blob: 1af862e9b7d9ad35b794af48c2c729819295c424 [file] [log] [blame]
/*
* Health-checks functions.
*
* Copyright 2000-2009 Willy Tarreau <w@1wt.eu>
* Copyright 2007-2009 Krzysztof Piotr Oledzki <ole@ans.pl>
*
* 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 <assert.h>
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <signal.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <sys/socket.h>
#include <sys/types.h>
#include <sys/wait.h>
#include <netinet/in.h>
#include <netinet/tcp.h>
#include <arpa/inet.h>
#include <common/chunk.h>
#include <common/compat.h>
#include <common/config.h>
#include <common/mini-clist.h>
#include <common/standard.h>
#include <common/time.h>
#include <types/global.h>
#include <types/mailers.h>
#include <types/dns.h>
#include <types/stats.h>
#include <proto/backend.h>
#include <proto/checks.h>
#include <proto/stats.h>
#include <proto/fd.h>
#include <proto/log.h>
#include <proto/queue.h>
#include <proto/port_range.h>
#include <proto/proto_http.h>
#include <proto/proto_tcp.h>
#include <proto/protocol.h>
#include <proto/proxy.h>
#include <proto/server.h>
#include <proto/signal.h>
#include <proto/stream_interface.h>
#include <proto/task.h>
#include <proto/log.h>
#include <proto/dns.h>
#include <proto/proto_udp.h>
static int httpchk_expect(struct server *s, int done);
static int tcpcheck_get_step_id(struct check *);
static char * tcpcheck_get_step_comment(struct check *, int);
static void tcpcheck_main(struct connection *);
static const struct check_status check_statuses[HCHK_STATUS_SIZE] = {
[HCHK_STATUS_UNKNOWN] = { CHK_RES_UNKNOWN, "UNK", "Unknown" },
[HCHK_STATUS_INI] = { CHK_RES_UNKNOWN, "INI", "Initializing" },
[HCHK_STATUS_START] = { /* SPECIAL STATUS*/ },
/* Below we have finished checks */
[HCHK_STATUS_CHECKED] = { CHK_RES_NEUTRAL, "CHECKED", "No status change" },
[HCHK_STATUS_HANA] = { CHK_RES_FAILED, "HANA", "Health analyze" },
[HCHK_STATUS_SOCKERR] = { CHK_RES_FAILED, "SOCKERR", "Socket error" },
[HCHK_STATUS_L4OK] = { CHK_RES_PASSED, "L4OK", "Layer4 check passed" },
[HCHK_STATUS_L4TOUT] = { CHK_RES_FAILED, "L4TOUT", "Layer4 timeout" },
[HCHK_STATUS_L4CON] = { CHK_RES_FAILED, "L4CON", "Layer4 connection problem" },
[HCHK_STATUS_L6OK] = { CHK_RES_PASSED, "L6OK", "Layer6 check passed" },
[HCHK_STATUS_L6TOUT] = { CHK_RES_FAILED, "L6TOUT", "Layer6 timeout" },
[HCHK_STATUS_L6RSP] = { CHK_RES_FAILED, "L6RSP", "Layer6 invalid response" },
[HCHK_STATUS_L7TOUT] = { CHK_RES_FAILED, "L7TOUT", "Layer7 timeout" },
[HCHK_STATUS_L7RSP] = { CHK_RES_FAILED, "L7RSP", "Layer7 invalid response" },
[HCHK_STATUS_L57DATA] = { /* DUMMY STATUS */ },
[HCHK_STATUS_L7OKD] = { CHK_RES_PASSED, "L7OK", "Layer7 check passed" },
[HCHK_STATUS_L7OKCD] = { CHK_RES_CONDPASS, "L7OKC", "Layer7 check conditionally passed" },
[HCHK_STATUS_L7STS] = { CHK_RES_FAILED, "L7STS", "Layer7 wrong status" },
[HCHK_STATUS_PROCERR] = { CHK_RES_FAILED, "PROCERR", "External check error" },
[HCHK_STATUS_PROCTOUT] = { CHK_RES_FAILED, "PROCTOUT", "External check timeout" },
[HCHK_STATUS_PROCOK] = { CHK_RES_PASSED, "PROCOK", "External check passed" },
};
const struct extcheck_env extcheck_envs[EXTCHK_SIZE] = {
[EXTCHK_PATH] = { "PATH", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_PROXY_NAME] = { "HAPROXY_PROXY_NAME", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_PROXY_ID] = { "HAPROXY_PROXY_ID", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_PROXY_ADDR] = { "HAPROXY_PROXY_ADDR", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_PROXY_PORT] = { "HAPROXY_PROXY_PORT", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_SERVER_NAME] = { "HAPROXY_SERVER_NAME", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_SERVER_ID] = { "HAPROXY_SERVER_ID", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_SERVER_ADDR] = { "HAPROXY_SERVER_ADDR", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_SERVER_PORT] = { "HAPROXY_SERVER_PORT", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_SERVER_MAXCONN] = { "HAPROXY_SERVER_MAXCONN", EXTCHK_SIZE_EVAL_INIT },
[EXTCHK_HAPROXY_SERVER_CURCONN] = { "HAPROXY_SERVER_CURCONN", EXTCHK_SIZE_ULONG },
};
static const struct analyze_status analyze_statuses[HANA_STATUS_SIZE] = { /* 0: ignore, 1: error, 2: OK */
[HANA_STATUS_UNKNOWN] = { "Unknown", { 0, 0 }},
[HANA_STATUS_L4_OK] = { "L4 successful connection", { 2, 0 }},
[HANA_STATUS_L4_ERR] = { "L4 unsuccessful connection", { 1, 1 }},
[HANA_STATUS_HTTP_OK] = { "Correct http response", { 0, 2 }},
[HANA_STATUS_HTTP_STS] = { "Wrong http response", { 0, 1 }},
[HANA_STATUS_HTTP_HDRRSP] = { "Invalid http response (headers)", { 0, 1 }},
[HANA_STATUS_HTTP_RSP] = { "Invalid http response", { 0, 1 }},
[HANA_STATUS_HTTP_READ_ERROR] = { "Read error (http)", { 0, 1 }},
[HANA_STATUS_HTTP_READ_TIMEOUT] = { "Read timeout (http)", { 0, 1 }},
[HANA_STATUS_HTTP_BROKEN_PIPE] = { "Close from server (http)", { 0, 1 }},
};
/*
* Convert check_status code to description
*/
const char *get_check_status_description(short check_status) {
const char *desc;
if (check_status < HCHK_STATUS_SIZE)
desc = check_statuses[check_status].desc;
else
desc = NULL;
if (desc && *desc)
return desc;
else
return check_statuses[HCHK_STATUS_UNKNOWN].desc;
}
/*
* Convert check_status code to short info
*/
const char *get_check_status_info(short check_status) {
const char *info;
if (check_status < HCHK_STATUS_SIZE)
info = check_statuses[check_status].info;
else
info = NULL;
if (info && *info)
return info;
else
return check_statuses[HCHK_STATUS_UNKNOWN].info;
}
const char *get_analyze_status(short analyze_status) {
const char *desc;
if (analyze_status < HANA_STATUS_SIZE)
desc = analyze_statuses[analyze_status].desc;
else
desc = NULL;
if (desc && *desc)
return desc;
else
return analyze_statuses[HANA_STATUS_UNKNOWN].desc;
}
/* Builds a string containing some information about the health check's result.
* The output string is allocated from the trash chunks. If the check is NULL,
* NULL is returned. This is designed to be used when emitting logs about health
* checks.
*/
static const char *check_reason_string(struct check *check)
{
struct chunk *msg;
if (!check)
return NULL;
msg = get_trash_chunk();
chunk_printf(msg, "reason: %s", get_check_status_description(check->status));
if (check->status >= HCHK_STATUS_L57DATA)
chunk_appendf(msg, ", code: %d", check->code);
if (*check->desc) {
struct chunk src;
chunk_appendf(msg, ", info: \"");
chunk_initlen(&src, check->desc, 0, strlen(check->desc));
chunk_asciiencode(msg, &src, '"');
chunk_appendf(msg, "\"");
}
if (check->duration >= 0)
chunk_appendf(msg, ", check duration: %ldms", check->duration);
return msg->str;
}
/*
* Set check->status, update check->duration and fill check->result with
* an adequate CHK_RES_* value. The new check->health is computed based
* on the result.
*
* Show information in logs about failed health check if server is UP
* or succeeded health checks if server is DOWN.
*/
static void set_server_check_status(struct check *check, short status, const char *desc)
{
struct server *s = check->server;
short prev_status = check->status;
int report = 0;
if (status == HCHK_STATUS_START) {
check->result = CHK_RES_UNKNOWN; /* no result yet */
check->desc[0] = '\0';
check->start = now;
return;
}
if (!check->status)
return;
if (desc && *desc) {
strncpy(check->desc, desc, HCHK_DESC_LEN-1);
check->desc[HCHK_DESC_LEN-1] = '\0';
} else
check->desc[0] = '\0';
check->status = status;
if (check_statuses[status].result)
check->result = check_statuses[status].result;
if (status == HCHK_STATUS_HANA)
check->duration = -1;
else if (!tv_iszero(&check->start)) {
/* set_server_check_status() may be called more than once */
check->duration = tv_ms_elapsed(&check->start, &now);
tv_zero(&check->start);
}
/* no change is expected if no state change occurred */
if (check->result == CHK_RES_NEUTRAL)
return;
report = 0;
switch (check->result) {
case CHK_RES_FAILED:
/* Failure to connect to the agent as a secondary check should not
* cause the server to be marked down.
*/
if ((!(check->state & CHK_ST_AGENT) ||
(check->status >= HCHK_STATUS_L57DATA)) &&
(check->health >= check->rise)) {
s->counters.failed_checks++;
report = 1;
check->health--;
if (check->health < check->rise)
check->health = 0;
}
break;
case CHK_RES_PASSED:
case CHK_RES_CONDPASS: /* "condpass" cannot make the first step but it OK after a "passed" */
if ((check->health < check->rise + check->fall - 1) &&
(check->result == CHK_RES_PASSED || check->health > 0)) {
report = 1;
check->health++;
if (check->health >= check->rise)
check->health = check->rise + check->fall - 1; /* OK now */
}
/* clear consecutive_errors if observing is enabled */
if (s->onerror)
s->consecutive_errors = 0;
break;
default:
break;
}
if (s->proxy->options2 & PR_O2_LOGHCHKS &&
(status != prev_status || report)) {
chunk_printf(&trash,
"%s check for %sserver %s/%s %s%s",
(check->state & CHK_ST_AGENT) ? "Agent" : "Health",
s->flags & SRV_F_BACKUP ? "backup " : "",
s->proxy->id, s->id,
(check->result == CHK_RES_CONDPASS) ? "conditionally ":"",
(check->result >= CHK_RES_PASSED) ? "succeeded" : "failed");
srv_append_status(&trash, s, check_reason_string(check), -1, 0);
chunk_appendf(&trash, ", status: %d/%d %s",
(check->health >= check->rise) ? check->health - check->rise + 1 : check->health,
(check->health >= check->rise) ? check->fall : check->rise,
(check->health >= check->rise) ? (s->uweight ? "UP" : "DRAIN") : "DOWN");
Warning("%s.\n", trash.str);
send_log(s->proxy, LOG_NOTICE, "%s.\n", trash.str);
send_email_alert(s, LOG_INFO, "%s", trash.str);
}
}
/* Marks the check <check>'s server down if the current check is already failed
* and the server is not down yet nor in maintenance.
*/
static void check_notify_failure(struct check *check)
{
struct server *s = check->server;
/* The agent secondary check should only cause a server to be marked
* as down if check->status is HCHK_STATUS_L7STS, which indicates
* that the agent returned "fail", "stopped" or "down".
* The implication here is that failure to connect to the agent
* as a secondary check should not cause the server to be marked
* down. */
if ((check->state & CHK_ST_AGENT) && check->status != HCHK_STATUS_L7STS)
return;
if (check->health > 0)
return;
/* We only report a reason for the check if we did not do so previously */
srv_set_stopped(s, (!s->track && !(s->proxy->options2 & PR_O2_LOGHCHKS)) ? check_reason_string(check) : NULL);
}
/* Marks the check <check> as valid and tries to set its server up, provided
* it isn't in maintenance, it is not tracking a down server and other checks
* comply. The rule is simple : by default, a server is up, unless any of the
* following conditions is true :
* - health check failed (check->health < rise)
* - agent check failed (agent->health < rise)
* - the server tracks a down server (track && track->state == STOPPED)
* Note that if the server has a slowstart, it will switch to STARTING instead
* of RUNNING. Also, only the health checks support the nolb mode, so the
* agent's success may not take the server out of this mode.
*/
static void check_notify_success(struct check *check)
{
struct server *s = check->server;
if (s->admin & SRV_ADMF_MAINT)
return;
if (s->track && s->track->state == SRV_ST_STOPPED)
return;
if ((s->check.state & CHK_ST_ENABLED) && (s->check.health < s->check.rise))
return;
if ((s->agent.state & CHK_ST_ENABLED) && (s->agent.health < s->agent.rise))
return;
if ((check->state & CHK_ST_AGENT) && s->state == SRV_ST_STOPPING)
return;
srv_set_running(s, (!s->track && !(s->proxy->options2 & PR_O2_LOGHCHKS)) ? check_reason_string(check) : NULL);
}
/* Marks the check <check> as valid and tries to set its server into stopping mode
* if it was running or starting, and provided it isn't in maintenance and other
* checks comply. The conditions for the server to be marked in stopping mode are
* the same as for it to be turned up. Also, only the health checks support the
* nolb mode.
*/
static void check_notify_stopping(struct check *check)
{
struct server *s = check->server;
if (s->admin & SRV_ADMF_MAINT)
return;
if (check->state & CHK_ST_AGENT)
return;
if (s->track && s->track->state == SRV_ST_STOPPED)
return;
if ((s->check.state & CHK_ST_ENABLED) && (s->check.health < s->check.rise))
return;
if ((s->agent.state & CHK_ST_ENABLED) && (s->agent.health < s->agent.rise))
return;
srv_set_stopping(s, (!s->track && !(s->proxy->options2 & PR_O2_LOGHCHKS)) ? check_reason_string(check) : NULL);
}
/* note: use health_adjust() only, which first checks that the observe mode is
* enabled.
*/
void __health_adjust(struct server *s, short status)
{
int failed;
int expire;
if (s->observe >= HANA_OBS_SIZE)
return;
if (status >= HANA_STATUS_SIZE || !analyze_statuses[status].desc)
return;
switch (analyze_statuses[status].lr[s->observe - 1]) {
case 1:
failed = 1;
break;
case 2:
failed = 0;
break;
default:
return;
}
if (!failed) {
/* good: clear consecutive_errors */
s->consecutive_errors = 0;
return;
}
s->consecutive_errors++;
if (s->consecutive_errors < s->consecutive_errors_limit)
return;
chunk_printf(&trash, "Detected %d consecutive errors, last one was: %s",
s->consecutive_errors, get_analyze_status(status));
switch (s->onerror) {
case HANA_ONERR_FASTINTER:
/* force fastinter - nothing to do here as all modes force it */
break;
case HANA_ONERR_SUDDTH:
/* simulate a pre-fatal failed health check */
if (s->check.health > s->check.rise)
s->check.health = s->check.rise + 1;
/* no break - fall through */
case HANA_ONERR_FAILCHK:
/* simulate a failed health check */
set_server_check_status(&s->check, HCHK_STATUS_HANA, trash.str);
check_notify_failure(&s->check);
break;
case HANA_ONERR_MARKDWN:
/* mark server down */
s->check.health = s->check.rise;
set_server_check_status(&s->check, HCHK_STATUS_HANA, trash.str);
check_notify_failure(&s->check);
break;
default:
/* write a warning? */
break;
}
s->consecutive_errors = 0;
s->counters.failed_hana++;
if (s->check.fastinter) {
expire = tick_add(now_ms, MS_TO_TICKS(s->check.fastinter));
if (s->check.task->expire > expire) {
s->check.task->expire = expire;
/* requeue check task with new expire */
task_queue(s->check.task);
}
}
}
static int httpchk_build_status_header(struct server *s, char *buffer, int size)
{
int sv_state;
int ratio;
int hlen = 0;
char addr[46];
char port[6];
const char *srv_hlt_st[7] = { "DOWN", "DOWN %d/%d",
"UP %d/%d", "UP",
"NOLB %d/%d", "NOLB",
"no check" };
memcpy(buffer + hlen, "X-Haproxy-Server-State: ", 24);
hlen += 24;
if (!(s->check.state & CHK_ST_ENABLED))
sv_state = 6;
else if (s->state != SRV_ST_STOPPED) {
if (s->check.health == s->check.rise + s->check.fall - 1)
sv_state = 3; /* UP */
else
sv_state = 2; /* going down */
if (s->state == SRV_ST_STOPPING)
sv_state += 2;
} else {
if (s->check.health)
sv_state = 1; /* going up */
else
sv_state = 0; /* DOWN */
}
hlen += snprintf(buffer + hlen, size - hlen,
srv_hlt_st[sv_state],
(s->state != SRV_ST_STOPPED) ? (s->check.health - s->check.rise + 1) : (s->check.health),
(s->state != SRV_ST_STOPPED) ? (s->check.fall) : (s->check.rise));
addr_to_str(&s->addr, addr, sizeof(addr));
if (s->addr.ss_family == AF_INET || s->addr.ss_family == AF_INET6)
snprintf(port, sizeof(port), "%u", s->svc_port);
else
*port = 0;
hlen += snprintf(buffer + hlen, size - hlen, "; address=%s; port=%s; name=%s/%s; node=%s; weight=%d/%d; scur=%d/%d; qcur=%d",
addr, port, s->proxy->id, s->id,
global.node,
(s->eweight * s->proxy->lbprm.wmult + s->proxy->lbprm.wdiv - 1) / s->proxy->lbprm.wdiv,
(s->proxy->lbprm.tot_weight * s->proxy->lbprm.wmult + s->proxy->lbprm.wdiv - 1) / s->proxy->lbprm.wdiv,
s->cur_sess, s->proxy->beconn - s->proxy->nbpend,
s->nbpend);
if ((s->state == SRV_ST_STARTING) &&
now.tv_sec < s->last_change + s->slowstart &&
now.tv_sec >= s->last_change) {
ratio = MAX(1, 100 * (now.tv_sec - s->last_change) / s->slowstart);
hlen += snprintf(buffer + hlen, size - hlen, "; throttle=%d%%", ratio);
}
buffer[hlen++] = '\r';
buffer[hlen++] = '\n';
return hlen;
}
/* Check the connection. If an error has already been reported or the socket is
* closed, keep errno intact as it is supposed to contain the valid error code.
* If no error is reported, check the socket's error queue using getsockopt().
* Warning, this must be done only once when returning from poll, and never
* after an I/O error was attempted, otherwise the error queue might contain
* inconsistent errors. If an error is detected, the CO_FL_ERROR is set on the
* socket. Returns non-zero if an error was reported, zero if everything is
* clean (including a properly closed socket).
*/
static int retrieve_errno_from_socket(struct connection *conn)
{
int skerr;
socklen_t lskerr = sizeof(skerr);
if (conn->flags & CO_FL_ERROR && ((errno && errno != EAGAIN) || !conn->ctrl))
return 1;
if (!conn_ctrl_ready(conn))
return 0;
if (getsockopt(conn->t.sock.fd, SOL_SOCKET, SO_ERROR, &skerr, &lskerr) == 0)
errno = skerr;
if (errno == EAGAIN)
errno = 0;
if (!errno) {
/* we could not retrieve an error, that does not mean there is
* none. Just don't change anything and only report the prior
* error if any.
*/
if (conn->flags & CO_FL_ERROR)
return 1;
else
return 0;
}
conn->flags |= CO_FL_ERROR | CO_FL_SOCK_WR_SH | CO_FL_SOCK_RD_SH;
return 1;
}
/* Try to collect as much information as possible on the connection status,
* and adjust the server status accordingly. It may make use of <errno_bck>
* if non-null when the caller is absolutely certain of its validity (eg:
* checked just after a syscall). If the caller doesn't have a valid errno,
* it can pass zero, and retrieve_errno_from_socket() will be called to try
* to extract errno from the socket. If no error is reported, it will consider
* the <expired> flag. This is intended to be used when a connection error was
* reported in conn->flags or when a timeout was reported in <expired>. The
* function takes care of not updating a server status which was already set.
* All situations where at least one of <expired> or CO_FL_ERROR are set
* produce a status.
*/
static void chk_report_conn_err(struct connection *conn, int errno_bck, int expired)
{
struct check *check = conn->owner;
const char *err_msg;
struct chunk *chk;
int step;
char *comment;
if (check->result != CHK_RES_UNKNOWN)
return;
errno = errno_bck;
if (!errno || errno == EAGAIN)
retrieve_errno_from_socket(conn);
if (!(conn->flags & CO_FL_ERROR) && !expired)
return;
/* we'll try to build a meaningful error message depending on the
* context of the error possibly present in conn->err_code, and the
* socket error possibly collected above. This is useful to know the
* exact step of the L6 layer (eg: SSL handshake).
*/
chk = get_trash_chunk();
if (check->type == PR_O2_TCPCHK_CHK) {
step = tcpcheck_get_step_id(check);
if (!step)
chunk_printf(chk, " at initial connection step of tcp-check");
else {
chunk_printf(chk, " at step %d of tcp-check", step);
/* we were looking for a string */
if (check->last_started_step && check->last_started_step->action == TCPCHK_ACT_CONNECT) {
if (check->last_started_step->port)
chunk_appendf(chk, " (connect port %d)" ,check->last_started_step->port);
else
chunk_appendf(chk, " (connect)");
}
else if (check->last_started_step && check->last_started_step->action == TCPCHK_ACT_EXPECT) {
if (check->last_started_step->string)
chunk_appendf(chk, " (expect string '%s')", check->last_started_step->string);
else if (check->last_started_step->expect_regex)
chunk_appendf(chk, " (expect regex)");
}
else if (check->last_started_step && check->last_started_step->action == TCPCHK_ACT_SEND) {
chunk_appendf(chk, " (send)");
}
comment = tcpcheck_get_step_comment(check, step);
if (comment)
chunk_appendf(chk, " comment: '%s'", comment);
}
}
if (conn->err_code) {
if (errno && errno != EAGAIN)
chunk_printf(&trash, "%s (%s)%s", conn_err_code_str(conn), strerror(errno), chk->str);
else
chunk_printf(&trash, "%s%s", conn_err_code_str(conn), chk->str);
err_msg = trash.str;
}
else {
if (errno && errno != EAGAIN) {
chunk_printf(&trash, "%s%s", strerror(errno), chk->str);
err_msg = trash.str;
}
else {
err_msg = chk->str;
}
}
if (check->state & CHK_ST_PORT_MISS) {
/* NOTE: this is reported after <fall> tries */
chunk_printf(chk, "No port available for the TCP connection");
set_server_check_status(check, HCHK_STATUS_SOCKERR, err_msg);
}
if ((conn->flags & (CO_FL_CONNECTED|CO_FL_WAIT_L4_CONN)) == CO_FL_WAIT_L4_CONN) {
/* L4 not established (yet) */
if (conn->flags & CO_FL_ERROR)
set_server_check_status(check, HCHK_STATUS_L4CON, err_msg);
else if (expired)
set_server_check_status(check, HCHK_STATUS_L4TOUT, err_msg);
/*
* might be due to a server IP change.
* Let's trigger a DNS resolution if none are currently running.
*/
if ((check->server->resolution) && (check->server->resolution->step == RSLV_STEP_NONE))
dns_trigger_resolution(check->server->resolution);
}
else if ((conn->flags & (CO_FL_CONNECTED|CO_FL_WAIT_L6_CONN)) == CO_FL_WAIT_L6_CONN) {
/* L6 not established (yet) */
if (conn->flags & CO_FL_ERROR)
set_server_check_status(check, HCHK_STATUS_L6RSP, err_msg);
else if (expired)
set_server_check_status(check, HCHK_STATUS_L6TOUT, err_msg);
}
else if (conn->flags & CO_FL_ERROR) {
/* I/O error after connection was established and before we could diagnose */
set_server_check_status(check, HCHK_STATUS_SOCKERR, err_msg);
}
else if (expired) {
/* connection established but expired check */
if (check->type == PR_O2_SSL3_CHK)
set_server_check_status(check, HCHK_STATUS_L6TOUT, err_msg);
else /* HTTP, SMTP, ... */
set_server_check_status(check, HCHK_STATUS_L7TOUT, err_msg);
}
return;
}
/*
* This function is used only for server health-checks. It handles
* the connection acknowledgement. If the proxy requires L7 health-checks,
* it sends the request. In other cases, it calls set_server_check_status()
* to set check->status, check->duration and check->result.
*/
static void event_srv_chk_w(struct connection *conn)
{
struct check *check = conn->owner;
struct server *s = check->server;
struct task *t = check->task;
if (unlikely(check->result == CHK_RES_FAILED))
goto out_wakeup;
if (conn->flags & CO_FL_HANDSHAKE)
return;
if (retrieve_errno_from_socket(conn)) {
chk_report_conn_err(conn, errno, 0);
__conn_data_stop_both(conn);
goto out_wakeup;
}
if (conn->flags & (CO_FL_SOCK_WR_SH | CO_FL_DATA_WR_SH)) {
/* if the output is closed, we can't do anything */
conn->flags |= CO_FL_ERROR;
chk_report_conn_err(conn, 0, 0);
goto out_wakeup;
}
/* here, we know that the connection is established. That's enough for
* a pure TCP check.
*/
if (!check->type)
goto out_wakeup;
if (check->type == PR_O2_TCPCHK_CHK) {
tcpcheck_main(conn);
return;
}
if (check->bo->o) {
conn->xprt->snd_buf(conn, check->bo, 0);
if (conn->flags & CO_FL_ERROR) {
chk_report_conn_err(conn, errno, 0);
__conn_data_stop_both(conn);
goto out_wakeup;
}
if (check->bo->o)
return;
}
/* full request sent, we allow up to <timeout.check> if nonzero for a response */
if (s->proxy->timeout.check) {
t->expire = tick_add_ifset(now_ms, s->proxy->timeout.check);
task_queue(t);
}
goto out_nowake;
out_wakeup:
task_wakeup(t, TASK_WOKEN_IO);
out_nowake:
__conn_data_stop_send(conn); /* nothing more to write */
}
/*
* This function is used only for server health-checks. It handles the server's
* reply to an HTTP request, SSL HELLO or MySQL client Auth. It calls
* set_server_check_status() to update check->status, check->duration
* and check->result.
* The set_server_check_status function is called with HCHK_STATUS_L7OKD if
* an HTTP server replies HTTP 2xx or 3xx (valid responses), if an SMTP server
* returns 2xx, HCHK_STATUS_L6OK if an SSL server returns at least 5 bytes in
* response to an SSL HELLO (the principle is that this is enough to
* distinguish between an SSL server and a pure TCP relay). All other cases will
* call it with a proper error status like HCHK_STATUS_L7STS, HCHK_STATUS_L6RSP,
* etc.
*/
static void event_srv_chk_r(struct connection *conn)
{
struct check *check = conn->owner;
struct server *s = check->server;
struct task *t = check->task;
char *desc;
int done;
unsigned short msglen;
if (unlikely(check->result == CHK_RES_FAILED))
goto out_wakeup;
if (conn->flags & CO_FL_HANDSHAKE)
return;
if (check->type == PR_O2_TCPCHK_CHK) {
tcpcheck_main(conn);
return;
}
/* Warning! Linux returns EAGAIN on SO_ERROR if data are still available
* but the connection was closed on the remote end. Fortunately, recv still
* works correctly and we don't need to do the getsockopt() on linux.
*/
/* Set buffer to point to the end of the data already read, and check
* that there is free space remaining. If the buffer is full, proceed
* with running the checks without attempting another socket read.
*/
done = 0;
conn->xprt->rcv_buf(conn, check->bi, check->bi->size);
if (conn->flags & (CO_FL_ERROR | CO_FL_SOCK_RD_SH | CO_FL_DATA_RD_SH)) {
done = 1;
if ((conn->flags & CO_FL_ERROR) && !check->bi->i) {
/* Report network errors only if we got no other data. Otherwise
* we'll let the upper layers decide whether the response is OK
* or not. It is very common that an RST sent by the server is
* reported as an error just after the last data chunk.
*/
chk_report_conn_err(conn, errno, 0);
goto out_wakeup;
}
}
/* Intermediate or complete response received.
* Terminate string in check->bi->data buffer.
*/
if (check->bi->i < check->bi->size)
check->bi->data[check->bi->i] = '\0';
else {
check->bi->data[check->bi->i - 1] = '\0';
done = 1; /* buffer full, don't wait for more data */
}
/* Run the checks... */
switch (check->type) {
case PR_O2_HTTP_CHK:
if (!done && check->bi->i < strlen("HTTP/1.0 000\r"))
goto wait_more_data;
/* Check if the server speaks HTTP 1.X */
if ((check->bi->i < strlen("HTTP/1.0 000\r")) ||
(memcmp(check->bi->data, "HTTP/1.", 7) != 0 ||
(*(check->bi->data + 12) != ' ' && *(check->bi->data + 12) != '\r')) ||
!isdigit((unsigned char) *(check->bi->data + 9)) || !isdigit((unsigned char) *(check->bi->data + 10)) ||
!isdigit((unsigned char) *(check->bi->data + 11))) {
cut_crlf(check->bi->data);
set_server_check_status(check, HCHK_STATUS_L7RSP, check->bi->data);
goto out_wakeup;
}
check->code = str2uic(check->bi->data + 9);
desc = ltrim(check->bi->data + 12, ' ');
if ((s->proxy->options & PR_O_DISABLE404) &&
(s->state != SRV_ST_STOPPED) && (check->code == 404)) {
/* 404 may be accepted as "stopping" only if the server was up */
cut_crlf(desc);
set_server_check_status(check, HCHK_STATUS_L7OKCD, desc);
}
else if (s->proxy->options2 & PR_O2_EXP_TYPE) {
/* Run content verification check... We know we have at least 13 chars */
if (!httpchk_expect(s, done))
goto wait_more_data;
}
/* check the reply : HTTP/1.X 2xx and 3xx are OK */
else if (*(check->bi->data + 9) == '2' || *(check->bi->data + 9) == '3') {
cut_crlf(desc);
set_server_check_status(check, HCHK_STATUS_L7OKD, desc);
}
else {
cut_crlf(desc);
set_server_check_status(check, HCHK_STATUS_L7STS, desc);
}
break;
case PR_O2_SSL3_CHK:
if (!done && check->bi->i < 5)
goto wait_more_data;
/* Check for SSLv3 alert or handshake */
if ((check->bi->i >= 5) && (*check->bi->data == 0x15 || *check->bi->data == 0x16))
set_server_check_status(check, HCHK_STATUS_L6OK, NULL);
else
set_server_check_status(check, HCHK_STATUS_L6RSP, NULL);
break;
case PR_O2_SMTP_CHK:
if (!done && check->bi->i < strlen("000\r"))
goto wait_more_data;
/* Check if the server speaks SMTP */
if ((check->bi->i < strlen("000\r")) ||
(*(check->bi->data + 3) != ' ' && *(check->bi->data + 3) != '\r') ||
!isdigit((unsigned char) *check->bi->data) || !isdigit((unsigned char) *(check->bi->data + 1)) ||
!isdigit((unsigned char) *(check->bi->data + 2))) {
cut_crlf(check->bi->data);
set_server_check_status(check, HCHK_STATUS_L7RSP, check->bi->data);
goto out_wakeup;
}
check->code = str2uic(check->bi->data);
desc = ltrim(check->bi->data + 3, ' ');
cut_crlf(desc);
/* Check for SMTP code 2xx (should be 250) */
if (*check->bi->data == '2')
set_server_check_status(check, HCHK_STATUS_L7OKD, desc);
else
set_server_check_status(check, HCHK_STATUS_L7STS, desc);
break;
case PR_O2_LB_AGENT_CHK: {
int status = HCHK_STATUS_CHECKED;
const char *hs = NULL; /* health status */
const char *as = NULL; /* admin status */
const char *ps = NULL; /* performance status */
const char *cs = NULL; /* maxconn */
const char *err = NULL; /* first error to report */
const char *wrn = NULL; /* first warning to report */
char *cmd, *p;
/* We're getting an agent check response. The agent could
* have been disabled in the mean time with a long check
* still pending. It is important that we ignore the whole
* response.
*/
if (!(check->server->agent.state & CHK_ST_ENABLED))
break;
/* The agent supports strings made of a single line ended by the
* first CR ('\r') or LF ('\n'). This line is composed of words
* delimited by spaces (' '), tabs ('\t'), or commas (','). The
* line may optionally contained a description of a state change
* after a sharp ('#'), which is only considered if a health state
* is announced.
*
* Words may be composed of :
* - a numeric weight suffixed by the percent character ('%').
* - a health status among "up", "down", "stopped", and "fail".
* - an admin status among "ready", "drain", "maint".
*
* These words may appear in any order. If multiple words of the
* same category appear, the last one wins.
*/
p = check->bi->data;
while (*p && *p != '\n' && *p != '\r')
p++;
if (!*p) {
if (!done)
goto wait_more_data;
/* at least inform the admin that the agent is mis-behaving */
set_server_check_status(check, check->status, "Ignoring incomplete line from agent");
break;
}
*p = 0;
cmd = check->bi->data;
while (*cmd) {
/* look for next word */
if (*cmd == ' ' || *cmd == '\t' || *cmd == ',') {
cmd++;
continue;
}
if (*cmd == '#') {
/* this is the beginning of a health status description,
* skip the sharp and blanks.
*/
cmd++;
while (*cmd == '\t' || *cmd == ' ')
cmd++;
break;
}
/* find the end of the word so that we have a null-terminated
* word between <cmd> and <p>.
*/
p = cmd + 1;
while (*p && *p != '\t' && *p != ' ' && *p != '\n' && *p != ',')
p++;
if (*p)
*p++ = 0;
/* first, health statuses */
if (strcasecmp(cmd, "up") == 0) {
check->health = check->rise + check->fall - 1;
status = HCHK_STATUS_L7OKD;
hs = cmd;
}
else if (strcasecmp(cmd, "down") == 0) {
check->health = 0;
status = HCHK_STATUS_L7STS;
hs = cmd;
}
else if (strcasecmp(cmd, "stopped") == 0) {
check->health = 0;
status = HCHK_STATUS_L7STS;
hs = cmd;
}
else if (strcasecmp(cmd, "fail") == 0) {
check->health = 0;
status = HCHK_STATUS_L7STS;
hs = cmd;
}
/* admin statuses */
else if (strcasecmp(cmd, "ready") == 0) {
as = cmd;
}
else if (strcasecmp(cmd, "drain") == 0) {
as = cmd;
}
else if (strcasecmp(cmd, "maint") == 0) {
as = cmd;
}
/* try to parse a weight here and keep the last one */
else if (isdigit((unsigned char)*cmd) && strchr(cmd, '%') != NULL) {
ps = cmd;
}
/* try to parse a maxconn here */
else if (strncasecmp(cmd, "maxconn:", strlen("maxconn:")) == 0) {
cs = cmd;
}
else {
/* keep a copy of the first error */
if (!err)
err = cmd;
}
/* skip to next word */
cmd = p;
}
/* here, cmd points either to \0 or to the beginning of a
* description. Skip possible leading spaces.
*/
while (*cmd == ' ' || *cmd == '\n')
cmd++;
/* First, update the admin status so that we avoid sending other
* possibly useless warnings and can also update the health if
* present after going back up.
*/
if (as) {
if (strcasecmp(as, "drain") == 0)
srv_adm_set_drain(check->server);
else if (strcasecmp(as, "maint") == 0)
srv_adm_set_maint(check->server);
else
srv_adm_set_ready(check->server);
}
/* now change weights */
if (ps) {
const char *msg;
msg = server_parse_weight_change_request(s, ps);
if (!wrn || !*wrn)
wrn = msg;
}
if (cs) {
const char *msg;
cs += strlen("maxconn:");
msg = server_parse_maxconn_change_request(s, cs);
if (!wrn || !*wrn)
wrn = msg;
}
/* and finally health status */
if (hs) {
/* We'll report some of the warnings and errors we have
* here. Down reports are critical, we leave them untouched.
* Lack of report, or report of 'UP' leaves the room for
* ERR first, then WARN.
*/
const char *msg = cmd;
struct chunk *t;
if (!*msg || status == HCHK_STATUS_L7OKD) {
if (err && *err)
msg = err;
else if (wrn && *wrn)
msg = wrn;
}
t = get_trash_chunk();
chunk_printf(t, "via agent : %s%s%s%s",
hs, *msg ? " (" : "",
msg, *msg ? ")" : "");
set_server_check_status(check, status, t->str);
}
else if (err && *err) {
/* No status change but we'd like to report something odd.
* Just report the current state and copy the message.
*/
chunk_printf(&trash, "agent reports an error : %s", err);
set_server_check_status(check, status/*check->status*/, trash.str);
}
else if (wrn && *wrn) {
/* No status change but we'd like to report something odd.
* Just report the current state and copy the message.
*/
chunk_printf(&trash, "agent warns : %s", wrn);
set_server_check_status(check, status/*check->status*/, trash.str);
}
else
set_server_check_status(check, status, NULL);
break;
}
case PR_O2_PGSQL_CHK:
if (!done && check->bi->i < 9)
goto wait_more_data;
if (check->bi->data[0] == 'R') {
set_server_check_status(check, HCHK_STATUS_L7OKD, "PostgreSQL server is ok");
}
else {
if ((check->bi->data[0] == 'E') && (check->bi->data[5]!=0) && (check->bi->data[6]!=0))
desc = &check->bi->data[6];
else
desc = "PostgreSQL unknown error";
set_server_check_status(check, HCHK_STATUS_L7STS, desc);
}
break;
case PR_O2_REDIS_CHK:
if (!done && check->bi->i < 7)
goto wait_more_data;
if (strcmp(check->bi->data, "+PONG\r\n") == 0) {
set_server_check_status(check, HCHK_STATUS_L7OKD, "Redis server is ok");
}
else {
set_server_check_status(check, HCHK_STATUS_L7STS, check->bi->data);
}
break;
case PR_O2_MYSQL_CHK:
if (!done && check->bi->i < 5)
goto wait_more_data;
if (s->proxy->check_len == 0) { // old mode
if (*(check->bi->data + 4) != '\xff') {
/* We set the MySQL Version in description for information purpose
* FIXME : it can be cool to use MySQL Version for other purpose,
* like mark as down old MySQL server.
*/
if (check->bi->i > 51) {
desc = ltrim(check->bi->data + 5, ' ');
set_server_check_status(check, HCHK_STATUS_L7OKD, desc);
}
else {
if (!done)
goto wait_more_data;
/* it seems we have a OK packet but without a valid length,
* it must be a protocol error
*/
set_server_check_status(check, HCHK_STATUS_L7RSP, check->bi->data);
}
}
else {
/* An error message is attached in the Error packet */
desc = ltrim(check->bi->data + 7, ' ');
set_server_check_status(check, HCHK_STATUS_L7STS, desc);
}
} else {
unsigned int first_packet_len = ((unsigned int) *check->bi->data) +
(((unsigned int) *(check->bi->data + 1)) << 8) +
(((unsigned int) *(check->bi->data + 2)) << 16);
if (check->bi->i == first_packet_len + 4) {
/* MySQL Error packet always begin with field_count = 0xff */
if (*(check->bi->data + 4) != '\xff') {
/* We have only one MySQL packet and it is a Handshake Initialization packet
* but we need to have a second packet to know if it is alright
*/
if (!done && check->bi->i < first_packet_len + 5)
goto wait_more_data;
}
else {
/* We have only one packet and it is an Error packet,
* an error message is attached, so we can display it
*/
desc = &check->bi->data[7];
//Warning("onlyoneERR: %s\n", desc);
set_server_check_status(check, HCHK_STATUS_L7STS, desc);
}
} else if (check->bi->i > first_packet_len + 4) {
unsigned int second_packet_len = ((unsigned int) *(check->bi->data + first_packet_len + 4)) +
(((unsigned int) *(check->bi->data + first_packet_len + 5)) << 8) +
(((unsigned int) *(check->bi->data + first_packet_len + 6)) << 16);
if (check->bi->i == first_packet_len + 4 + second_packet_len + 4 ) {
/* We have 2 packets and that's good */
/* Check if the second packet is a MySQL Error packet or not */
if (*(check->bi->data + first_packet_len + 8) != '\xff') {
/* No error packet */
/* We set the MySQL Version in description for information purpose */
desc = &check->bi->data[5];
//Warning("2packetOK: %s\n", desc);
set_server_check_status(check, HCHK_STATUS_L7OKD, desc);
}
else {
/* An error message is attached in the Error packet
* so we can display it ! :)
*/
desc = &check->bi->data[first_packet_len+11];
//Warning("2packetERR: %s\n", desc);
set_server_check_status(check, HCHK_STATUS_L7STS, desc);
}
}
}
else {
if (!done)
goto wait_more_data;
/* it seems we have a Handshake Initialization packet but without a valid length,
* it must be a protocol error
*/
desc = &check->bi->data[5];
//Warning("protoerr: %s\n", desc);
set_server_check_status(check, HCHK_STATUS_L7RSP, desc);
}
}
break;
case PR_O2_LDAP_CHK:
if (!done && check->bi->i < 14)
goto wait_more_data;
/* Check if the server speaks LDAP (ASN.1/BER)
* http://en.wikipedia.org/wiki/Basic_Encoding_Rules
* http://tools.ietf.org/html/rfc4511
*/
/* http://tools.ietf.org/html/rfc4511#section-4.1.1
* LDAPMessage: 0x30: SEQUENCE
*/
if ((check->bi->i < 14) || (*(check->bi->data) != '\x30')) {
set_server_check_status(check, HCHK_STATUS_L7RSP, "Not LDAPv3 protocol");
}
else {
/* size of LDAPMessage */
msglen = (*(check->bi->data + 1) & 0x80) ? (*(check->bi->data + 1) & 0x7f) : 0;
/* http://tools.ietf.org/html/rfc4511#section-4.2.2
* messageID: 0x02 0x01 0x01: INTEGER 1
* protocolOp: 0x61: bindResponse
*/
if ((msglen > 2) ||
(memcmp(check->bi->data + 2 + msglen, "\x02\x01\x01\x61", 4) != 0)) {
set_server_check_status(check, HCHK_STATUS_L7RSP, "Not LDAPv3 protocol");
goto out_wakeup;
}
/* size of bindResponse */
msglen += (*(check->bi->data + msglen + 6) & 0x80) ? (*(check->bi->data + msglen + 6) & 0x7f) : 0;
/* http://tools.ietf.org/html/rfc4511#section-4.1.9
* ldapResult: 0x0a 0x01: ENUMERATION
*/
if ((msglen > 4) ||
(memcmp(check->bi->data + 7 + msglen, "\x0a\x01", 2) != 0)) {
set_server_check_status(check, HCHK_STATUS_L7RSP, "Not LDAPv3 protocol");
goto out_wakeup;
}
/* http://tools.ietf.org/html/rfc4511#section-4.1.9
* resultCode
*/
check->code = *(check->bi->data + msglen + 9);
if (check->code) {
set_server_check_status(check, HCHK_STATUS_L7STS, "See RFC: http://tools.ietf.org/html/rfc4511#section-4.1.9");
} else {
set_server_check_status(check, HCHK_STATUS_L7OKD, "Success");
}
}
break;
case PR_O2_SPOP_CHK: {
unsigned int framesz;
char err[HCHK_DESC_LEN];
if (!done && check->bi->i < 4)
goto wait_more_data;
memcpy(&framesz, check->bi->data, 4);
framesz = ntohl(framesz);
if (!done && check->bi->i < (4+framesz))
goto wait_more_data;
if (!spoe_handle_healthcheck_response(check->bi->data+4, framesz, err, HCHK_DESC_LEN-1))
set_server_check_status(check, HCHK_STATUS_L7OKD, "SPOA server is ok");
else
set_server_check_status(check, HCHK_STATUS_L7STS, err);
break;
}
default:
/* for other checks (eg: pure TCP), delegate to the main task */
break;
} /* switch */
out_wakeup:
/* collect possible new errors */
if (conn->flags & CO_FL_ERROR)
chk_report_conn_err(conn, 0, 0);
/* Reset the check buffer... */
*check->bi->data = '\0';
check->bi->i = 0;
/* Close the connection... We still attempt to nicely close if,
* for instance, SSL needs to send a "close notify." Later, we perform
* a hard close and reset the connection if some data are pending,
* otherwise we end up with many TIME_WAITs and eat all the source port
* range quickly. To avoid sending RSTs all the time, we first try to
* drain pending data.
*/
__conn_data_stop_both(conn);
conn_data_shutw(conn);
/* OK, let's not stay here forever */
if (check->result == CHK_RES_FAILED)
conn->flags |= CO_FL_ERROR;
task_wakeup(t, TASK_WOKEN_IO);
return;
wait_more_data:
__conn_data_want_recv(conn);
}
/*
* This function is used only for server health-checks. It handles connection
* status updates including errors. If necessary, it wakes the check task up.
* It always returns 0.
*/
static int wake_srv_chk(struct connection *conn)
{
struct check *check = conn->owner;
if (unlikely(conn->flags & CO_FL_ERROR)) {
/* We may get error reports bypassing the I/O handlers, typically
* the case when sending a pure TCP check which fails, then the I/O
* handlers above are not called. This is completely handled by the
* main processing task so let's simply wake it up. If we get here,
* we expect errno to still be valid.
*/
chk_report_conn_err(conn, errno, 0);
__conn_data_stop_both(conn);
task_wakeup(check->task, TASK_WOKEN_IO);
}
else if (!(conn->flags & (CO_FL_DATA_RD_ENA|CO_FL_DATA_WR_ENA|CO_FL_HANDSHAKE))) {
/* we may get here if only a connection probe was required : we
* don't have any data to send nor anything expected in response,
* so the completion of the connection establishment is enough.
*/
task_wakeup(check->task, TASK_WOKEN_IO);
}
if (check->result != CHK_RES_UNKNOWN) {
/* We're here because nobody wants to handle the error, so we
* sure want to abort the hard way.
*/
conn_sock_drain(conn);
conn_force_close(conn);
}
return 0;
}
struct data_cb check_conn_cb = {
.recv = event_srv_chk_r,
.send = event_srv_chk_w,
.wake = wake_srv_chk,
.name = "CHCK",
};
/*
* updates the server's weight during a warmup stage. Once the final weight is
* reached, the task automatically stops. Note that any server status change
* must have updated s->last_change accordingly.
*/
static struct task *server_warmup(struct task *t)
{
struct server *s = t->context;
/* by default, plan on stopping the task */
t->expire = TICK_ETERNITY;
if ((s->admin & SRV_ADMF_MAINT) ||
(s->state != SRV_ST_STARTING))
return t;
/* recalculate the weights and update the state */
server_recalc_eweight(s);
/* probably that we can refill this server with a bit more connections */
pendconn_grab_from_px(s);
/* get back there in 1 second or 1/20th of the slowstart interval,
* whichever is greater, resulting in small 5% steps.
*/
if (s->state == SRV_ST_STARTING)
t->expire = tick_add(now_ms, MS_TO_TICKS(MAX(1000, s->slowstart / 20)));
return t;
}
/*
* establish a server health-check that makes use of a connection.
*
* It can return one of :
* - SF_ERR_NONE if everything's OK and tcpcheck_main() was not called
* - SF_ERR_UP if if everything's OK and tcpcheck_main() was called
* - SF_ERR_SRVTO if there are no more servers
* - SF_ERR_SRVCL if the connection was refused by the server
* - SF_ERR_PRXCOND if the connection has been limited by the proxy (maxconn)
* - SF_ERR_RESOURCE if a system resource is lacking (eg: fd limits, ports, ...)
* - SF_ERR_INTERNAL for any other purely internal errors
* - SF_ERR_CHK_PORT if no port could be found to run a health check on an AF_INET* socket
* Additionally, in the case of SF_ERR_RESOURCE, an emergency log will be emitted.
* Note that we try to prevent the network stack from sending the ACK during the
* connect() when a pure TCP check is used (without PROXY protocol).
*/
static int connect_conn_chk(struct task *t)
{
struct check *check = t->context;
struct server *s = check->server;
struct connection *conn = check->conn;
struct protocol *proto;
int ret;
int quickack;
/* tcpcheck send/expect initialisation */
if (check->type == PR_O2_TCPCHK_CHK)
check->current_step = NULL;
/* prepare the check buffer.
* This should not be used if check is the secondary agent check
* of a server as s->proxy->check_req will relate to the
* configuration of the primary check. Similarly, tcp-check uses
* its own strings.
*/
if (check->type && check->type != PR_O2_TCPCHK_CHK && !(check->state & CHK_ST_AGENT)) {
bo_putblk(check->bo, s->proxy->check_req, s->proxy->check_len);
/* we want to check if this host replies to HTTP or SSLv3 requests
* so we'll send the request, and won't wake the checker up now.
*/
if ((check->type) == PR_O2_SSL3_CHK) {
/* SSL requires that we put Unix time in the request */
int gmt_time = htonl(date.tv_sec);
memcpy(check->bo->data + 11, &gmt_time, 4);
}
else if ((check->type) == PR_O2_HTTP_CHK) {
if (s->proxy->options2 & PR_O2_CHK_SNDST)
bo_putblk(check->bo, trash.str, httpchk_build_status_header(s, trash.str, trash.size));
/* prevent HTTP keep-alive when "http-check expect" is used */
if (s->proxy->options2 & PR_O2_EXP_TYPE)
bo_putstr(check->bo, "Connection: close\r\n");
bo_putstr(check->bo, "\r\n");
*check->bo->p = '\0'; /* to make gdb output easier to read */
}
}
if ((check->type & PR_O2_LB_AGENT_CHK) && check->send_string_len) {
bo_putblk(check->bo, check->send_string, check->send_string_len);
}
/* prepare a new connection */
conn_init(conn);
if (is_addr(&check->addr)) {
/* we'll connect to the check addr specified on the server */
conn->addr.to = check->addr;
}
else {
/* we'll connect to the addr on the server */
conn->addr.to = s->addr;
}
if ((conn->addr.to.ss_family == AF_INET) || (conn->addr.to.ss_family == AF_INET6)) {
int i = 0;
i = srv_check_healthcheck_port(check);
if (i == 0) {
conn->owner = check;
return SF_ERR_CHK_PORT;
}
set_host_port(&conn->addr.to, i);
}
proto = protocol_by_family(conn->addr.to.ss_family);
conn_prepare(conn, proto, check->xprt);
conn_attach(conn, check, &check_conn_cb);
conn->target = &s->obj_type;
/* no client address */
clear_addr(&conn->addr.from);
/* only plain tcp-check supports quick ACK */
quickack = check->type == 0 || check->type == PR_O2_TCPCHK_CHK;
if (check->type == PR_O2_TCPCHK_CHK && !LIST_ISEMPTY(check->tcpcheck_rules)) {
struct tcpcheck_rule *r;
r = LIST_NEXT(check->tcpcheck_rules, struct tcpcheck_rule *, list);
/* if first step is a 'connect', then tcpcheck_main must run it */
if (r->action == TCPCHK_ACT_CONNECT) {
tcpcheck_main(conn);
return SF_ERR_UP;
}
if (r->action == TCPCHK_ACT_EXPECT)
quickack = 0;
}
ret = SF_ERR_INTERNAL;
if (proto->connect)
ret = proto->connect(conn, check->type, quickack ? 2 : 0);
if (s->check.send_proxy && !(check->state & CHK_ST_AGENT)) {
conn->send_proxy_ofs = 1;
conn->flags |= CO_FL_SEND_PROXY;
}
return ret;
}
static struct list pid_list = LIST_HEAD_INIT(pid_list);
static struct pool_head *pool2_pid_list;
void block_sigchld(void)
{
sigset_t set;
sigemptyset(&set);
sigaddset(&set, SIGCHLD);
assert(sigprocmask(SIG_BLOCK, &set, NULL) == 0);
}
void unblock_sigchld(void)
{
sigset_t set;
sigemptyset(&set);
sigaddset(&set, SIGCHLD);
assert(sigprocmask(SIG_UNBLOCK, &set, NULL) == 0);
}
static struct pid_list *pid_list_add(pid_t pid, struct task *t)
{
struct pid_list *elem;
struct check *check = t->context;
elem = pool_alloc2(pool2_pid_list);
if (!elem)
return NULL;
elem->pid = pid;
elem->t = t;
elem->exited = 0;
check->curpid = elem;
LIST_INIT(&elem->list);
LIST_ADD(&pid_list, &elem->list);
return elem;
}
static void pid_list_del(struct pid_list *elem)
{
struct check *check;
if (!elem)
return;
LIST_DEL(&elem->list);
if (!elem->exited)
kill(elem->pid, SIGTERM);
check = elem->t->context;
check->curpid = NULL;
pool_free2(pool2_pid_list, elem);
}
/* Called from inside SIGCHLD handler, SIGCHLD is blocked */
static void pid_list_expire(pid_t pid, int status)
{
struct pid_list *elem;
list_for_each_entry(elem, &pid_list, list) {
if (elem->pid == pid) {
elem->t->expire = now_ms;
elem->status = status;
elem->exited = 1;
task_wakeup(elem->t, TASK_WOKEN_IO);
return;
}
}
}
static void sigchld_handler(struct sig_handler *sh)
{
pid_t pid;
int status;
while ((pid = waitpid(0, &status, WNOHANG)) > 0)
pid_list_expire(pid, status);
}
static int init_pid_list(void)
{
if (pool2_pid_list != NULL)
/* Nothing to do */
return 0;
if (!signal_register_fct(SIGCHLD, sigchld_handler, SIGCHLD)) {
Alert("Failed to set signal handler for external health checks: %s. Aborting.\n",
strerror(errno));
return 1;
}
pool2_pid_list = create_pool("pid_list", sizeof(struct pid_list), MEM_F_SHARED);
if (pool2_pid_list == NULL) {
Alert("Failed to allocate memory pool for external health checks: %s. Aborting.\n",
strerror(errno));
return 1;
}
return 0;
}
/* helper macro to set an environment variable and jump to a specific label on failure. */
#define EXTCHK_SETENV(check, envidx, value, fail) { if (extchk_setenv(check, envidx, value)) goto fail; }
/*
* helper function to allocate enough memory to store an environment variable.
* It will also check that the environment variable is updatable, and silently
* fail if not.
*/
static int extchk_setenv(struct check *check, int idx, const char *value)
{
int len, ret;
char *envname;
int vmaxlen;
if (idx < 0 || idx >= EXTCHK_SIZE) {
Alert("Illegal environment variable index %d. Aborting.\n", idx);
return 1;
}
envname = extcheck_envs[idx].name;
vmaxlen = extcheck_envs[idx].vmaxlen;
/* Check if the environment variable is already set, and silently reject
* the update if this one is not updatable. */
if ((vmaxlen == EXTCHK_SIZE_EVAL_INIT) && (check->envp[idx]))
return 0;
/* Instead of sending NOT_USED, sending an empty value is preferable */
if (strcmp(value, "NOT_USED") == 0) {
value = "";
}
len = strlen(envname) + 1;
if (vmaxlen == EXTCHK_SIZE_EVAL_INIT)
len += strlen(value);
else
len += vmaxlen;
if (!check->envp[idx])
check->envp[idx] = malloc(len + 1);
if (!check->envp[idx]) {
Alert("Failed to allocate memory for the environment variable '%s'. Aborting.\n", envname);
return 1;
}
ret = snprintf(check->envp[idx], len + 1, "%s=%s", envname, value);
if (ret < 0) {
Alert("Failed to store the environment variable '%s'. Reason : %s. Aborting.\n", envname, strerror(errno));
return 1;
}
else if (ret > len) {
Alert("Environment variable '%s' was truncated. Aborting.\n", envname);
return 1;
}
return 0;
}
static int prepare_external_check(struct check *check)
{
struct server *s = check->server;
struct proxy *px = s->proxy;
struct listener *listener = NULL, *l;
int i;
const char *path = px->check_path ? px->check_path : DEF_CHECK_PATH;
char buf[256];
list_for_each_entry(l, &px->conf.listeners, by_fe)
/* Use the first INET, INET6 or UNIX listener */
if (l->addr.ss_family == AF_INET ||
l->addr.ss_family == AF_INET6 ||
l->addr.ss_family == AF_UNIX) {
listener = l;
break;
}
check->curpid = NULL;
check->envp = calloc((EXTCHK_SIZE + 1), sizeof(char *));
if (!check->envp) {
Alert("Failed to allocate memory for environment variables. Aborting\n");
goto err;
}
check->argv = calloc(6, sizeof(char *));
if (!check->argv) {
Alert("Starting [%s:%s] check: out of memory.\n", px->id, s->id);
goto err;
}
check->argv[0] = px->check_command;
if (!listener) {
check->argv[1] = strdup("NOT_USED");
check->argv[2] = strdup("NOT_USED");
}
else if (listener->addr.ss_family == AF_INET ||
listener->addr.ss_family == AF_INET6) {
addr_to_str(&listener->addr, buf, sizeof(buf));
check->argv[1] = strdup(buf);
port_to_str(&listener->addr, buf, sizeof(buf));
check->argv[2] = strdup(buf);
}
else if (listener->addr.ss_family == AF_UNIX) {
const struct sockaddr_un *un;
un = (struct sockaddr_un *)&listener->addr;
check->argv[1] = strdup(un->sun_path);
check->argv[2] = strdup("NOT_USED");
}
else {
Alert("Starting [%s:%s] check: unsupported address family.\n", px->id, s->id);
goto err;
}
addr_to_str(&s->addr, buf, sizeof(buf));
check->argv[3] = strdup(buf);
if (s->addr.ss_family == AF_INET || s->addr.ss_family == AF_INET6)
snprintf(buf, sizeof(buf), "%u", s->svc_port);
else
*buf = 0;
check->argv[4] = strdup(buf);
for (i = 0; i < 5; i++) {
if (!check->argv[i]) {
Alert("Starting [%s:%s] check: out of memory.\n", px->id, s->id);
goto err;
}
}
EXTCHK_SETENV(check, EXTCHK_PATH, path, err);
/* Add proxy environment variables */
EXTCHK_SETENV(check, EXTCHK_HAPROXY_PROXY_NAME, px->id, err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_PROXY_ID, ultoa_r(px->uuid, buf, sizeof(buf)), err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_PROXY_ADDR, check->argv[1], err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_PROXY_PORT, check->argv[2], err);
/* Add server environment variables */
EXTCHK_SETENV(check, EXTCHK_HAPROXY_SERVER_NAME, s->id, err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_SERVER_ID, ultoa_r(s->puid, buf, sizeof(buf)), err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_SERVER_ADDR, check->argv[3], err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_SERVER_PORT, check->argv[4], err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_SERVER_MAXCONN, ultoa_r(s->maxconn, buf, sizeof(buf)), err);
EXTCHK_SETENV(check, EXTCHK_HAPROXY_SERVER_CURCONN, ultoa_r(s->cur_sess, buf, sizeof(buf)), err);
/* Ensure that we don't leave any hole in check->envp */
for (i = 0; i < EXTCHK_SIZE; i++)
if (!check->envp[i])
EXTCHK_SETENV(check, i, "", err);
return 1;
err:
if (check->envp) {
for (i = 0; i < EXTCHK_SIZE; i++)
free(check->envp[i]);
free(check->envp);
check->envp = NULL;
}
if (check->argv) {
for (i = 1; i < 5; i++)
free(check->argv[i]);
free(check->argv);
check->argv = NULL;
}
return 0;
}
/*
* establish a server health-check that makes use of a process.
*
* It can return one of :
* - SF_ERR_NONE if everything's OK
* - SF_ERR_SRVTO if there are no more servers
* - SF_ERR_SRVCL if the connection was refused by the server
* - SF_ERR_PRXCOND if the connection has been limited by the proxy (maxconn)
* - SF_ERR_RESOURCE if a system resource is lacking (eg: fd limits, ports, ...)
* - SF_ERR_INTERNAL for any other purely internal errors
* Additionally, in the case of SF_ERR_RESOURCE, an emergency log will be emitted.
*
* Blocks and then unblocks SIGCHLD
*/
static int connect_proc_chk(struct task *t)
{
char buf[256];
struct check *check = t->context;
struct server *s = check->server;
struct proxy *px = s->proxy;
int status;
pid_t pid;
status = SF_ERR_RESOURCE;
block_sigchld();
pid = fork();
if (pid < 0) {
Alert("Failed to fork process for external health check: %s. Aborting.\n",
strerror(errno));
set_server_check_status(check, HCHK_STATUS_SOCKERR, strerror(errno));
goto out;
}
if (pid == 0) {
/* Child */
extern char **environ;
int fd;
/* close all FDs. Keep stdin/stdout/stderr in verbose mode */
fd = (global.mode & (MODE_QUIET|MODE_VERBOSE)) == MODE_QUIET ? 0 : 3;
while (fd < global.rlimit_nofile)
close(fd++);
environ = check->envp;
extchk_setenv(check, EXTCHK_HAPROXY_SERVER_CURCONN, ultoa_r(s->cur_sess, buf, sizeof(buf)));
execvp(px->check_command, check->argv);
Alert("Failed to exec process for external health check: %s. Aborting.\n",
strerror(errno));
exit(-1);
}
/* Parent */
if (check->result == CHK_RES_UNKNOWN) {
if (pid_list_add(pid, t) != NULL) {
t->expire = tick_add(now_ms, MS_TO_TICKS(check->inter));
if (px->timeout.check && px->timeout.connect) {
int t_con = tick_add(now_ms, px->timeout.connect);
t->expire = tick_first(t->expire, t_con);
}
status = SF_ERR_NONE;
goto out;
}
else {
set_server_check_status(check, HCHK_STATUS_SOCKERR, strerror(errno));
}
kill(pid, SIGTERM); /* process creation error */
}
else
set_server_check_status(check, HCHK_STATUS_SOCKERR, strerror(errno));
out:
unblock_sigchld();
return status;
}
/*
* manages a server health-check that uses a process. Returns
* the time the task accepts to wait, or TIME_ETERNITY for infinity.
*/
static struct task *process_chk_proc(struct task *t)
{
struct check *check = t->context;
struct server *s = check->server;
struct connection *conn = check->conn;
int rv;
int ret;
int expired = tick_is_expired(t->expire, now_ms);
if (!(check->state & CHK_ST_INPROGRESS)) {
/* no check currently running */
if (!expired) /* woke up too early */
return t;
/* we don't send any health-checks when the proxy is
* stopped, the server should not be checked or the check
* is disabled.
*/
if (((check->state & (CHK_ST_ENABLED | CHK_ST_PAUSED)) != CHK_ST_ENABLED) ||
s->proxy->state == PR_STSTOPPED)
goto reschedule;
/* we'll initiate a new check */
set_server_check_status(check, HCHK_STATUS_START, NULL);
check->state |= CHK_ST_INPROGRESS;
ret = connect_proc_chk(t);
switch (ret) {
case SF_ERR_UP:
return t;
case SF_ERR_NONE:
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
t->expire = tick_add(now_ms, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check && s->proxy->timeout.connect) {
int t_con = tick_add(now_ms, s->proxy->timeout.connect);
t->expire = tick_first(t->expire, t_con);
}
goto reschedule;
case SF_ERR_SRVTO: /* ETIMEDOUT */
case SF_ERR_SRVCL: /* ECONNREFUSED, ENETUNREACH, ... */
conn->flags |= CO_FL_ERROR;
chk_report_conn_err(conn, errno, 0);
break;
case SF_ERR_PRXCOND:
case SF_ERR_RESOURCE:
case SF_ERR_INTERNAL:
conn->flags |= CO_FL_ERROR;
chk_report_conn_err(conn, 0, 0);
break;
}
/* here, we have seen a synchronous error, no fd was allocated */
check->state &= ~CHK_ST_INPROGRESS;
check_notify_failure(check);
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
while (tick_is_expired(t->expire, now_ms)) {
int t_con;
t_con = tick_add(t->expire, s->proxy->timeout.connect);
t->expire = tick_add(t->expire, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check)
t->expire = tick_first(t->expire, t_con);
}
}
else {
/* there was a test running.
* First, let's check whether there was an uncaught error,
* which can happen on connect timeout or error.
*/
if (check->result == CHK_RES_UNKNOWN) {
/* good connection is enough for pure TCP check */
struct pid_list *elem = check->curpid;
int status = HCHK_STATUS_UNKNOWN;
if (elem->exited) {
status = elem->status; /* Save in case the process exits between use below */
if (!WIFEXITED(status))
check->code = -1;
else
check->code = WEXITSTATUS(status);
if (!WIFEXITED(status) || WEXITSTATUS(status))
status = HCHK_STATUS_PROCERR;
else
status = HCHK_STATUS_PROCOK;
} else if (expired) {
status = HCHK_STATUS_PROCTOUT;
Warning("kill %d\n", (int)elem->pid);
kill(elem->pid, SIGTERM);
}
set_server_check_status(check, status, NULL);
}
if (check->result == CHK_RES_FAILED) {
/* a failure or timeout detected */
check_notify_failure(check);
}
else if (check->result == CHK_RES_CONDPASS) {
/* check is OK but asks for stopping mode */
check_notify_stopping(check);
}
else if (check->result == CHK_RES_PASSED) {
/* a success was detected */
check_notify_success(check);
}
check->state &= ~CHK_ST_INPROGRESS;
pid_list_del(check->curpid);
rv = 0;
if (global.spread_checks > 0) {
rv = srv_getinter(check) * global.spread_checks / 100;
rv -= (int) (2 * rv * (rand() / (RAND_MAX + 1.0)));
}
t->expire = tick_add(now_ms, MS_TO_TICKS(srv_getinter(check) + rv));
}
reschedule:
while (tick_is_expired(t->expire, now_ms))
t->expire = tick_add(t->expire, MS_TO_TICKS(check->inter));
return t;
}
/*
* manages a server health-check that uses a connection. Returns
* the time the task accepts to wait, or TIME_ETERNITY for infinity.
*/
static struct task *process_chk_conn(struct task *t)
{
struct check *check = t->context;
struct server *s = check->server;
struct connection *conn = check->conn;
int rv;
int ret;
int expired = tick_is_expired(t->expire, now_ms);
if (!(check->state & CHK_ST_INPROGRESS)) {
/* no check currently running */
if (!expired) /* woke up too early */
return t;
/* we don't send any health-checks when the proxy is
* stopped, the server should not be checked or the check
* is disabled.
*/
if (((check->state & (CHK_ST_ENABLED | CHK_ST_PAUSED)) != CHK_ST_ENABLED) ||
s->proxy->state == PR_STSTOPPED)
goto reschedule;
/* we'll initiate a new check */
set_server_check_status(check, HCHK_STATUS_START, NULL);
check->state |= CHK_ST_INPROGRESS;
check->bi->p = check->bi->data;
check->bi->i = 0;
check->bo->p = check->bo->data;
check->bo->o = 0;
ret = connect_conn_chk(t);
switch (ret) {
case SF_ERR_UP:
return t;
case SF_ERR_NONE:
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
t->expire = tick_add(now_ms, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check && s->proxy->timeout.connect) {
int t_con = tick_add(now_ms, s->proxy->timeout.connect);
t->expire = tick_first(t->expire, t_con);
}
if (check->type)
conn_data_want_recv(conn); /* prepare for reading a possible reply */
goto reschedule;
case SF_ERR_SRVTO: /* ETIMEDOUT */
case SF_ERR_SRVCL: /* ECONNREFUSED, ENETUNREACH, ... */
conn->flags |= CO_FL_ERROR;
chk_report_conn_err(conn, errno, 0);
break;
/* should share same code than cases below */
case SF_ERR_CHK_PORT:
check->state |= CHK_ST_PORT_MISS;
case SF_ERR_PRXCOND:
case SF_ERR_RESOURCE:
case SF_ERR_INTERNAL:
conn->flags |= CO_FL_ERROR;
chk_report_conn_err(conn, 0, 0);
break;
}
/* here, we have seen a synchronous error, no fd was allocated */
check->state &= ~CHK_ST_INPROGRESS;
check_notify_failure(check);
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
while (tick_is_expired(t->expire, now_ms)) {
int t_con;
t_con = tick_add(t->expire, s->proxy->timeout.connect);
t->expire = tick_add(t->expire, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check)
t->expire = tick_first(t->expire, t_con);
}
}
else {
/* there was a test running.
* First, let's check whether there was an uncaught error,
* which can happen on connect timeout or error.
*/
if (check->result == CHK_RES_UNKNOWN) {
/* good connection is enough for pure TCP check */
if ((conn->flags & CO_FL_CONNECTED) && !check->type) {
if (check->use_ssl)
set_server_check_status(check, HCHK_STATUS_L6OK, NULL);
else
set_server_check_status(check, HCHK_STATUS_L4OK, NULL);
}
else if ((conn->flags & CO_FL_ERROR) || expired) {
chk_report_conn_err(conn, 0, expired);
}
else
goto out_wait; /* timeout not reached, wait again */
}
/* check complete or aborted */
if (conn->xprt) {
/* The check was aborted and the connection was not yet closed.
* This can happen upon timeout, or when an external event such
* as a failed response coupled with "observe layer7" caused the
* server state to be suddenly changed.
*/
conn_sock_drain(conn);
conn_force_close(conn);
}
if (check->result == CHK_RES_FAILED) {
/* a failure or timeout detected */
check_notify_failure(check);
}
else if (check->result == CHK_RES_CONDPASS) {
/* check is OK but asks for stopping mode */
check_notify_stopping(check);
}
else if (check->result == CHK_RES_PASSED) {
/* a success was detected */
check_notify_success(check);
}
check->state &= ~CHK_ST_INPROGRESS;
rv = 0;
if (global.spread_checks > 0) {
rv = srv_getinter(check) * global.spread_checks / 100;
rv -= (int) (2 * rv * (rand() / (RAND_MAX + 1.0)));
}
t->expire = tick_add(now_ms, MS_TO_TICKS(srv_getinter(check) + rv));
}
reschedule:
while (tick_is_expired(t->expire, now_ms))
t->expire = tick_add(t->expire, MS_TO_TICKS(check->inter));
out_wait:
return t;
}
/*
* manages a server health-check. Returns
* the time the task accepts to wait, or TIME_ETERNITY for infinity.
*/
static struct task *process_chk(struct task *t)
{
struct check *check = t->context;
if (check->type == PR_O2_EXT_CHK)
return process_chk_proc(t);
return process_chk_conn(t);
}
static int start_check_task(struct check *check, int mininter,
int nbcheck, int srvpos)
{
struct task *t;
/* task for the check */
if ((t = task_new()) == NULL) {
Alert("Starting [%s:%s] check: out of memory.\n",
check->server->proxy->id, check->server->id);
return 0;
}
check->task = t;
t->process = process_chk;
t->context = check;
if (mininter < srv_getinter(check))
mininter = srv_getinter(check);
if (global.max_spread_checks && mininter > global.max_spread_checks)
mininter = global.max_spread_checks;
/* check this every ms */
t->expire = tick_add(now_ms, MS_TO_TICKS(mininter * srvpos / nbcheck));
check->start = now;
task_queue(t);
return 1;
}
/*
* Start health-check.
* Returns 0 if OK, ERR_FATAL on error, and prints the error in this case.
*/
static int start_checks()
{
struct proxy *px;
struct server *s;
struct task *t;
int nbcheck=0, mininter=0, srvpos=0;
/* 1- count the checkers to run simultaneously.
* We also determine the minimum interval among all of those which
* have an interval larger than SRV_CHK_INTER_THRES. This interval
* will be used to spread their start-up date. Those which have
* a shorter interval will start independently and will not dictate
* too short an interval for all others.
*/
for (px = proxy; px; px = px->next) {
for (s = px->srv; s; s = s->next) {
if (s->slowstart) {
if ((t = task_new()) == NULL) {
Alert("Starting [%s:%s] check: out of memory.\n", px->id, s->id);
return ERR_ALERT | ERR_FATAL;
}
/* We need a warmup task that will be called when the server
* state switches from down to up.
*/
s->warmup = t;
t->process = server_warmup;
t->context = s;
t->expire = TICK_ETERNITY;
/* server can be in this state only because of */
if (s->state == SRV_ST_STARTING)
task_schedule(s->warmup, tick_add(now_ms, MS_TO_TICKS(MAX(1000, (now.tv_sec - s->last_change)) / 20)));
}
if (s->check.state & CHK_ST_CONFIGURED) {
nbcheck++;
if ((srv_getinter(&s->check) >= SRV_CHK_INTER_THRES) &&
(!mininter || mininter > srv_getinter(&s->check)))
mininter = srv_getinter(&s->check);
}
if (s->agent.state & CHK_ST_CONFIGURED) {
nbcheck++;
if ((srv_getinter(&s->agent) >= SRV_CHK_INTER_THRES) &&
(!mininter || mininter > srv_getinter(&s->agent)))
mininter = srv_getinter(&s->agent);
}
}
}
if (!nbcheck)
return 0;
srand((unsigned)time(NULL));
/*
* 2- start them as far as possible from each others. For this, we will
* start them after their interval set to the min interval divided by
* the number of servers, weighted by the server's position in the list.
*/
for (px = proxy; px; px = px->next) {
if ((px->options2 & PR_O2_CHK_ANY) == PR_O2_EXT_CHK) {
if (init_pid_list()) {
Alert("Starting [%s] check: out of memory.\n", px->id);
return ERR_ALERT | ERR_FATAL;
}
}
for (s = px->srv; s; s = s->next) {
/* A task for the main check */
if (s->check.state & CHK_ST_CONFIGURED) {
if (s->check.type == PR_O2_EXT_CHK) {
if (!prepare_external_check(&s->check))
return ERR_ALERT | ERR_FATAL;
}
if (!start_check_task(&s->check, mininter, nbcheck, srvpos))
return ERR_ALERT | ERR_FATAL;
srvpos++;
}
/* A task for a auxiliary agent check */
if (s->agent.state & CHK_ST_CONFIGURED) {
if (!start_check_task(&s->agent, mininter, nbcheck, srvpos)) {
return ERR_ALERT | ERR_FATAL;
}
srvpos++;
}
}
}
return 0;
}
/*
* Perform content verification check on data in s->check.buffer buffer.
* The buffer MUST be terminated by a null byte before calling this function.
* Sets server status appropriately. The caller is responsible for ensuring
* that the buffer contains at least 13 characters. If <done> is zero, we may
* return 0 to indicate that data is required to decide of a match.
*/
static int httpchk_expect(struct server *s, int done)
{
static char status_msg[] = "HTTP status check returned code <000>";
char status_code[] = "000";
char *contentptr;
int crlf;
int ret;
switch (s->proxy->options2 & PR_O2_EXP_TYPE) {
case PR_O2_EXP_STS:
case PR_O2_EXP_RSTS:
memcpy(status_code, s->check.bi->data + 9, 3);
memcpy(status_msg + strlen(status_msg) - 4, s->check.bi->data + 9, 3);
if ((s->proxy->options2 & PR_O2_EXP_TYPE) == PR_O2_EXP_STS)
ret = strncmp(s->proxy->expect_str, status_code, 3) == 0;
else
ret = regex_exec(s->proxy->expect_regex, status_code);
/* we necessarily have the response, so there are no partial failures */
if (s->proxy->options2 & PR_O2_EXP_INV)
ret = !ret;
set_server_check_status(&s->check, ret ? HCHK_STATUS_L7OKD : HCHK_STATUS_L7STS, status_msg);
break;
case PR_O2_EXP_STR:
case PR_O2_EXP_RSTR:
/* very simple response parser: ignore CR and only count consecutive LFs,
* stop with contentptr pointing to first char after the double CRLF or
* to '\0' if crlf < 2.
*/
crlf = 0;
for (contentptr = s->check.bi->data; *contentptr; contentptr++) {
if (crlf >= 2)
break;
if (*contentptr == '\r')
continue;
else if (*contentptr == '\n')
crlf++;
else
crlf = 0;
}
/* Check that response contains a body... */
if (crlf < 2) {
if (!done)
return 0;
set_server_check_status(&s->check, HCHK_STATUS_L7RSP,
"HTTP content check could not find a response body");
return 1;
}
/* Check that response body is not empty... */
if (*contentptr == '\0') {
if (!done)
return 0;
set_server_check_status(&s->check, HCHK_STATUS_L7RSP,
"HTTP content check found empty response body");
return 1;
}
/* Check the response content against the supplied string
* or regex... */
if ((s->proxy->options2 & PR_O2_EXP_TYPE) == PR_O2_EXP_STR)
ret = strstr(contentptr, s->proxy->expect_str) != NULL;
else
ret = regex_exec(s->proxy->expect_regex, contentptr);
/* if we don't match, we may need to wait more */
if (!ret && !done)
return 0;
if (ret) {
/* content matched */
if (s->proxy->options2 & PR_O2_EXP_INV)
set_server_check_status(&s->check, HCHK_STATUS_L7RSP,
"HTTP check matched unwanted content");
else
set_server_check_status(&s->check, HCHK_STATUS_L7OKD,
"HTTP content check matched");
}
else {
if (s->proxy->options2 & PR_O2_EXP_INV)
set_server_check_status(&s->check, HCHK_STATUS_L7OKD,
"HTTP check did not match unwanted content");
else
set_server_check_status(&s->check, HCHK_STATUS_L7RSP,
"HTTP content check did not match");
}
break;
}
return 1;
}
/*
* return the id of a step in a send/expect session
*/
static int tcpcheck_get_step_id(struct check *check)
{
struct tcpcheck_rule *cur = NULL, *next = NULL;
int i = 0;
/* not even started anything yet => step 0 = initial connect */
if (!check->current_step)
return 0;
cur = check->last_started_step;
/* no step => first step */
if (cur == NULL)
return 1;
/* increment i until current step */
list_for_each_entry(next, check->tcpcheck_rules, list) {
if (next->list.p == &cur->list)
break;
++i;
}
return i;
}
/*
* return the latest known comment before (including) the given stepid
* returns NULL if no comment found
*/
static char * tcpcheck_get_step_comment(struct check *check, int stepid)
{
struct tcpcheck_rule *cur = NULL;
char *ret = NULL;
int i = 0;
/* not even started anything yet, return latest comment found before any action */
if (!check->current_step) {
list_for_each_entry(cur, check->tcpcheck_rules, list) {
if (cur->action == TCPCHK_ACT_COMMENT)
ret = cur->comment;
else
goto return_comment;
}
}
i = 1;
list_for_each_entry(cur, check->tcpcheck_rules, list) {
if (cur->comment)
ret = cur->comment;
if (i >= stepid)
goto return_comment;
++i;
}
return_comment:
return ret;
}
static void tcpcheck_main(struct connection *conn)
{
char *contentptr, *comment;
struct tcpcheck_rule *next;
int done = 0, ret = 0, step = 0;
struct check *check = conn->owner;
struct server *s = check->server;
struct task *t = check->task;
struct list *head = check->tcpcheck_rules;
/* here, we know that the check is complete or that it failed */
if (check->result != CHK_RES_UNKNOWN)
goto out_end_tcpcheck;
/* We have 4 possibilities here :
* 1. we've not yet attempted step 1, and step 1 is a connect, so no
* connection attempt was made yet ;
* 2. we've not yet attempted step 1, and step 1 is a not connect or
* does not exist (no rule), so a connection attempt was made
* before coming here.
* 3. we're coming back after having started with step 1, so we may
* be waiting for a connection attempt to complete.
* 4. the connection + handshake are complete
*
* #2 and #3 are quite similar, we want both the connection and the
* handshake to complete before going any further. Thus we must always
* wait for a connection to complete unless we're before and existing
* step 1.
*/
/* find first rule and skip comments */
next = LIST_NEXT(head, struct tcpcheck_rule *, list);
while (&next->list != head && next->action == TCPCHK_ACT_COMMENT)
next = LIST_NEXT(&next->list, struct tcpcheck_rule *, list);
if ((!(conn->flags & CO_FL_CONNECTED) || (conn->flags & CO_FL_HANDSHAKE)) &&
(check->current_step || &next->list == head)) {
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
while (tick_is_expired(t->expire, now_ms)) {
int t_con;
t_con = tick_add(t->expire, s->proxy->timeout.connect);
t->expire = tick_add(t->expire, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check)
t->expire = tick_first(t->expire, t_con);
}
return;
}
/* special case: option tcp-check with no rule, a connect is enough */
if (&next->list == head) {
set_server_check_status(check, HCHK_STATUS_L4OK, NULL);
goto out_end_tcpcheck;
}
/* no step means first step initialisation */
if (check->current_step == NULL) {
check->last_started_step = NULL;
check->bo->p = check->bo->data;
check->bo->o = 0;
check->bi->p = check->bi->data;
check->bi->i = 0;
check->current_step = next;
t->expire = tick_add(now_ms, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check)
t->expire = tick_add_ifset(now_ms, s->proxy->timeout.check);
}
/* It's only the rules which will enable send/recv */
__conn_data_stop_both(conn);
while (1) {
/* We have to try to flush the output buffer before reading, at
* the end, or if we're about to send a string that does not fit
* in the remaining space. That explains why we break out of the
* loop after this control.
*/
if (check->bo->o &&
(&check->current_step->list == head ||
check->current_step->action != TCPCHK_ACT_SEND ||
check->current_step->string_len >= buffer_total_space(check->bo))) {
if (conn->xprt->snd_buf(conn, check->bo, 0) <= 0) {
if (conn->flags & CO_FL_ERROR) {
chk_report_conn_err(conn, errno, 0);
__conn_data_stop_both(conn);
goto out_end_tcpcheck;
}
break;
}
}
if (&check->current_step->list == head)
break;
/* have 'next' point to the next rule or NULL if we're on the
* last one, connect() needs this.
*/
next = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
/* bypass all comment rules */
while (&next->list != head && next->action == TCPCHK_ACT_COMMENT)
next = LIST_NEXT(&next->list, struct tcpcheck_rule *, list);
/* NULL if we're on the last rule */
if (&next->list == head)
next = NULL;
if (check->current_step->action == TCPCHK_ACT_CONNECT) {
struct protocol *proto;
struct xprt_ops *xprt;
/* mark the step as started */
check->last_started_step = check->current_step;
/* first, shut existing connection */
conn_force_close(conn);
/* prepare new connection */
/* initialization */
conn_init(conn);
conn_attach(conn, check, &check_conn_cb);
conn->target = &s->obj_type;
/* no client address */
clear_addr(&conn->addr.from);
if (is_addr(&check->addr)) {
/* we'll connect to the check addr specified on the server */
conn->addr.to = check->addr;
}
else {
/* we'll connect to the addr on the server */
conn->addr.to = s->addr;
}
proto = protocol_by_family(conn->addr.to.ss_family);
/* port */
if (check->current_step->port)
set_host_port(&conn->addr.to, check->current_step->port);
else if (check->port)
set_host_port(&conn->addr.to, check->port);
if (check->current_step->conn_opts & TCPCHK_OPT_SSL) {
xprt = xprt_get(XPRT_SSL);
}
else {
xprt = xprt_get(XPRT_RAW);
}
conn_prepare(conn, proto, xprt);
ret = SF_ERR_INTERNAL;
if (proto->connect)
ret = proto->connect(conn,
1 /* I/O polling is always needed */,
(next && next->action == TCPCHK_ACT_EXPECT) ? 0 : 2);
if (check->current_step->conn_opts & TCPCHK_OPT_SEND_PROXY) {
conn->send_proxy_ofs = 1;
conn->flags |= CO_FL_SEND_PROXY;
}
/* It can return one of :
* - SF_ERR_NONE if everything's OK
* - SF_ERR_SRVTO if there are no more servers
* - SF_ERR_SRVCL if the connection was refused by the server
* - SF_ERR_PRXCOND if the connection has been limited by the proxy (maxconn)
* - SF_ERR_RESOURCE if a system resource is lacking (eg: fd limits, ports, ...)
* - SF_ERR_INTERNAL for any other purely internal errors
* Additionally, in the case of SF_ERR_RESOURCE, an emergency log will be emitted.
* Note that we try to prevent the network stack from sending the ACK during the
* connect() when a pure TCP check is used (without PROXY protocol).
*/
switch (ret) {
case SF_ERR_NONE:
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
t->expire = tick_add(now_ms, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check && s->proxy->timeout.connect) {
int t_con = tick_add(now_ms, s->proxy->timeout.connect);
t->expire = tick_first(t->expire, t_con);
}
break;
case SF_ERR_SRVTO: /* ETIMEDOUT */
case SF_ERR_SRVCL: /* ECONNREFUSED, ENETUNREACH, ... */
step = tcpcheck_get_step_id(check);
chunk_printf(&trash, "TCPCHK error establishing connection at step %d: %s",
step, strerror(errno));
comment = tcpcheck_get_step_comment(check, step);
if (comment)
chunk_appendf(&trash, " comment: '%s'", comment);
set_server_check_status(check, HCHK_STATUS_L4CON, trash.str);
goto out_end_tcpcheck;
case SF_ERR_PRXCOND:
case SF_ERR_RESOURCE:
case SF_ERR_INTERNAL:
step = tcpcheck_get_step_id(check);
chunk_printf(&trash, "TCPCHK error establishing connection at step %d", step);
comment = tcpcheck_get_step_comment(check, step);
if (comment)
chunk_appendf(&trash, " comment: '%s'", comment);
set_server_check_status(check, HCHK_STATUS_SOCKERR, trash.str);
goto out_end_tcpcheck;
}
/* allow next rule */
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
/* bypass all comment rules */
while (&check->current_step->list != head &&
check->current_step->action == TCPCHK_ACT_COMMENT)
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
if (&check->current_step->list == head)
break;
/* don't do anything until the connection is established */
if (!(conn->flags & CO_FL_CONNECTED)) {
/* update expire time, should be done by process_chk */
/* we allow up to min(inter, timeout.connect) for a connection
* to establish but only when timeout.check is set
* as it may be to short for a full check otherwise
*/
while (tick_is_expired(t->expire, now_ms)) {
int t_con;
t_con = tick_add(t->expire, s->proxy->timeout.connect);
t->expire = tick_add(t->expire, MS_TO_TICKS(check->inter));
if (s->proxy->timeout.check)
t->expire = tick_first(t->expire, t_con);
}
return;
}
} /* end 'connect' */
else if (check->current_step->action == TCPCHK_ACT_SEND) {
/* mark the step as started */
check->last_started_step = check->current_step;
/* reset the read buffer */
if (*check->bi->data != '\0') {
*check->bi->data = '\0';
check->bi->i = 0;
}
if (conn->flags & (CO_FL_SOCK_WR_SH | CO_FL_DATA_WR_SH)) {
conn->flags |= CO_FL_ERROR;
chk_report_conn_err(conn, 0, 0);
goto out_end_tcpcheck;
}
if (check->current_step->string_len >= check->bo->size) {
chunk_printf(&trash, "tcp-check send : string too large (%d) for buffer size (%d) at step %d",
check->current_step->string_len, check->bo->size,
tcpcheck_get_step_id(check));
set_server_check_status(check, HCHK_STATUS_L7RSP, trash.str);
goto out_end_tcpcheck;
}
/* do not try to send if there is no space */
if (check->current_step->string_len >= buffer_total_space(check->bo))
continue;
bo_putblk(check->bo, check->current_step->string, check->current_step->string_len);
*check->bo->p = '\0'; /* to make gdb output easier to read */
/* go to next rule and try to send */
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
/* bypass all comment rules */
while (&check->current_step->list != head &&
check->current_step->action == TCPCHK_ACT_COMMENT)
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
if (&check->current_step->list == head)
break;
} /* end 'send' */
else if (check->current_step->action == TCPCHK_ACT_EXPECT) {
if (unlikely(check->result == CHK_RES_FAILED))
goto out_end_tcpcheck;
if (conn->xprt->rcv_buf(conn, check->bi, check->bi->size) <= 0) {
if (conn->flags & (CO_FL_ERROR | CO_FL_SOCK_RD_SH | CO_FL_DATA_RD_SH)) {
done = 1;
if ((conn->flags & CO_FL_ERROR) && !check->bi->i) {
/* Report network errors only if we got no other data. Otherwise
* we'll let the upper layers decide whether the response is OK
* or not. It is very common that an RST sent by the server is
* reported as an error just after the last data chunk.
*/
chk_report_conn_err(conn, errno, 0);
goto out_end_tcpcheck;
}
}
else
break;
}
/* mark the step as started */
check->last_started_step = check->current_step;
/* Intermediate or complete response received.
* Terminate string in check->bi->data buffer.
*/
if (check->bi->i < check->bi->size) {
check->bi->data[check->bi->i] = '\0';
}
else {
check->bi->data[check->bi->i - 1] = '\0';
done = 1; /* buffer full, don't wait for more data */
}
contentptr = check->bi->data;
/* Check that response body is not empty... */
if (!check->bi->i) {
if (!done)
continue;
/* empty response */
step = tcpcheck_get_step_id(check);
chunk_printf(&trash, "TCPCHK got an empty response at step %d", step);
comment = tcpcheck_get_step_comment(check, step);
if (comment)
chunk_appendf(&trash, " comment: '%s'", comment);
set_server_check_status(check, HCHK_STATUS_L7RSP, trash.str);
goto out_end_tcpcheck;
}
if (!done && (check->current_step->string != NULL) && (check->bi->i < check->current_step->string_len) )
continue; /* try to read more */
tcpcheck_expect:
if (check->current_step->string != NULL)
ret = my_memmem(contentptr, check->bi->i, check->current_step->string, check->current_step->string_len) != NULL;
else if (check->current_step->expect_regex != NULL)
ret = regex_exec(check->current_step->expect_regex, contentptr);
if (!ret && !done)
continue; /* try to read more */
/* matched */
step = tcpcheck_get_step_id(check);
if (ret) {
/* matched but we did not want to => ERROR */
if (check->current_step->inverse) {
/* we were looking for a string */
if (check->current_step->string != NULL) {
chunk_printf(&trash, "TCPCHK matched unwanted content '%s' at step %d",
check->current_step->string, step);
}
else {
/* we were looking for a regex */
chunk_printf(&trash, "TCPCHK matched unwanted content (regex) at step %d", step);
}
comment = tcpcheck_get_step_comment(check, step);
if (comment)
chunk_appendf(&trash, " comment: '%s'", comment);
set_server_check_status(check, HCHK_STATUS_L7RSP, trash.str);
goto out_end_tcpcheck;
}
/* matched and was supposed to => OK, next step */
else {
/* allow next rule */
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
/* bypass all comment rules */
while (&check->current_step->list != head &&
check->current_step->action == TCPCHK_ACT_COMMENT)
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
if (&check->current_step->list == head)
break;
if (check->current_step->action == TCPCHK_ACT_EXPECT)
goto tcpcheck_expect;
__conn_data_stop_recv(conn);
}
}
else {
/* not matched */
/* not matched and was not supposed to => OK, next step */
if (check->current_step->inverse) {
/* allow next rule */
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
/* bypass all comment rules */
while (&check->current_step->list != head &&
check->current_step->action == TCPCHK_ACT_COMMENT)
check->current_step = LIST_NEXT(&check->current_step->list, struct tcpcheck_rule *, list);
if (&check->current_step->list == head)
break;
if (check->current_step->action == TCPCHK_ACT_EXPECT)
goto tcpcheck_expect;
__conn_data_stop_recv(conn);
}
/* not matched but was supposed to => ERROR */
else {
/* we were looking for a string */
if (check->current_step->string != NULL) {
chunk_printf(&trash, "TCPCHK did not match content '%s' at step %d",
check->current_step->string, step);
}
else {
/* we were looking for a regex */
chunk_printf(&trash, "TCPCHK did not match content (regex) at step %d",
step);
}
comment = tcpcheck_get_step_comment(check, step);
if (comment)
chunk_appendf(&trash, " comment: '%s'", comment);
set_server_check_status(check, HCHK_STATUS_L7RSP, trash.str);
goto out_end_tcpcheck;
}
}
} /* end expect */
} /* end loop over double chained step list */
/* We're waiting for some I/O to complete, we've reached the end of the
* rules, or both. Do what we have to do, otherwise we're done.
*/
if (&check->current_step->list == head && !check->bo->o) {
set_server_check_status(check, HCHK_STATUS_L7OKD, "(tcp-check)");
goto out_end_tcpcheck;
}
/* warning, current_step may now point to the head */
if (check->bo->o)
__conn_data_want_send(conn);
if (&check->current_step->list != head &&
check->current_step->action == TCPCHK_ACT_EXPECT)
__conn_data_want_recv(conn);
return;
out_end_tcpcheck:
/* collect possible new errors */
if (conn->flags & CO_FL_ERROR)
chk_report_conn_err(conn, 0, 0);
/* cleanup before leaving */
check->current_step = NULL;
if (check->result == CHK_RES_FAILED)
conn->flags |= CO_FL_ERROR;
__conn_data_stop_both(conn);
return;
}
const char *init_check(struct check *check, int type)
{
check->type = type;
/* Allocate buffer for requests... */
if ((check->bi = calloc(sizeof(struct buffer) + global.tune.chksize, sizeof(char))) == NULL) {
return "out of memory while allocating check buffer";
}
check->bi->size = global.tune.chksize;
/* Allocate buffer for responses... */
if ((check->bo = calloc(sizeof(struct buffer) + global.tune.chksize, sizeof(char))) == NULL) {
return "out of memory while allocating check buffer";
}
check->bo->size = global.tune.chksize;
/* Allocate buffer for partial results... */
if ((check->conn = calloc(1, sizeof(struct connection))) == NULL) {
return "out of memory while allocating check connection";
}
check->conn->t.sock.fd = -1; /* no agent in progress yet */
return NULL;
}
void free_check(struct check *check)
{
free(check->bi);
check->bi = NULL;
free(check->bo);
check->bo = NULL;
free(check->conn);
check->conn = NULL;
}
void email_alert_free(struct email_alert *alert)
{
struct tcpcheck_rule *rule, *back;
if (!alert)
return;
list_for_each_entry_safe(rule, back, &alert->tcpcheck_rules, list)
free(rule);
free(alert);
}
static struct task *process_email_alert(struct task *t)
{
struct check *check = t->context;
struct email_alertq *q;
q = container_of(check, typeof(*q), check);
if (!(check->state & CHK_ST_ENABLED)) {
if (LIST_ISEMPTY(&q->email_alerts)) {
/* All alerts processed, delete check */
task_delete(t);
task_free(t);
check->task = NULL;
return NULL;
} else {
struct email_alert *alert;
alert = LIST_NEXT(&q->email_alerts, typeof(alert), list);
check->tcpcheck_rules = &alert->tcpcheck_rules;
LIST_DEL(&alert->list);
check->state |= CHK_ST_ENABLED;
}
}
process_chk(t);
if (!(check->state & CHK_ST_INPROGRESS) && check->tcpcheck_rules) {
struct email_alert *alert;
alert = container_of(check->tcpcheck_rules, typeof(*alert), tcpcheck_rules);
email_alert_free(alert);
check->tcpcheck_rules = NULL;
check->state &= ~CHK_ST_ENABLED;
}
return t;
}
static int init_email_alert_checks(struct server *s)
{
int i;
struct mailer *mailer;
const char *err_str;
struct proxy *p = s->proxy;
if (p->email_alert.queues)
/* Already initialised, nothing to do */
return 1;
p->email_alert.queues = calloc(p->email_alert.mailers.m->count, sizeof *p->email_alert.queues);
if (!p->email_alert.queues) {
err_str = "out of memory while allocating checks array";
goto error_alert;
}
for (i = 0, mailer = p->email_alert.mailers.m->mailer_list;
i < p->email_alert.mailers.m->count; i++, mailer = mailer->next) {
struct email_alertq *q = &p->email_alert.queues[i];
struct check *check = &q->check;
LIST_INIT(&q->email_alerts);
check->inter = p->email_alert.mailers.m->timeout.mail;
check->rise = DEF_AGENT_RISETIME;
check->fall = DEF_AGENT_FALLTIME;
err_str = init_check(check, PR_O2_TCPCHK_CHK);
if (err_str) {
goto error_free;
}
check->xprt = mailer->xprt;
if (!get_host_port(&mailer->addr))
/* Default to submission port */
check->port = 587;
check->addr = mailer->addr;
check->server = s;
}
return 1;
error_free:
while (i-- > 1)
task_free(p->email_alert.queues[i].check.task);
free(p->email_alert.queues);
p->email_alert.queues = NULL;
error_alert:
Alert("Email alert [%s] could not be initialised: %s\n", p->id, err_str);
return 0;
}
static int add_tcpcheck_expect_str(struct list *list, const char *str)
{
struct tcpcheck_rule *tcpcheck;
tcpcheck = calloc(1, sizeof *tcpcheck);
if (!tcpcheck)
return 0;
tcpcheck->action = TCPCHK_ACT_EXPECT;
tcpcheck->string = strdup(str);
if (!tcpcheck->string) {
free(tcpcheck);
return 0;
}
LIST_ADDQ(list, &tcpcheck->list);
return 1;
}
static int add_tcpcheck_send_strs(struct list *list, const char * const *strs)
{
struct tcpcheck_rule *tcpcheck;
const char *in;
char *dst;
int i;
tcpcheck = calloc(1, sizeof *tcpcheck);
if (!tcpcheck)
return 0;
tcpcheck->action = TCPCHK_ACT_SEND;
tcpcheck->string_len = 0;
for (i = 0; strs[i]; i++)
tcpcheck->string_len += strlen(strs[i]);
tcpcheck->string = malloc(tcpcheck->string_len + 1);
if (!tcpcheck->string) {
free(tcpcheck);
return 0;
}
dst = tcpcheck->string;
for (i = 0; strs[i]; i++)
for (in = strs[i]; (*dst = *in++); dst++);
*dst = 0;
LIST_ADDQ(list, &tcpcheck->list);
return 1;
}
static int enqueue_one_email_alert(struct email_alertq *q, const char *msg)
{
struct email_alert *alert = NULL;
struct tcpcheck_rule *tcpcheck;
struct check *check = &q->check;
struct proxy *p = check->server->proxy;
alert = calloc(1, sizeof *alert);
if (!alert) {
goto error;
}
LIST_INIT(&alert->tcpcheck_rules);
tcpcheck = calloc(1, sizeof *tcpcheck);
if (!tcpcheck)
goto error;
tcpcheck->action = TCPCHK_ACT_CONNECT;
LIST_ADDQ(&alert->tcpcheck_rules, &tcpcheck->list);
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "220 "))
goto error;
{
const char * const strs[4] = { "EHLO ", p->email_alert.myhostname, "\r\n" };
if (!add_tcpcheck_send_strs(&alert->tcpcheck_rules, strs))
goto error;
}
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "250 "))
goto error;
{
const char * const strs[4] = { "MAIL FROM:<", p->email_alert.from, ">\r\n" };
if (!add_tcpcheck_send_strs(&alert->tcpcheck_rules, strs))
goto error;
}
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "250 "))
goto error;
{
const char * const strs[4] = { "RCPT TO:<", p->email_alert.to, ">\r\n" };
if (!add_tcpcheck_send_strs(&alert->tcpcheck_rules, strs))
goto error;
}
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "250 "))
goto error;
{
const char * const strs[2] = { "DATA\r\n" };
if (!add_tcpcheck_send_strs(&alert->tcpcheck_rules, strs))
goto error;
}
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "354 "))
goto error;
{
struct tm tm;
char datestr[48];
const char * const strs[18] = {
"From: ", p->email_alert.from, "\r\n",
"To: ", p->email_alert.to, "\r\n",
"Date: ", datestr, "\r\n",
"Subject: [HAproxy Alert] ", msg, "\r\n",
"\r\n",
msg, "\r\n",
"\r\n",
".\r\n",
NULL
};
get_localtime(date.tv_sec, &tm);
if (strftime(datestr, sizeof(datestr), "%a, %d %b %Y %T %z (%Z)", &tm) == 0) {
goto error;
}
if (!add_tcpcheck_send_strs(&alert->tcpcheck_rules, strs))
goto error;
}
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "250 "))
goto error;
{
const char * const strs[2] = { "QUIT\r\n" };
if (!add_tcpcheck_send_strs(&alert->tcpcheck_rules, strs))
goto error;
}
if (!add_tcpcheck_expect_str(&alert->tcpcheck_rules, "221 "))
goto error;
if (!check->task) {
struct task *t;
if ((t = task_new()) == NULL)
goto error;
check->task = t;
t->process = process_email_alert;
t->context = check;
/* check this in one ms */
t->expire = tick_add(now_ms, MS_TO_TICKS(1));
check->start = now;
task_queue(t);
}
LIST_ADDQ(&q->email_alerts, &alert->list);
return 1;
error:
email_alert_free(alert);
return 0;
}
static void enqueue_email_alert(struct proxy *p, const char *msg)
{
int i;
struct mailer *mailer;
for (i = 0, mailer = p->email_alert.mailers.m->mailer_list;
i < p->email_alert.mailers.m->count; i++, mailer = mailer->next) {
if (!enqueue_one_email_alert(&p->email_alert.queues[i], msg)) {
Alert("Email alert [%s] could not be enqueued: out of memory\n", p->id);
return;
}
}
return;
}
/*
* Send email alert if configured.
*/
void send_email_alert(struct server *s, int level, const char *format, ...)
{
va_list argp;
char buf[1024];
int len;
struct proxy *p = s->proxy;
if (!p->email_alert.mailers.m || level > p->email_alert.level ||
format == NULL || !init_email_alert_checks(s))
return;
va_start(argp, format);
len = vsnprintf(buf, sizeof(buf), format, argp);
va_end(argp);
if (len < 0 || len >= sizeof(buf)) {
Alert("Email alert [%s] could not format message\n", p->id);
return;
}
enqueue_email_alert(p, buf);
}
/*
* Return value:
* the port to be used for the health check
* 0 in case no port could be found for the check
*/
int srv_check_healthcheck_port(struct check *chk)
{
int i = 0;
struct server *srv = NULL;
srv = chk->server;
/* If neither a port nor an addr was specified and no check transport
* layer is forced, then the transport layer used by the checks is the
* same as for the production traffic. Otherwise we use raw_sock by
* default, unless one is specified.
*/
if (!chk->port && !is_addr(&chk->addr)) {
chk->use_ssl |= (srv->use_ssl || (srv->proxy->options & PR_O_TCPCHK_SSL));
chk->send_proxy |= (srv->pp_opts);
}
/* by default, we use the health check port ocnfigured */
if (chk->port > 0)
return chk->port;
/* try to get the port from check_core.addr if check.port not set */
i = get_host_port(&chk->addr);
if (i > 0)
return i;
/* try to get the port from server address */
/* prevent MAPPORTS from working at this point, since checks could
* not be performed in such case (MAPPORTS impose a relative ports
* based on live traffic)
*/
if (srv->flags & SRV_F_MAPPORTS)
return 0;
i = srv->svc_port; /* by default */
if (i > 0)
return i;
return 0;
}
__attribute__((constructor))
static void __check_init(void)
{
hap_register_post_check(start_checks);
}
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/