast(ptr, gpc0_rate))->curr_ctr;
}
ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_GPC0);
if (ptr)
smp->data.uint = ++stktable_data_cast(ptr, gpc0);
}
return 1;
}
/* Clear the General Purpose Counter 0 value from the session's tracked
* frontend counters and return its previous value into temp integer.
* Supports being called as "sc[0-9]_clr_gpc0" or "src_clr_gpc0" only.
*/
static int
smp_fetch_sc_clr_gpc0(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_GPC0);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, gpc0);
stktable_data_cast(ptr, gpc0) = 0;
}
return 1;
}
/* set <smp> to the cumulated number of connections from the session's tracked
* frontend counters. Supports being called as "sc[0-9]_conn_cnt" or
* "src_conn_cnt" only.
*/
static int
smp_fetch_sc_conn_cnt(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_CONN_CNT);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, conn_cnt);
}
return 1;
}
/* set <smp> to the connection rate from the session's tracked frontend
* counters. Supports being called as "sc[0-9]_conn_rate" or "src_conn_rate"
* only.
*/
static int
smp_fetch_sc_conn_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_CONN_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, conn_rate),
stkctr->table->data_arg[STKTABLE_DT_CONN_RATE].u);
}
return 1;
}
/* set temp integer to the number of connections from the session's source address
* in the table pointed to by expr, after updating it.
* Accepts exactly 1 argument of type table.
*/
static int
smp_fetch_src_updt_conn_cnt(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stksess *ts;
struct stktable_key *key;
void *ptr;
key = addr_to_stktable_key(&l4->si[0].conn->addr.from);
if (!key)
return 0;
px = args->data.prx;
if ((ts = stktable_update_key(&px->table, key)) == NULL)
/* entry does not exist and could not be created */
return 0;
ptr = stktable_data_ptr(&px->table, ts, STKTABLE_DT_CONN_CNT);
if (!ptr)
return 0; /* parameter not stored in this table */
smp->type = SMP_T_UINT;
smp->data.uint = ++stktable_data_cast(ptr, conn_cnt);
smp->flags = SMP_F_VOL_TEST;
return 1;
}
/* set <smp> to the number of concurrent connections from the session's tracked
* frontend counters. Supports being called as "sc[0-9]_conn_cur" or
* "src_conn_cur" only.
*/
static int
smp_fetch_sc_conn_cur(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_CONN_CUR);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, conn_cur);
}
return 1;
}
/* set <smp> to the cumulated number of sessions from the session's tracked
* frontend counters. Supports being called as "sc[0-9]_sess_cnt" or
* "src_sess_cnt" only.
*/
static int
smp_fetch_sc_sess_cnt(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_SESS_CNT);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, sess_cnt);
}
return 1;
}
/* set <smp> to the session rate from the session's tracked frontend counters.
* Supports being called as "sc[0-9]_sess_rate" or "src_sess_rate" only.
*/
static int
smp_fetch_sc_sess_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_SESS_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, sess_rate),
stkctr->table->data_arg[STKTABLE_DT_SESS_RATE].u);
}
return 1;
}
/* set <smp> to the cumulated number of HTTP requests from the session's tracked
* frontend counters. Supports being called as "sc[0-9]_http_req_cnt" or
* "src_http_req_cnt" only.
*/
static int
smp_fetch_sc_http_req_cnt(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_HTTP_REQ_CNT);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, http_req_cnt);
}
return 1;
}
/* set <smp> to the HTTP request rate from the session's tracked frontend
* counters. Supports being called as "sc[0-9]_http_req_rate" or
* "src_http_req_rate" only.
*/
static int
smp_fetch_sc_http_req_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_HTTP_REQ_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, http_req_rate),
stkctr->table->data_arg[STKTABLE_DT_HTTP_REQ_RATE].u);
}
return 1;
}
/* set <smp> to the cumulated number of HTTP requests errors from the session's
* tracked frontend counters. Supports being called as "sc[0-9]_http_err_cnt" or
* "src_http_err_cnt" only.
*/
static int
smp_fetch_sc_http_err_cnt(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_HTTP_ERR_CNT);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, http_err_cnt);
}
return 1;
}
/* set <smp> to the HTTP request error rate from the session's tracked frontend
* counters. Supports being called as "sc[0-9]_http_err_rate" or
* "src_http_err_rate" only.
*/
static int
smp_fetch_sc_http_err_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_HTTP_ERR_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, http_err_rate),
stkctr->table->data_arg[STKTABLE_DT_HTTP_ERR_RATE].u);
}
return 1;
}
/* set <smp> to the number of kbytes received from clients, as found in the
* session's tracked frontend counters. Supports being called as
* "sc[0-9]_kbytes_in" or "src_kbytes_in" only.
*/
static int
smp_fetch_sc_kbytes_in(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_BYTES_IN_CNT);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, bytes_in_cnt) >> 10;
}
return 1;
}
/* set <smp> to the data rate received from clients in bytes/s, as found
* in the session's tracked frontend counters. Supports being called as
* "sc[0-9]_bytes_in_rate" or "src_bytes_in_rate" only.
*/
static int
smp_fetch_sc_bytes_in_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_BYTES_IN_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, bytes_in_rate),
stkctr->table->data_arg[STKTABLE_DT_BYTES_IN_RATE].u);
}
return 1;
}
/* set <smp> to the number of kbytes sent to clients, as found in the
* session's tracked frontend counters. Supports being called as
* "sc[0-9]_kbytes_out" or "src_kbytes_out" only.
*/
static int
smp_fetch_sc_kbytes_out(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_BYTES_OUT_CNT);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = stktable_data_cast(ptr, bytes_out_cnt) >> 10;
}
return 1;
}
/* set <smp> to the data rate sent to clients in bytes/s, as found in the
* session's tracked frontend counters. Supports being called as
* "sc[0-9]_bytes_out_rate" or "src_bytes_out_rate" only.
*/
static int
smp_fetch_sc_bytes_out_rate(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = 0;
if (stkctr->entry != NULL) {
void *ptr = stktable_data_ptr(stkctr->table, stkctr->entry, STKTABLE_DT_BYTES_OUT_RATE);
if (!ptr)
return 0; /* parameter not stored */
smp->data.uint = read_freq_ctr_period(&stktable_data_cast(ptr, bytes_out_rate),
stkctr->table->data_arg[STKTABLE_DT_BYTES_OUT_RATE].u);
}
return 1;
}
/* set <smp> to the number of active trackers on the SC entry in the session's
* tracked frontend counters. Supports being called as "sc[0-9]_trackers" only.
*/
static int
smp_fetch_sc_trackers(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
struct stkctr *stkctr = smp_fetch_sc_stkctr(l4, args, kw);
if (!stkctr)
return 0;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = stkctr->entry->ref_cnt;
return 1;
}
/* set temp integer to the number of used entries in the table pointed to by expr.
* Accepts exactly 1 argument of type table.
*/
static int
smp_fetch_table_cnt(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = args->data.prx->table.current;
return 1;
}
/* set temp integer to the number of free entries in the table pointed to by expr.
* Accepts exactly 1 argument of type table.
*/
static int
smp_fetch_table_avl(struct proxy *px, struct session *l4, void *l7, unsigned int opt,
const struct arg *args, struct sample *smp, const char *kw)
{
px = args->data.prx;
smp->flags = SMP_F_VOL_TEST;
smp->type = SMP_T_UINT;
smp->data.uint = px->table.size - px->table.current;
return 1;
}
/* Note: must not be declared <const> as its list will be overwritten.
* Please take care of keeping this list alphabetically sorted.
*/
static struct acl_kw_list acl_kws = {ILH, {
{ /* END */ },
}};
/* Note: must not be declared <const> as its list will be overwritten.
* Please take care of keeping this list alphabetically sorted.
*/
static struct sample_fetch_kw_list smp_fetch_keywords = {ILH, {
{ "sc_bytes_in_rate", smp_fetch_sc_bytes_in_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_bytes_out_rate", smp_fetch_sc_bytes_out_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_clr_gpc0", smp_fetch_sc_clr_gpc0, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_conn_cnt", smp_fetch_sc_conn_cnt, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_conn_cur", smp_fetch_sc_conn_cur, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_conn_rate", smp_fetch_sc_conn_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_get_gpc0", smp_fetch_sc_get_gpc0, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_gpc0_rate", smp_fetch_sc_gpc0_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_http_err_cnt", smp_fetch_sc_http_err_cnt, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_http_err_rate", smp_fetch_sc_http_err_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_http_req_cnt", smp_fetch_sc_http_req_cnt, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_http_req_rate", smp_fetch_sc_http_req_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_inc_gpc0", smp_fetch_sc_inc_gpc0, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_kbytes_in", smp_fetch_sc_kbytes_in, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc_kbytes_out", smp_fetch_sc_kbytes_out, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc_sess_cnt", smp_fetch_sc_sess_cnt, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_sess_rate", smp_fetch_sc_sess_rate, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc_tracked", smp_fetch_sc_tracked, ARG2(1,UINT,TAB), NULL, SMP_T_BOOL, SMP_USE_INTRN, },
{ "sc_trackers", smp_fetch_sc_trackers, ARG2(1,UINT,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_bytes_in_rate", smp_fetch_sc_bytes_in_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_bytes_out_rate", smp_fetch_sc_bytes_out_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_clr_gpc0", smp_fetch_sc_clr_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_conn_cnt", smp_fetch_sc_conn_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_conn_cur", smp_fetch_sc_conn_cur, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_conn_rate", smp_fetch_sc_conn_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_get_gpc0", smp_fetch_sc_get_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_gpc0_rate", smp_fetch_sc_gpc0_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_http_err_cnt", smp_fetch_sc_http_err_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_http_err_rate", smp_fetch_sc_http_err_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_http_req_cnt", smp_fetch_sc_http_req_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_http_req_rate", smp_fetch_sc_http_req_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_inc_gpc0", smp_fetch_sc_inc_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_kbytes_in", smp_fetch_sc_kbytes_in, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc0_kbytes_out", smp_fetch_sc_kbytes_out, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc0_sess_cnt", smp_fetch_sc_sess_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_sess_rate", smp_fetch_sc_sess_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc0_tracked", smp_fetch_sc_tracked, ARG1(0,TAB), NULL, SMP_T_BOOL, SMP_USE_INTRN, },
{ "sc0_trackers", smp_fetch_sc_trackers, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_bytes_in_rate", smp_fetch_sc_bytes_in_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_bytes_out_rate", smp_fetch_sc_bytes_out_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_clr_gpc0", smp_fetch_sc_clr_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_conn_cnt", smp_fetch_sc_conn_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_conn_cur", smp_fetch_sc_conn_cur, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_conn_rate", smp_fetch_sc_conn_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_get_gpc0", smp_fetch_sc_get_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_gpc0_rate", smp_fetch_sc_gpc0_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_http_err_cnt", smp_fetch_sc_http_err_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_http_err_rate", smp_fetch_sc_http_err_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_http_req_cnt", smp_fetch_sc_http_req_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_http_req_rate", smp_fetch_sc_http_req_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_inc_gpc0", smp_fetch_sc_inc_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_kbytes_in", smp_fetch_sc_kbytes_in, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc1_kbytes_out", smp_fetch_sc_kbytes_out, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc1_sess_cnt", smp_fetch_sc_sess_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_sess_rate", smp_fetch_sc_sess_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc1_tracked", smp_fetch_sc_tracked, ARG1(0,TAB), NULL, SMP_T_BOOL, SMP_USE_INTRN, },
{ "sc1_trackers", smp_fetch_sc_trackers, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_bytes_in_rate", smp_fetch_sc_bytes_in_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_bytes_out_rate", smp_fetch_sc_bytes_out_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_clr_gpc0", smp_fetch_sc_clr_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_conn_cnt", smp_fetch_sc_conn_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_conn_cur", smp_fetch_sc_conn_cur, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_conn_rate", smp_fetch_sc_conn_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_get_gpc0", smp_fetch_sc_get_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_gpc0_rate", smp_fetch_sc_gpc0_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_http_err_cnt", smp_fetch_sc_http_err_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_http_err_rate", smp_fetch_sc_http_err_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_http_req_cnt", smp_fetch_sc_http_req_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_http_req_rate", smp_fetch_sc_http_req_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_inc_gpc0", smp_fetch_sc_inc_gpc0, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_kbytes_in", smp_fetch_sc_kbytes_in, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc2_kbytes_out", smp_fetch_sc_kbytes_out, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "sc2_sess_cnt", smp_fetch_sc_sess_cnt, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_sess_rate", smp_fetch_sc_sess_rate, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "sc2_tracked", smp_fetch_sc_tracked, ARG1(0,TAB), NULL, SMP_T_BOOL, SMP_USE_INTRN, },
{ "sc2_trackers", smp_fetch_sc_trackers, ARG1(0,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "src_bytes_in_rate", smp_fetch_sc_bytes_in_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_bytes_out_rate", smp_fetch_sc_bytes_out_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_clr_gpc0", smp_fetch_sc_clr_gpc0, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_conn_cnt", smp_fetch_sc_conn_cnt, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_conn_cur", smp_fetch_sc_conn_cur, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_conn_rate", smp_fetch_sc_conn_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_get_gpc0", smp_fetch_sc_get_gpc0, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_gpc0_rate", smp_fetch_sc_gpc0_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_http_err_cnt", smp_fetch_sc_http_err_cnt, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_http_err_rate", smp_fetch_sc_http_err_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_http_req_cnt", smp_fetch_sc_http_req_cnt, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_http_req_rate", smp_fetch_sc_http_req_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_inc_gpc0", smp_fetch_sc_inc_gpc0, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_kbytes_in", smp_fetch_sc_kbytes_in, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_kbytes_out", smp_fetch_sc_kbytes_out, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_sess_cnt", smp_fetch_sc_sess_cnt, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_sess_rate", smp_fetch_sc_sess_rate, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "src_updt_conn_cnt", smp_fetch_src_updt_conn_cnt, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_L4CLI, },
{ "table_avl", smp_fetch_table_avl, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ "table_cnt", smp_fetch_table_cnt, ARG1(1,TAB), NULL, SMP_T_UINT, SMP_USE_INTRN, },
{ /* END */ },
}};
__attribute__((constructor))
static void __session_init(void)
{
sample_register_fetches(&smp_fetch_keywords);
acl_register_keywords(&acl_kws);
}
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/
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