------------------- HAProxy Reference Manual ------------------- version 1.3.15 willy tarreau 2008/04/19 !!!! NOTE: THIS DOCUMENT IS OUTDATED !!!! Please use "configuration.txt" from the same directory, or download an up-to-date version from the following location : http://haproxy.1wt.eu/download/1.4/doc/configuration.txt ============ | Abstract | ============ HAProxy is a TCP/HTTP reverse proxy which is particularly suited for high availability environments. Indeed, it can : - route HTTP requests depending on statically assigned cookies ; - spread the load among several servers while assuring server persistence through the use of HTTP cookies ; - switch to backup servers in the event a main one fails ; - accept connections to special ports dedicated to service monitoring ; - stop accepting connections without breaking existing ones ; - add/modify/delete HTTP headers both ways ; - block requests matching a particular pattern ; - hold clients to the right application server depending on application cookies - report detailed status as HTML pages to authenticated users from an URI intercepted from the application. It needs very little resource. Its event-driven architecture allows it to easily handle thousands of simultaneous connections on hundreds of instances without risking the system's stability. ==================== | Start parameters | ==================== There are only a few command line options : -f -n = 'maxconn' in 'global' section -N = 'maxconn' in 'listen' or 'default' sections -d starts in foregreound with debugging mode enabled -D starts in daemon mode -Ds starts in systemd daemon mode -q disable messages on output -V displays messages on output even when -q or 'quiet' are specified. -c only checks config file and exits with code 0 if no error was found, or exits with code 1 if a syntax error was found. -p asks the process to write down each of its children's pids to this file in daemon mode. -sf specifies a list of pids to send a FINISH signal to after startup. -st specifies a list of pids to send a TERMINATE signal to after startup. -s shows statistics (only if compiled in) -l shows even more statistics (implies '-s') -dk disables use of kqueue() -de disables use of epoll() -dp disables use of poll() -db disables background mode (stays in foreground, useful for debugging) -m enforces a memory usage limit to a maximum of megabytes. The maximal number of connections per proxy instance is used as the default parameter for each instance for which the 'maxconn' paramter is not set in the 'listen' section. The maximal number of total connections limits the number of connections used by the whole process if the 'maxconn' parameter is not set in the 'global' section. The debugging mode has the same effect as the 'debug' option in the 'global' section. When the proxy runs in this mode, it dumps every connections, disconnections, timestamps, and HTTP headers to stdout. This should NEVER be used in an init script since it will prevent the system from starting up. For debugging, the '-db' option is very useful as it temporarily disables daemon mode and multi-process mode. The service can then be stopped by simply pressing Ctrl-C, without having to edit the config nor run full debug. Statistics are only available if compiled in with the 'STATTIME' option. It's only used during code optimization phases, and will soon disappear. The '-st' and '-sf' options are used for hot reconfiguration (see below). ====================== | Configuration file | ====================== Structure ========= The configuration file parser ignores empty lines, spaces, tabs. Anything between a sharp ('#') not following a backslash ('\'), and the end of a line constitutes a comment and is ignored too. The configuration file is segmented in sections. A section begins whenever one of these 3 keywords are encountered : - 'global' - 'listen' - 'defaults' Every parameter refer to the section beginning at the last one of these 3 keywords. 1) Global parameters ==================== Global parameters affect the whole process behaviour. They are all set in the 'global' section. There may be several 'global' sections if needed, but their parameters will only be merged. Allowed parameters in 'global' section include the following ones : - log
[max_level] - maxconn - uid - gid - user - group - chroot - nbproc - daemon - debug - nokqueue - noepoll - nopoll - quiet - pidfile - ulimit-n - stats - tune.maxpollevents 1.1) Event logging ------------------ Most events are logged : start, stop, servers going up and down, connections and errors. Each event generates a syslog message which can be sent to up to 2 servers. The syntax is : log [max_level] Connections are logged at level "info". Services initialization and servers going up are logged at level "notice", termination signals are logged at "warning", and definitive service termination, as well as loss of servers are logged at level "alert". The optional parameter specifies above what level messages should be sent. Level can take one of these 8 values : emerg, alert, crit, err, warning, notice, info, debug For backwards compatibility with versions 1.1.16 and earlier, the default level value is "debug" if not specified. Permitted facilities are : kern, user, mail, daemon, auth, syslog, lpr, news, uucp, cron, auth2, ftp, ntp, audit, alert, cron2, local0, local1, local2, local3, local4, local5, local6, local7 According to RFC3164, messages are truncated to 1024 bytes before being emitted. Example : --------- global log 192.168.2.200 local3 log 127.0.0.1 local4 notice 1.2) limiting the number of connections --------------------------------------- It is possible and recommended to limit the global number of per-process connections using the 'maxconn' global keyword. Since one connection includes both a client and a server, it means that the max number of TCP sessions will be about the double of this number. It's important to understand this when trying to find best values for 'ulimit -n' before starting the proxy. To anticipate the number of sockets needed, all these parameters must be counted : - 1 socket per incoming connection - 1 socket per outgoing connection - 1 socket per address/port/proxy tuple. - 1 socket per server being health-checked - 1 socket for all logs In simple configurations where each proxy only listens one one address/port, set the limit of file descriptors (ulimit -n) to (2 * maxconn + nbproxies + nbservers + 1). Starting with versions 1.1.32/1.2.6, it is now possible to set the limit in the configuration using the 'ulimit-n' global keyword, provided the proxy is started as root. This puts an end to the recurrent problem of ensuring that the system limits are adapted to the proxy values. Note that these limits are per-process. Example : --------- global maxconn 32000 ulimit-n 65536 1.3) Drop of priviledges ------------------------ In order to reduce the risk and consequences of attacks, in the event where a yet non-identified vulnerability would be successfully exploited, it's possible to lower the process priviledges and even isolate it in a riskless directory. In the 'global' section, the 'uid' parameter sets a numerical user identifier which the process will switch to after binding its listening sockets. The value '0', which normally represents the super-user, here indicates that the UID must not change during startup. It's the default behaviour. The 'gid' parameter does the same for the group identifier. If setting an uid is not possible because of deployment constraints, it is possible to set a user name with the 'user' keyword followed by a valid user name. The same is true for the gid. It is possible to specify a group name after the 'group' keyword. It is particularly advised against use of generic accounts such as 'nobody' because it has the same consequences as using 'root' if other services use them. The 'chroot' parameter makes the process isolate itself in an empty directory just before switching its UID. This type of isolation (chroot) can sometimes be worked around on certain OS (Linux, Solaris), provided that the attacker has gained 'root' priviledges and has the ability to use or create a directory. For this reason, it's capital to use a dedicated directory and not to share one between several services of different nature. To make isolation more resistant, it's recommended to use an empty directory without any right, and to change the UID of the process so that it cannot do anything there. Note: in the event where such a vulnerability would be exploited, it's most likely that first attempts would kill the process due to 'Segmentation Fault', 'Bus Error' or 'Illegal Instruction' signals. Eventhough it's true that isolating the server reduces the risks of intrusion, it's sometimes useful to find why a process dies, via the analysis of a 'core' file, although very rare (the last bug of this sort was fixed in 1.1.9). For security reasons, most systems disable the generation of core file when a process changes its UID. So the two workarounds are either to start the process from a restricted user account, which will not be able to chroot itself, or start it as root and not change the UID. In both cases the core will be either in the start or the chroot directories. Do not forget to allow core dumps prior to start the process : # ulimit -c unlimited Example : --------- # with uid/gid global uid 30000 gid 30000 chroot /var/chroot/haproxy # with user/group global user haproxy group public chroot /var/chroot/haproxy 1.4) Startup modes ------------------ The service can start in several different modes : - foreground / background - quiet / normal / debug The default mode is normal, foreground, which means that the program doesn't return once started. NEVER EVER use this mode in a system startup script, or the system won't boot. It needs to be started in background, so that it returns immediately after forking. That's accomplished by the 'daemon' option in the 'global' section, which is the equivalent of the '-D' command line argument. The '-db' command line argument overrides the 'daemon' and 'nbproc' global options to make the process run in normal, foreground mode. Moreover, certain alert messages are still sent to the standard output even in 'daemon' mode. To make them disappear, simply add the 'quiet' option in the 'global' section. This option has no command-line equivalent. Last, the 'debug' mode, enabled with the 'debug' option in the 'global' section, and which is equivalent of the '-d' option, allows deep TCP/HTTP analysis, with timestamped display of each connection, disconnection, and HTTP headers for both ways. This mode is incompatible with 'daemon' and 'quiet' modes for obvious reasons. 1.5) Increasing the overall processing power -------------------------------------------- On multi-processor systems, it may seem to be a shame to use only one processor, eventhough the load needed to saturate a recent processor is far above common usage. Anyway, for very specific needs, the proxy can start several processes between which the operating system will spread the incoming connections. The number of processes is controlled by the 'nbproc' parameter in the 'global' section. It defaults to 1, and obviously works only in 'daemon' mode. One typical usage of this parameter has been to workaround the default per-process file-descriptor limit that Solaris imposes to user processes. Example : --------- global daemon quiet nbproc 2 1.6) Helping process management ------------------------------- Haproxy now supports the notion of pidfile. If the '-p' command line argument, or the 'pidfile' global option is followed with a file name, this file will be removed, then filled with all children's pids, one per line (only in daemon mode). This file is NOT within the chroot, which allows to work with a readonly chroot. It will be owned by the user starting the process, and will have permissions 0644. Example : --------- global daemon quiet nbproc 2 pidfile /var/run/haproxy-private.pid # to stop only those processes among others : # kill $( [ :[,...] ] - is the name of the instance. This name will be reported in logs, so it is good to have it reflect the proxied service. No unicity test is done on this name, and it's not mandatory for it to be unique, but highly recommended. - is the IP address the proxy binds to. Empty address, '*' and '0.0.0.0' all mean that the proxy listens to all valid addresses on the system. - is either a unique port, or a port range for which the proxy will accept connections for the IP address specified above. This range can be : - a numerical port (ex: '80') - a dash-delimited ports range explicitly stating the lower and upper bounds (ex: '2000-2100') which are included in the range. Particular care must be taken against port ranges, because every couple consumes one socket (=a file descriptor), so it's easy to eat lots of descriptors with a simple range. The couple must be used only once among all instances running on a same system. Please note that attaching to ports lower than 1024 need particular priviledges to start the program, which are independent of the 'uid' parameter. - the : couple may be repeated indefinitely to require the proxy to listen to other addresses and/or ports. To achieve this, simply separate them with a coma. Examples : --------- listen http_proxy :80 listen x11_proxy 127.0.0.1:6000-6009 listen smtp_proxy 127.0.0.1:25,127.0.0.1:587 listen ldap_proxy :389,:663 In the event that all addresses do not fit line width, it's preferable to detach secondary addresses on other lines with the 'bind' keyword. If this keyword is used, it's not even necessary to specify the first address on the 'listen' line, which sometimes makes multiple configuration handling easier : bind [ :[,...] ] Examples : ---------- listen http_proxy bind :80,:443 bind 10.0.0.1:10080,10.0.0.1:10443 2.1) Inhibiting a service ------------------------- A service may be disabled for maintenance reasons, without needing to comment out the whole section, simply by specifying the 'disabled' keyword in the section to be disabled : listen smtp_proxy 0.0.0.0:25 disabled Note: the 'enabled' keyword allows to enable a service which has been disabled previously by a default configuration. 2.2) Modes of operation ----------------------- A service can work in 3 different distinct modes : - TCP - HTTP - health TCP mode -------- In this mode, the service relays TCP connections as soon as they're established, towards one or several servers. No processing is done on the stream. It's only an association of source(addr:port) -> destination(addr:port). To use this mode, you must specify 'mode tcp' in the 'listen' section. This is the default mode. Example : --------- listen smtp_proxy 0.0.0.0:25 mode tcp HTTP mode --------- In this mode, the service relays TCP connections towards one or several servers, when it has enough informations to decide, which normally means that all HTTP headers have been read. Some of them may be scanned for a cookie or a pattern matching a regex. To use this mode, specify 'mode http' in the 'listen' section. Example : --------- listen http_proxy 0.0.0.0:80 mode http Health-checking mode -------------------- This mode provides a way for external components to check the proxy's health. It is meant to be used with intelligent load-balancers which can use send/expect scripts to check for all of their servers' availability. This one simply accepts the connection, returns the word 'OK' and closes it. If the 'option httpchk' is set, then the reply will be 'HTTP/1.0 200 OK' with no data, so that it can be tested from a tool which supports HTTP health-checks. To enable it, simply specify 'health' as the working mode : Example : --------- # simple response : 'OK' listen health_check 0.0.0.0:60000 mode health # HTTP response : 'HTTP/1.0 200 OK' listen http_health_check 0.0.0.0:60001 mode health option httpchk 2.2.1 Monitoring ---------------- Versions 1.1.32 and 1.2.6 provide a new solution to check the proxy's availability without perturbating the service. The 'monitor-net' keyword was created to specify a network of equipments which CANNOT use the service for anything but health-checks. This is particularly suited to TCP proxies, because it prevents the proxy from relaying the monitor's connection to the remote server. When used with TCP, the connection is accepted then closed and nothing is logged. This is enough for a front-end load-balancer to detect the service as available. When used with HTTP, the connection is accepted, nothing is logged, the following response is sent, then the session is closed : "HTTP/1.0 200 OK". This is normally enough for any front-end HTTP load-balancer to detect the service as available too, both with TCP and HTTP checks. Proxies using the "monitor-net" keyword can remove the "option dontlognull", as it will make them log empty connections from hosts outside the monitoring network. Example : --------- listen tse-proxy bind :3389,:1494,:5900 # TSE, ICA and VNC at once. mode tcp balance roundrobin server tse-farm 192.168.1.10 monitor-net 192.168.1.252/31 # L4 load-balancers on .252 and .253 When the system executing the checks is located behind a proxy, the monitor-net keyword cannot be used because haproxy will always see the proxy's address. To overcome this limitation, version 1.2.15 brought the 'monitor-uri' keyword. It defines an URI which will not be forwarded nor logged, but for which haproxy will immediately send an "HTTP/1.0 200 OK" response. This makes it possible to check the validity of the reverse-proxy->haproxy chain with one request. It can be used in HTTPS checks in front of an stunnel -> haproxy combination for instance. Obviously, this keyword is only valid in HTTP mode, otherwise there is no notion of URI. Note that the method and HTTP versions are simply ignored. Example : --------- listen stunnel_backend :8080 mode http balance roundrobin server web1 192.168.1.10:80 check server web2 192.168.1.11:80 check monitor-uri /haproxy_test 2.3) Limiting the number of simultaneous connections ---------------------------------------------------- The 'maxconn' parameter allows a proxy to refuse connections above a certain amount of simultaneous ones. When the limit is reached, it simply stops listening, but the system may still be accepting them because of the back log queue. These connections will be processed later when other ones have freed some slots. This provides a serialization effect which helps very fragile servers resist to high loads. See further for system limitations. Example : --------- listen tiny_server 0.0.0.0:80 maxconn 10 2.4) Soft stop -------------- It is possible to stop services without breaking existing connections by the sending of the SIGUSR1 signal to the process. All services are then put into soft-stop state, which means that they will refuse to accept new connections, except for those which have a non-zero value in the 'grace' parameter, in which case they will still accept connections for the specified amount of time, in milliseconds. This makes it possible to tell a load-balancer that the service is failing, while still doing the job during the time it needs to detect it. Note: active connections are never killed. In the worst case, the user will have to wait for all of them to close or to time-out, or simply kill the process normally (SIGTERM). The default 'grace' value is '0'. Example : --------- # enter soft stop after 'killall -USR1 haproxy' # the service will still run 10 seconds after the signal listen http_proxy 0.0.0.0:80 mode http grace 10000 # this port is dedicated to a load-balancer, and must fail immediately listen health_check 0.0.0.0:60000 mode health grace 0 As of version 1.2.8, a new soft-reconfiguration mechanism has been introduced. It is now possible to "pause" all the proxies by sending a SIGTTOU signal to the processes. This will disable the listening socket without breaking existing connections. After that, sending a SIGTTIN signal to those processes enables the listening sockets again. This is very useful to try to load a new configuration or even a new version of haproxy without breaking existing connections. If the load succeeds, then simply send a SIGUSR1 which will make the previous proxies exit immediately once their sessions are closed ; and if the load fails, then simply send a SIGTTIN to restore the service immediately. Please note that the 'grace' parameter is ignored for SIGTTOU, as well as for SIGUSR1 when the process was in the pause mode. Please also note that it would be useful to save the pidfile before starting a new instance. This mechanism fully exploited since 1.2.11 with the '-st' and '-sf' options (see below). 2.4.1) Hot reconfiguration -------------------------- The '-st' and '-sf' command line options are used to inform previously running processes that a configuration is being reloaded. They will receive the SIGTTOU signal to ask them to temporarily stop listening to the ports so that the new process can grab them. If anything wrong happens, the new process will send them a SIGTTIN to tell them to re-listen to the ports and continue their normal work. Otherwise, it will either ask them to finish (-sf) their work then softly exit, or immediately terminate (-st), breaking existing sessions. A typical use of this allows a configuration reload without service interruption : # haproxy -p /var/run/haproxy.pid -sf $(cat /var/run/haproxy.pid) 2.5) Connections expiration time -------------------------------- It is possible (and recommended) to configure several time-outs on TCP connections. Three independent timers are adjustable with values specified in milliseconds. A session will be terminated if either one of these timers expire. - the time we accept to wait for data from the client, or for the client to accept data : 'clitimeout' : # client time-out set to 2mn30. clitimeout 150000 - the time we accept to wait for data from the server, or for the server to accept data : 'srvtimeout' : # server time-out set to 30s. srvtimeout 30000 - the time we accept to wait for a connection to establish on a server : 'contimeout' : # we give up if the connection does not complete within 4 seconds contimeout 4000 Notes : ------- - 'contimeout' and 'srvtimeout' have no sense on 'health' mode servers ; - under high loads, or with a saturated or defective network, it's possible that some packets get lost. Since the first TCP retransmit only happens after 3 seconds, a time-out equal to, or lower than 3 seconds cannot compensate for a packet loss. A 4 seconds time-out seems a reasonable minimum which will considerably reduce connection failures. - starting with version 1.3.14, it is possible to specify timeouts in arbitrary time units among { us, ms, s, m, h, d }. For this, the integer value just has to be suffixed with the unit. 2.6) Attempts to reconnect -------------------------- After a connection failure to a server, it is possible to retry, potentially on another server. This is useful if health-checks are too rare and you don't want the clients to see the failures. The number of attempts to reconnect is set by the 'retries' paramter. Example : --------- # we can retry 3 times max after a failure retries 3 Please note that the reconnection attempt may lead to getting the connection sent to a new server if the original one died between connection attempts. 2.7) Address of the dispatch server (deprecated) ------------------------------------------------ The server which will be sent all new connections is defined by the 'dispatch' parameter, in the form
:. It generally is dedicated to unknown connections and will assign them a cookie, in case of HTTP persistence mode, or simply is a single server in case of generic TCP proxy. This old mode is only provided for backwards compatibility, but doesn't allow to check remote servers state, and has a rather limited usage. All new setups should switch to 'balance' mode. The principle of the dispatcher is to be able to perform the load balancing itself, but work only on new clients so that the server doesn't need to be a big machine. Example : --------- # all new connections go there dispatch 192.168.1.2:80 Note : ------ This parameter has no sense for 'health' servers, and is incompatible with 'balance' mode. 2.8) Outgoing source address ---------------------------- It is often necessary to bind to a particular address when connecting to some remote hosts. This is done via the 'source' parameter which is a per-proxy parameter. A newer version may allow to fix different sources to reach different servers. The syntax is 'source
[:]', where
is a valid local address (or '0.0.0.0' or '*' or empty to let the system choose), and is an optional parameter allowing the user to force the source port for very specific needs. If the port is not specified or is '0', the system will choose a free port. Note that as of version 1.1.18, the servers health checks are also performed from the same source. Examples : ---------- listen http_proxy *:80 # all connections take 192.168.1.200 as source address source 192.168.1.200:0 listen rlogin_proxy *:513 # use address 192.168.1.200 and the reserved port 900 (needs to be root) source 192.168.1.200:900 2.9) Setting the cookie name ---------------------------- In HTTP mode, it is possible to look for a particular cookie which will contain a server identifier which should handle the connection. The cookie name is set via the 'cookie' parameter. Example : --------- listen http_proxy :80 mode http cookie SERVERID It is possible to change the cookie behaviour to get a smarter persistence, depending on applications. It is notably possible to delete or modify a cookie emitted by a server, insert a cookie identifying the server in an HTTP response and even add a header to tell upstream caches not to cache this response. Examples : ---------- To remove the cookie for direct accesses (ie when the server matches the one which was specified in the client cookie) : cookie SERVERID indirect To replace the cookie value with the one assigned to the server if any (no cookie will be created if the server does not provide one, nor if the configuration does not provide one). This lets the application put the cookie exactly on certain pages (eg: successful authentication) : cookie SERVERID rewrite To create a new cookie and assign the server identifier to it (in this case, all servers should be associated with a valid cookie, since no cookie will simply delete the cookie from the client's browser) : cookie SERVERID insert To reuse an existing application cookie and prefix it with the server's identifier, and remove it in the request, use the 'prefix' option. This allows to insert a haproxy in front of an application without risking to break clients which does not support more than one cookie : cookie JSESSIONID prefix To insert a cookie and ensure that no upstream cache will store it, add the 'nocache' option : cookie SERVERID insert nocache To insert a cookie only after a POST request, add 'postonly' after 'insert'. This has the advantage that there's no risk of caching, and that all pages seen before the POST one can still be cached : cookie SERVERID insert postonly Notes : ----------- - it is possible to combine 'insert' with 'indirect' or 'rewrite' to adapt to applications which already generate the cookie with an invalid content. - in the case where 'insert' and 'indirect' are both specified, the cookie is never transmitted to the server, since it wouldn't understand it. This is the most application-transparent mode. - it is particularly recommended to use 'nocache' in 'insert' mode if any upstream HTTP/1.0 cache is susceptible to cache the result, because this may lead to many clients going to the same server, or even worse, some clients having their server changed while retrieving a page from the cache. - the 'prefix' mode normally does not need 'indirect', 'nocache', nor 'postonly', because just as in the 'rewrite' mode, it relies on the application to know when a cookie can be emitted. However, since it has to fix the cookie name in every subsequent requests, you must ensure that the proxy will be used without any "HTTP keep-alive". Use option "httpclose" if unsure. - when the application is well known and controlled, the best method is to only add the persistence cookie on a POST form because it's up to the application to select which page it wants the upstream servers to cache. In this case, you would use 'insert postonly indirect'. 2.10) Associating a cookie value with a server ---------------------------------------------- In HTTP mode, it's possible to associate a cookie value to each server. This was initially used in combination with 'dispatch' mode to handle direct accesses but it is now the standard way of doing the load balancing. The syntax is : server
: cookie - is any name which can be used to identify the server in the logs. -
: specifies where the server is bound. - is the value to put in or to read from the cookie. Example : the 'SERVERID' cookie can be either 'server01' or 'server02' --------- listen http_proxy :80 mode http cookie SERVERID dispatch 192.168.1.100:80 server web1 192.168.1.1:80 cookie server01 server web2 192.168.1.2:80 cookie server02 Warning : the syntax has changed since version 1.0 ! --------- 2.11) Application Cookies ------------------------- Since 1.2.4 it is possible to catch the cookie that comes from an application server in order to apply "application session stickyness". The server's response is searched for 'appsession' cookie, the first 'len' bytes are used for matching and it is stored for a period of 'timeout'. The syntax is: appsession len timeout - is the cookie, the server uses for it's session-handling - how many bytes/characters should be used for matching equal sessions - after this inactivaty time, in ms, the cookie will be deleted from the sessionstore - starting with version 1.3.14, it is possible to specify timeouts in arbitrary time units among { us, ms, s, m, h, d }. For this, the integer value just has to be prefixed with the unit. The appsession is only per 'listen' section possible. Example : --------- listen http_lb1 192.168.3.4:80 mode http capture request header Cookie len 200 # Havind a ServerID cookie on the client allows him to reach # the right server even after expiration of the appsession. cookie ServerID insert nocache indirect # Will memorize 52 bytes of the cookie 'JSESSIONID' and keep them # for 3 hours. It will match it in the cookie and the URL field. appsession JSESSIONID len 52 timeout 3h server first1 10.3.9.2:10805 check inter 3000 cookie first server secon1 10.3.9.3:10805 check inter 3000 cookie secon server first1 10.3.9.4:10805 check inter 3000 cookie first server secon2 10.3.9.5:10805 check inter 3000 cookie secon option httpchk GET /test.jsp 3) Autonomous load balancer =========================== The proxy can perform the load-balancing itself, both in TCP and in HTTP modes. This is the most interesting mode which obsoletes the old 'dispatch' mode described above. It has advantages such as server health monitoring, multiple port binding and port mapping. To use this mode, the 'balance' keyword is used, followed by the selected algorithm. Up to version 1.2.11, only 'roundrobin' was available, which is also the default value if unspecified. Starting with version 1.2.12, a new 'source' keyword appeared. A new 'uri' keyword was added in version 1.3.10. In this mode, there will be no dispatch address, but the proxy needs at least one server. Example : same as the last one, with internal load balancer --------- listen http_proxy :80 mode http cookie SERVERID balance roundrobin server web1 192.168.1.1:80 cookie server01 server web2 192.168.1.2:80 cookie server02 Since version 1.1.22, it is possible to automatically determine on which port the server will get the connection, depending on the port the client connected to. Indeed, there now are 4 possible combinations for the server's field: - unspecified or '0' : the connection will be sent to the same port as the one on which the proxy received the client connection itself. - numerical value (the only one supported in versions earlier than 1.1.22) : the connection will always be sent to the specified port. - '+' followed by a numerical value : the connection will be sent to the same port as the one on which the proxy received the connection, plus this value. - '-' followed by a numerical value : the connection will be sent to the same port as the one on which the proxy received the connection, minus this value. Examples : ---------- # same as previous example listen http_proxy :80 mode http cookie SERVERID balance roundrobin server web1 192.168.1.1 cookie server01 server web2 192.168.1.2 cookie server02 # simultaneous relaying of ports 80, 81 and 8080-8089 listen http_proxy :80,:81,:8080-8089 mode http cookie SERVERID balance roundrobin server web1 192.168.1.1 cookie server01 server web2 192.168.1.2 cookie server02 # relaying of TCP ports 25, 389 and 663 to ports 1025, 1389 and 1663 listen http_proxy :25,:389,:663 mode tcp balance roundrobin server srv1 192.168.1.1:+1000 server srv2 192.168.1.2:+1000 As previously stated, version 1.2.12 brought the 'source' keyword. When this keyword is used, the client's IP address is hashed and evenly distributed among the available servers so that a same source IP will always go to the same server as long as there are no change in the number of available servers. This can be used for instance to bind HTTP and HTTPS to the same server. It can also be used to improve stickyness when one part of the client population does not accept cookies. In this case, only those ones will be perturbated should a server fail. NOTE: It is important to consider the fact that many clients surf the net through proxy farms which assign different IP addresses for each request. Others use dialup connections with a different IP at each connection. Thus, the 'source' parameter should be used with extreme care. Examples : ---------- # make a same IP go to the same server whatever the service listen http_proxy bind :80,:443 mode http balance source server web1 192.168.1.1 server web2 192.168.1.2 # try to improve client-server binding by using both source IP and cookie : listen http_proxy :80 mode http cookie SERVERID balance source server web1 192.168.1.1 cookie server01 server web2 192.168.1.2 cookie server02 As indicated above, the 'uri' keyword was introduced in version 1.3.10. It is useful when load-balancing between reverse proxy-caches, because it will hash the URI and use the hash result to select a server, thus optimizing the hit rate on the caches, because the same URI will always reach the same cache. This keyword is only allowed in HTTP mode. Example : --------- # Always send a given URI to the same server listen http_proxy bind :3128 mode http balance uri server squid1 192.168.1.1 server squid2 192.168.1.2 Version 1.3.14 introduced the "balance url_param" method. It consists in relying on a parameter passed in the URL to perform a hash. This is mostly useful for applications which do not have strict persistence requirements, but for which it still provides a performance boost due to local caching. Some of these applications may not be able to use a cookie for whatever reason, but may be able to look for a parameter passed in the URL. If the parameter is missing from the URL, then the 'round robin' method applies. A modifier may be added to specify that parameters in POST requests may be found in the messsage body if the URL lacks a '?' separator character. A wait limit may also be applied, if no limit is requested then the default value is 48 octets, the minimum is 3. HAProxy may wait, until 48 octets are received. If Content-Length is missing, or zero it need not wait for more data then the client promissed to send. When Content-Length is present, and more than ; then waiting is limited and it is assumed this will be enough data to search for the presence of a parameter. If Transfer-Encoding: chunked is used (unlikely), then the length of the first chunk is the maximum number of bytes to wait for. balance url_param [check_post []] Caveats for using the check_post extension: - all POST requests are eligable for consideration, because there is no way to determine if the parameters will be found in the body or entity which may contain binary data. Therefore another method may be required to restrict consideration of POST requests that have no URL parameters in the body. (see acl reqideny http_end) Limitations on inspecting the entity body of a POST: - Content-Encoding is not supported, the parameter search will probably fail; and load balancing will fall back to Round Robin. - Expect: 100-continue is not supported, load balancing will fall back to Round Robin. - Transfer-Encoding(RFC2616 3.6.1) is only supported in the first chunk. If the entire parameter value is not present in the first chunk, the selection of server is undefined (actually, defined by how little actually appeared in the first chunk). - This feature does not support generation of a 100, 411 or 501 response. - In some cases, requesting check_post MAY attempt to scan the entire contents of a message body. Scaning normally terminates when linear white space or control characters are found, indicating the end of what might be a URL parameter list. This is probably not a concern with SGML type message bodies. Example : --------- # Hash the "basket_id" argument from the URL to determine the server listen http_proxy bind :3128 mode http balance url_param basket_id server ebiz1 192.168.1.1 server ebiz2 192.168.1.2 3.1) Server monitoring ---------------------- It is possible to check the servers status by trying to establish TCP connections or even sending HTTP requests to them. A server which fails to reply to health checks as expected will not be used by the load balancing algorithms. To enable monitoring, add the 'check' keyword on a server line. It is possible to specify the interval between tests (in milliseconds) with the 'inter' parameter, the number of failures supported before declaring that the server has fallen down with the 'fall' parameter, and the number of valid checks needed for the server to fully get up with the 'rise' parameter. Since version 1.1.22, it is also possible to send checks to a different port (mandatory when none is specified) with the 'port' parameter. The default values are the following ones : - inter : 2000 - rise : 2 - fall : 3 - port : default server port - addr : specific address for the test (default = address server) The default mode consists in establishing TCP connections only. But in certain types of application failures, it is often that the server continues to accept connections because the system does it itself while the application is running an endless loop, or is completely stuck. So in version 1.1.16 were introduced HTTP health checks which only performed simple lightweight requests and analysed the response. Now, as of version 1.1.23, it is possible to change the HTTP method, the URI, and the HTTP version string (which even allows to send headers with a dirty trick). To enable HTTP health-checks, use 'option httpchk'. By default, requests use the 'OPTIONS' method because it's very light and easy to filter from logs, and does it on '/'. Only HTTP responses 2xx and 3xx are considered valid ones, and only if they come before the time to send a new request is reached ('inter' parameter). If some servers block this type of request, 3 other forms help to forge a request : - option httpchk -> OPTIONS / HTTP/1.0 - option httpchk URI -> OPTIONS HTTP/1.0 - option httpchk METH URI -> HTTP/1.0 - option httpchk METH URI VER -> Some people are using HAProxy to relay various TCP-based protocols such as HTTPS, SMTP or LDAP, with the most common one being HTTPS. One problem commonly encountered in data centers is the need to forward the traffic to far remote servers while providing server fail-over. Often, TCP-only checks are not enough because intermediate firewalls, load balancers or proxies might acknowledge the connection before it reaches the real server. The only solution to this problem is to send application-level health checks. Since the demand for HTTPS checks is high, it has been implemented in 1.2.15 based on SSLv3 Client Hello packets. To enable it, use 'option ssl-hello-chk'. It will send SSL CLIENT HELLO packets to the servers, announcing support for most common cipher suites. If the server responds what looks like a SERVER HELLO or an ALERT (refuses the ciphers) then the response is considered as valid. Note that Apache does not generate a log when it receives only an HELLO message, which makes this type of message perfectly suit this need. Version 1.3.10 introduced the SMTP health check. By default, it sends "HELO localhost" to the servers, and waits for the 250 message. Note that it can also send a specific request : - option smtpchk -> sends "HELO localhost" - option smtpchk EHLO mail.mydomain.com -> sends this ESMTP greeting See examples below. Since version 1.1.17, it is possible to specify backup servers. These servers are only sollicited when no other server is available. This may only be useful to serve a maintenance page, or define one active and one backup server (seldom used in TCP mode). To make a server a backup one, simply add the 'backup' option on its line. These servers also support cookies, so if a cookie is specified for a backup server, clients assigned to this server will stick to it even when the other ones come back. Conversely, if no cookie is assigned to such a server, the clients will get their cookies removed (empty cookie = removal), and will be balanced against other servers once they come back. Please note that there is no load-balancing among backup servers by default. If there are several backup servers, the second one will only be used when the first one dies, and so on. To force load-balancing between backup servers, specify the 'allbackups' option. Since version 1.1.22, it is possible to send health checks to a different port than the service. It is mainly needed in setups where the server does not have any predefined port, for instance when the port is deduced from the listening port. For this, use the 'port' parameter followed by the port number which must respond to health checks. It is also possible to send health checks to a different address than the service. It makes it easier to use a dedicated check daemon on the servers, for instance, check return contents and stop several farms at once in the event of an error anywhere. Since version 1.1.17, it is also possible to visually check the status of all servers at once. For this, you just have to send a SIGHUP signal to the proxy. The servers status will be dumped into the logs at the 'notice' level, as well as on if not closed. For this reason, it's always a good idea to have one local log server at the 'notice' level. Since version 1.1.28 and 1.2.1, if an instance loses all its servers, an emergency message will be sent in the logs to inform the administator that an immediate action must be taken. Since version 1.1.30 and 1.2.3, several servers can share the same cookie value. This is particularly useful in backup mode, to select alternate paths for a given server for example, to provide soft-stop, or to direct the clients to a temporary page during an application restart. The principle is that when a server is dead, the proxy will first look for another server which shares the same cookie value for every client which presents the cookie. If there is no standard server for this cookie, it will then look for a backup server which shares the same name. Please consult the architecture guide for more information. Examples : ---------- # same setup as in paragraph 3) with TCP monitoring listen http_proxy 0.0.0.0:80 mode http cookie SERVERID balance roundrobin server web1 192.168.1.1:80 cookie server01 check server web2 192.168.1.2:80 cookie server02 check inter 500 rise 1 fall 2 # same with HTTP monitoring via 'OPTIONS / HTTP/1.0' listen http_proxy 0.0.0.0:80 mode http cookie SERVERID balance roundrobin option httpchk server web1 192.168.1.1:80 cookie server01 check server web2 192.168.1.2:80 cookie server02 check inter 500 rise 1 fall 2 # same with HTTP monitoring via 'OPTIONS /index.html HTTP/1.0' listen http_proxy 0.0.0.0:80 mode http cookie SERVERID balance roundrobin option httpchk /index.html server web1 192.168.1.1:80 cookie server01 check server web2 192.168.1.2:80 cookie server02 check inter 500 rise 1 fall 2 # same with HTTP monitoring via 'HEAD /index.jsp? HTTP/1.1\r\nHost: www' listen http_proxy 0.0.0.0:80 mode http cookie SERVERID balance roundrobin option httpchk HEAD /index.jsp? HTTP/1.1\r\nHost:\ www server web1 192.168.1.1:80 cookie server01 check server web2 192.168.1.2:80 cookie server02 check inter 500 rise 1 fall 2 # Load-balancing with 'prefixed cookie' persistence, and soft-stop using an # alternate port 81 on the server for health-checks. listen http_proxy 0.0.0.0:80 mode http cookie JSESSIONID prefix balance roundrobin option httpchk HEAD /index.jsp? HTTP/1.1\r\nHost:\ www server web1-norm 192.168.1.1:80 cookie s1 check port 81 server web2-norm 192.168.1.2:80 cookie s2 check port 81 server web1-stop 192.168.1.1:80 cookie s1 check port 80 backup server web2-stop 192.168.1.2:80 cookie s2 check port 80 backup # automatic insertion of a cookie in the server's response, and automatic # deletion of the cookie in the client request, while asking upstream caches # not to cache replies. listen web_appl 0.0.0.0:80 mode http cookie SERVERID insert nocache indirect balance roundrobin server web1 192.168.1.1:80 cookie server01 check server web2 192.168.1.2:80 cookie server02 check # same with off-site application backup and local error pages server listen web_appl 0.0.0.0:80 mode http cookie SERVERID insert nocache indirect balance roundrobin server web1 192.168.1.1:80 cookie server01 check server web2 192.168.1.2:80 cookie server02 check server web-backup 192.168.2.1:80 cookie server03 check backup server web-excuse 192.168.3.1:80 check backup # SMTP+TLS relaying with health-checks and backup servers listen http_proxy :25,:587 mode tcp balance roundrobin server srv1 192.168.1.1 check port 25 inter 30000 rise 1 fall 2 server srv2 192.168.1.2 backup # HTTPS relaying with health-checks and backup servers listen http_proxy :443 mode tcp option ssl-hello-chk balance roundrobin server srv1 192.168.1.1 check inter 30000 rise 1 fall 2 server srv2 192.168.1.2 backup # Load-balancing using a backup pool (requires haproxy 1.2.9) listen http_proxy 0.0.0.0:80 mode http balance roundrobin option httpchk server inst1 192.168.1.1:80 cookie s1 check server inst2 192.168.1.2:80 cookie s2 check server inst3 192.168.1.3:80 cookie s3 check server back1 192.168.1.10:80 check backup server back2 192.168.1.11:80 check backup option allbackups # all backups will be used 3.2) Redistribute connections in case of failure ------------------------------------------------ In HTTP mode, if a server designated by a cookie does not respond, the clients may definitely stick to it because they cannot flush the cookie, so they will not be able to access the service anymore. Specifying 'redispatch' will allow the proxy to break their persistence and redistribute them to working servers. Example : --------- listen http_proxy 0.0.0.0:80 mode http cookie SERVERID dispatch 192.168.1.100:80 server web1 192.168.1.1:80 cookie server01 server web2 192.168.1.2:80 cookie server02 redispatch # send back to dispatch in case of connection failure Up to, and including version 1.1.16, this parameter only applied to connection failures. Since version 1.1.17, it also applies to servers which have been detected as failed by the health check mechanism. Indeed, a server may be broken but still accepting connections, which would not solve every case. But it is possible to conserve the old behaviour, that is, make a client insist on trying to connect to a server even if it is said to be down, by setting the 'persist' option : listen http_proxy 0.0.0.0:80 mode http option persist cookie SERVERID dispatch 192.168.1.100:80 server web1 192.168.1.1:80 cookie server01 server web2 192.168.1.2:80 cookie server02 redispatch # send back to dispatch in case of connection failure 3.3) Assigning different weights to servers ------------------------------------------- Sometimes you will need to bring new servers to increase your server farm's capacity, but the new server will be either smaller (emergency use of anything that fits) or bigger (when investing in new hardware). For this reason, it might be wise to be able to send more clients to biggest servers. Till version 1.2.11, it was necessary to replicate the same server multiple times in the configuration. Starting with 1.2.12, the 'weight' option is available. HAProxy then computes the most homogenous possible map of servers based on their weights so that the load gets distributed as smoothly as possible among them. The weight, between 1 and 256, should reflect one server's capacity relative to others. Weight 1 represents the lowest frequency and 256 the highest. This way, if a server fails, the remaining capacities are still respected. Example : --------- # fair distribution among two opterons and one old pentium3 listen web_appl 0.0.0.0:80 mode http cookie SERVERID insert nocache indirect balance roundrobin server pentium3-800 192.168.1.1:80 cookie server01 weight 8 check server opteron-2.0G 192.168.1.2:80 cookie server02 weight 20 check server opteron-2.4G 192.168.1.3:80 cookie server03 weight 24 check server web-backup1 192.168.2.1:80 cookie server04 check backup server web-excuse 192.168.3.1:80 check backup Notes : ------- - if unspecified, the default weight is 1 - the weight does not impact health checks, so it is cleaner to use weights than replicating the same server several times - weights also work on backup servers if the 'allbackups' option is used - the weights also apply to the source address load balancing ('balance source'). - whatever the weights, the first server will always be assigned first. This is helpful for troubleshooting. - for the purists, the map calculation algorithm gives precedence to first server, so the map is the most uniform when servers are declared in ascending order relative to their weights. The load distribution will follow exactly this sequence : Request| 1 1 1 1 number | 1 2 3 4 5 6 7 8 9 0 1 2 3 --------+--------------------------- p3-800 | X . . . . . . X . . . . . opt-20 | . X . X . X . . . X . X . opt-24 | . . X . X . X . X . X . X 3.4) Limiting the number of concurrent sessions on each server -------------------------------------------------------------- Some pre-forked servers such as Apache suffer from too many concurrent sessions, because it's very expensive to run hundreds or thousands of processes on one system. One solution is to increase the number of servers and load-balance between them, but it is a problem when the only goal is to resist to short surges. To solve this problem, a new feature was implemented in HAProxy 1.2.13. It's a per-server 'maxconn', associated with a per-server and a per-proxy queue. This transforms haproxy into a request buffer between the thousands of clients and the few servers. On many circumstances, lowering the maxconn value will increase the server's performance and decrease the overall response times because the servers will be less congested. When a request tries to reach any server, the first non-saturated server is used, respective to the load balancing algorithm. If all servers are saturated, then the request gets queued into the instance's global queue. It will be dequeued once a server will have freed a session and all previously queued requests have been processed. If a request references a particular server (eg: source hashing, or persistence cookie), and if this server is full, then the request will be queued into the server's dedicated queue. This queue has higher priority than the global queue, so it's easier for already registered users to enter the site than for new users. For this, the logs have been enhanced to show the number of sessions per server, the request's position in the queue and the time spent in the queue. This helps doing capacity planning. See the 'logs' section below for more info. Example : --------- # be nice with P3 which only has 256 MB of RAM. listen web_appl 0.0.0.0:80 maxconn 10000 mode http cookie SERVERID insert nocache indirect balance roundrobin server pentium3-800 192.168.1.1:80 cookie s1 weight 8 maxconn 100 check server opteron-2.0G 192.168.1.2:80 cookie s2 weight 20 maxconn 300 check server opteron-2.4G 192.168.1.3:80 cookie s3 weight 24 maxconn 300 check server web-backup1 192.168.2.1:80 cookie s4 check maxconn 200 backup server web-excuse 192.168.3.1:80 check backup This was so much efficient at reducing the server's response time that some users wanted to use low values to improve their server's performance. However, they were not able anymore to handle very large loads because it was not possible anymore to saturate the servers. For this reason, version 1.2.14 has brought dynamic limitation with the addition of the parameter 'minconn'. When this parameter is set along with maxconn, it will enable dynamic limitation based on the instance's load. The maximum number of concurrent sessions on a server will be proportionnal to the number of sessions on the instance relative to its maxconn. A minimum of will be allowed whatever the load. This will ensure that servers will perform at their best level under normal loads, while still handling surges when needed. The dynamic limit is computed like this : srv.dyn_limit = max(srv.minconn, srv.maxconn * inst.sess / inst.maxconn) Example : --------- # be nice with P3 which only has 256 MB of RAM. listen web_appl 0.0.0.0:80 maxconn 10000 mode http cookie SERVERID insert nocache indirect balance roundrobin server pentium3-800 192.168.1.1:80 cookie s1 weight 8 minconn 10 maxconn 100 check server opteron-2.0G 192.168.1.2:80 cookie s2 weight 20 minconn 30 maxconn 300 check server opteron-2.4G 192.168.1.3:80 cookie s3 weight 24 minconn 30 maxconn 300 check server web-backup1 192.168.2.1:80 cookie s4 check maxconn 200 backup server web-excuse 192.168.3.1:80 check backup In the example above, the server 'pentium3-800' will receive at most 100 simultaneous sessions when the proxy instance will reach 10000 sessions, and will receive only 10 simultaneous sessions when the proxy will be under 1000 sessions. It is possible to limit server queue length in order to rebalance excess sessions between less busy application servers IF session affinity isn't hard functional requirement (for example it just gives huge performance boost by keeping server-local caches hot and compact). 'maxqueue' option sets a queue limit on a server, as in example below: ... (just the same as in example above) server pentium3-800 192.168.1.1:80 cookie s1 weight 8 minconn 10 maxconn 100 check maxqueue 50 server opteron-2.0G 192.168.1.2:80 cookie s2 weight 20 minconn 30 maxconn 300 check maxqueue 200 server opteron-2.4G 192.168.1.3:80 cookie s3 weight 24 minconn 30 maxconn 300 check Absence of 'maxqueue' option means unlimited queue. When queue gets filled up to 'maxqueue' client session is moved from server-local queue to a global one. Notes : ------- - The requests will not stay indefinitely in the queue, they follow the 'contimeout' parameter, and if a request cannot be dequeued within this timeout because the server is saturated or because the queue is filled, the session will expire with a 503 error. - if only is specified, it has the same effect as - setting too low values for maxconn might improve performance but might also allow slow users to block access to the server for other users. 3.5) Dropping aborted requests ------------------------------ In presence of very high loads, the servers will take some time to respond. The per-proxy's connection queue will inflate, and the response time will increase respective to the size of the queue times the average per-session response time. When clients will wait for more than a few seconds, they will often hit the 'STOP' button on their browser, leaving a useless request in the queue, and slowing down other users. As there is no way to distinguish between a full STOP and a simple shutdown(SHUT_WR) on the client side, HTTP agents should be conservative and consider that the client might only have closed its output channel while waiting for the response. However, this introduces risks of congestion when lots of users do the same, and is completely useless nowadays because probably no client at all will close the session while waiting for the response. Some HTTP agents support this (Squid, Apache, HAProxy), and others do not (TUX, most hardware-based load balancers). So the probability for a closed input channel to represent a user hitting the 'STOP' button is close to 100%, and it is very tempting to be able to abort the session early without polluting the servers. For this reason, a new option "abortonclose" was introduced in version 1.2.14. By default (without the option) the behaviour is HTTP-compliant. But when the option is specified, a session with an incoming channel closed will be aborted if it's still possible, which means that it's either waiting for a connect() to establish or it is queued waiting for a connection slot. This considerably reduces the queue size and the load on saturated servers when users are tempted to click on STOP, which in turn reduces the response time for other users. Example : --------- listen web_appl 0.0.0.0:80 maxconn 10000 mode http cookie SERVERID insert nocache indirect balance roundrobin server web1 192.168.1.1:80 cookie s1 weight 10 maxconn 100 check server web2 192.168.1.2:80 cookie s2 weight 10 maxconn 100 check server web3 192.168.1.3:80 cookie s3 weight 10 maxconn 100 check server bck1 192.168.2.1:80 cookie s4 check maxconn 200 backup option abortonclose 4) Additionnal features ======================= Other features are available. They are transparent mode, event logging, header rewriting/filtering, and the status as an HTML page. 4.1) Network features --------------------- 4.1.1) Transparent mode ----------------------- In HTTP mode, the 'transparent' keyword allows to intercept sessions which are routed through the system hosting the proxy. This mode was implemented as a replacement for the 'dispatch' mode, since connections without cookie will be sent to the original address while known cookies will be sent to the servers. This mode implies that the system can redirect sessions to a local port. Example : --------- listen http_proxy 0.0.0.0:65000 mode http transparent cookie SERVERID server server01 192.168.1.1:80 server server02 192.168.1.2:80 # iptables -t nat -A PREROUTING -i eth0 -p tcp -d 192.168.1.100 \ --dport 80 -j REDIRECT --to-ports 65000 Note : ------ If the port is left unspecified on the server, the port the client connected to will be used. This allows to relay a full port range without using transparent mode nor thousands of file descriptors, provided that the system can redirect sessions to local ports. Example : --------- # redirect all ports to local port 65000, then forward to the server on the # original port. listen http_proxy 0.0.0.0:65000 mode tcp server server01 192.168.1.1 check port 60000 server server02 192.168.1.2 check port 60000 # iptables -t nat -A PREROUTING -i eth0 -p tcp -d 192.168.1.100 \ -j REDIRECT --to-ports 65000 4.1.2) Per-server source address binding ---------------------------------------- As of versions 1.1.30 and 1.2.3, it is possible to specify a particular source to reach each server. This is useful when reaching backup servers from a different LAN, or to use an alternate path to reach the same server. It is also usable to provide source load-balancing for outgoing connections. Obviously, the same source address is used to send health-checks. Example : --------- # use a particular source to reach both servers listen http_proxy 0.0.0.0:65000 mode http balance roundrobin server server01 192.168.1.1:80 source 192.168.2.13 server server02 192.168.1.2:80 source 192.168.2.13 Example : --------- # use a particular source to reach each servers listen http_proxy 0.0.0.0:65000 mode http balance roundrobin server server01 192.168.1.1:80 source 192.168.1.1 server server02 192.168.2.1:80 source 192.168.2.1 Example : --------- # provide source load-balancing to reach the same proxy through 2 WAN links listen http_proxy 0.0.0.0:65000 mode http balance roundrobin server remote-proxy-way1 192.168.1.1:3128 source 192.168.2.1 server remote-proxy-way2 192.168.1.1:3128 source 192.168.3.1 Example : --------- # force a TCP connection to bind to a specific port listen http_proxy 0.0.0.0:2000 mode tcp balance roundrobin server srv1 192.168.1.1:80 source 192.168.2.1:20 server srv2 192.168.1.2:80 source 192.168.2.1:20 4.1.3) TCP keep-alive --------------------- With version 1.2.7, it becomes possible to enable TCP keep-alives on both the client and server sides. This makes it possible to prevent long sessions from expiring on external layer 4 components such as firewalls and load-balancers. It also allows the system to terminate dead sessions when no timeout has been set (not recommanded). The proxy cannot set the keep-alive probes intervals nor maximal count, consult your operating system manual for this. There are 3 options to enable TCP keep-alive : option tcpka # enables keep-alive both on client and server side option clitcpka # enables keep-alive only on client side option srvtcpka # enables keep-alive only on server side 4.1.4) TCP lingering -------------------- It is possible to disable the system's lingering of data unacked by the client at the end of a session. This is sometimes required when haproxy is used as a front-end with lots of unreliable clients, and you observe thousands of sockets in the FIN_WAIT state on the machine. This may be used in a frontend to affect the client-side connection, as well as in a backend for the server-side connection : option nolinger # disables data lingering 4.2) Event logging ------------------ HAProxy's strength certainly lies in its precise logs. It probably provides the finest level of information available for such a product, which is very important for troubleshooting complex environments. Standard log information include client ports, TCP/HTTP state timers, precise session state at termination and precise termination cause, information about decisions to direct trafic to a server, and of course the ability to capture arbitrary headers. In order to improve administrators reactivity, it offers a great transparency about encountered problems, both internal and external, and it is possible to send logs to different sources at the same time with different level filters : - global process-level logs (system errors, start/stop, etc..) - per-listener system and internal errors (lack of resource, bugs, ...) - per-listener external troubles (servers up/down, max connections) - per-listener activity (client connections), either at the establishment or at the termination. The ability to distribute different levels of logs to different log servers allow several production teams to interact and to fix their problems as soon as possible. For example, the system team might monitor system-wide errors, while the application team might be monitoring the up/down for their servers in real time, and the security team might analyze the activity logs with one hour delay. 4.2.1) Log levels ----------------- TCP and HTTP connections can be logged with informations such as date, time, source IP address, destination address, connection duration, response times, HTTP request, the HTTP return code, number of bytes transmitted, the conditions in which the session ended, and even exchanged cookies values, to track a particular user's problems for example. All messages are sent to up to two syslog servers. Consult section 1.1 for more info about log facilities. The syntax follows : log [max_level_1] log [max_level_2] or log global Note : ------ The particular syntax 'log global' means that the same log configuration as the 'global' section will be used. Example : --------- listen http_proxy 0.0.0.0:80 mode http log 192.168.2.200 local3 log 192.168.2.201 local4 4.2.2) Log format ----------------- By default, connections are logged at the TCP level, as soon as the session establishes between the client and the proxy. By enabling the 'tcplog' option, the proxy will wait until the session ends to generate an enhanced log containing more information such as session duration and its state during the disconnection. The number of remaining session after disconnection is also indicated (for the server, the listener, and the process). Example of TCP logging : ------------------------ listen relais-tcp 0.0.0.0:8000 mode tcp option tcplog log 192.168.2.200 local3 >>> haproxy[18989]: 127.0.0.1:34550 [15/Oct/2003:15:24:28] relais-tcp Srv1 0/0/5007 0 -- 1/1/1 0/0 Field Format Example 1 process_name '[' pid ']:' haproxy[18989]: 2 client_ip ':' client_port 127.0.0.1:34550 3 '[' date ']' [15/Oct/2003:15:24:28] 4 listener_name relais-tcp 5 server_name Srv1 6 queue_time '/' connect_time '/' total_time 0/0/5007 7 bytes_read 0 8 termination_state -- 9 srv_conn '/' listener_conn '/' process_conn 1/1/1 10 position in srv_queue / listener_queue 0/0 Another option, 'httplog', provides more detailed information about HTTP contents, such as the request and some cookies. In the event where an external component would establish frequent connections to check the service, logs may be full of useless lines. So it is possible not to log any session which didn't transfer any data, by the setting of the 'dontlognull' option. This only has effect on sessions which are established then closed. Example of HTTP logging : ------------------------- listen http_proxy 0.0.0.0:80 mode http option httplog option dontlognull log 192.168.2.200 local3 >>> haproxy[674]: 127.0.0.1:33319 [15/Oct/2003:08:31:57] relais-http Srv1 9/0/7/147/723 200 243 - - ---- 34/34/15/8/3 0/0 "HEAD / HTTP/1.0" More complete example haproxy[18989]: 10.0.0.1:34552 [15/Oct/2003:15:26:31] relais-http Srv1 3183/-1/-1/-1/11215 503 0 - - SC-- 205/202/150/137/+4 0/0 {w.ods.org|Mozilla} {} "HEAD / HTTP/1.0" Field Format Example 1 process_name '[' pid ']:' haproxy[18989]: 2 client_ip ':' client_port 10.0.0.1:34552 3 '[' date ']' [15/Oct/2003:15:26:31] 4 listener_name relais-http 5 server_name Srv1 6 Tq '/' Tw '/' Tc '/' Tr '/' Tt 3183/-1/-1/-1/11215 7 HTTP_return_code 503 8 bytes_read 0 9 captured_request_cookie - 10 captured_response_cookie - 11 termination_state SC-- 12 actconn '/' feconn '/' beconn '/' srv_conn '/' retries 205/202/150/137/+4 13 position in srv_queue / listener_queue 0/0 14 '{' captured_request_headers '}' {w.ods.org|Mozilla} 15 '{' captured_response_headers '}' {} 16 '"' HTTP_request '"' "HEAD / HTTP/1.0" Note for log parsers: the URI is ALWAYS the end of the line starting with the first double quote '"'. The retries count may have additional '+' sign means that the connection had been redispatched from one server to another shortly before retries limit (retries 4 in above example) was depleted. The problem when logging at end of connection is that you have no clue about what is happening during very long sessions. To workaround this problem, a new option 'logasap' has been introduced in 1.1.28/1.2.1. When specified, the proxy will log as soon as possible, just before data transfer begins. This means that in case of TCP, it will still log the connection status to the server, and in case of HTTP, it will log just after processing the server headers. In this case, the number of bytes reported is the number of header bytes sent to the client. In order to avoid confusion with normal logs, the total time field and the number of bytes are prefixed with a '+' sign which means that real numbers are certainly bigger. Example : --------- listen http_proxy 0.0.0.0:80 mode http option httplog option dontlognull option logasap log 192.168.2.200 local3 >>> haproxy[674]: 127.0.0.1:33320 [15/Oct/2003:08:32:17] relais-http Srv1 9/10/7/14/+30 200 +243 - - ---- 3/1/1/1/0 1/0 "GET /image.iso HTTP/1.0" 4.2.3) Timing events -------------------- Timers provide a great help in trouble shooting network problems. All values are reported in milliseconds (ms). In HTTP mode, four control points are reported under the form 'Tq/Tw/Tc/Tr/Tt' : - Tq: total time to get the client request. It's the time elapsed between the moment the client connection was accepted and the moment the proxy received the last HTTP header. The value '-1' indicates that the end of headers (empty line) has never been seen. - Tw: total time spent in the queues waiting for a connection slot. It accounts for listener's queue as well as the server's queue, and depends on the queue size, and the time needed for the server to complete previous sessions. The value '-1' means that the request was killed before reaching the queue. - Tc: total time to establish the TCP connection to the server. It's the time elapsed between the moment the proxy sent the connection request, and the moment it was acknowledged, or between the TCP SYN packet and the matching SYN/ACK in return. The value '-1' means that the connection never established. - Tr: server response time. It's the time elapsed between the moment the TCP connection was established to the server and the moment it send its complete response header. It purely shows its request processing time, without the network overhead due to the data transmission. The value '-1' means that the last the response header (empty line) was never seen. - Tt: total session duration time, between the moment the proxy accepted it and the moment both ends were closed. The exception is when the 'logasap' option is specified. In this case, it only equals (Tq+Tw+Tc+Tr), and is prefixed with a '+' sign. From this field, we can deduce Td, the data transmission time, by substracting other timers when valid : Td = Tt - (Tq + Tw + Tc + Tr) Timers with '-1' values have to be excluded from this equation. In TCP mode ('option tcplog'), only Tw, Tc and Tt are reported. These timers provide precious indications on trouble causes. Since the TCP protocol defines retransmit delays of 3, 6, 12... seconds, we know for sure that timers close to multiples of 3s are nearly always related to packets lost due to network problems (wires or negociation). Moreover, if is close to a timeout value specified in the configuration, it often means that a session has been aborted on time-out. Most common cases : - If Tq is close to 3000, a packet has probably been lost between the client and the proxy. - If Tc is close to 3000, a packet has probably been lost between the server and the proxy during the server connection phase. This one should always be very low (less than a few tens). - If Tr is nearly always lower than 3000 except some rare values which seem to be the average majored by 3000, there are probably some packets lost between the proxy and the server. - If Tt is often slightly higher than a time-out, it's often because the client and the server use HTTP keep-alive and the session is maintained after the response ends. Se further for how to disable HTTP keep-alive. Other cases ('xx' means any value to be ignored) : -1/xx/xx/xx/Tt: the client was not able to send its complete request in time, or that it aborted it too early. Tq/-1/xx/xx/Tt: it was not possible to process the request, maybe because servers were out of order. Tq/Tw/-1/xx/Tt: the connection could not establish on the server. Either it refused it or it timed out after Tt-(Tq+Tw) ms. Tq/Tw/Tc/-1/Tt: the server has accepted the connection but did not return a complete response in time, or it closed its connexion unexpectedly, after Tt-(Tq+Tw+Tc) ms. 4.2.4) Session state at disconnection ------------------------------------- TCP and HTTP logs provide a session completion indicator in the field, just before the number of active connections. It is 2-characters long in TCP, and 4-characters long in HTTP, each of which has a special meaning : - On the first character, a code reporting the first event which caused the session to terminate : C : the TCP session was unexpectedly aborted by the client. S : the TCP session was unexpectedly aborted by the server, or the server explicitly refused it. P : the session was prematurely aborted by the proxy, because of a connection limit enforcement, because a DENY filter was matched, or because of a security check which detected and blocked a dangerous error in server response which might have caused information leak (eg: cacheable cookie). R : a resource on the proxy has been exhausted (memory, sockets, source ports, ...). Usually, this appears during the connection phase, and system logs should contain a copy of the precise error. I : an internal error was identified by the proxy during a self-check. This should NEVER happen, and you are encouraged to report any log containing this, because this is a bug. c : the client-side time-out expired first. s : the server-side time-out expired first. - : normal session completion. - on the second character, the TCP/HTTP session state when it was closed : R : waiting for complete REQUEST from the client (HTTP only). Nothing was sent to any server. Q : waiting in the QUEUE for a connection slot. This can only happen on servers which have a 'maxconn' parameter set. No connection attempt was made to any server. C : waiting for CONNECTION to establish on the server. The server might at most have noticed a connection attempt. H : waiting for, receiving and processing server HEADERS (HTTP only). D : the session was in the DATA phase. L : the proxy was still transmitting LAST data to the client while the server had already finished. T : the request was tarpitted. It has been held open on with the client during the whole contimeout duration or untill the client closed. - : normal session completion after end of data transfer. - the third character tells whether the persistence cookie was provided by the client (only in HTTP mode) : N : the client provided NO cookie. This is usually the case on new connections. I : the client provided an INVALID cookie matching no known server. This might be caused by a recent configuration change, mixed cookies between HTTP/HTTPS sites, or an attack. D : the client provided a cookie designating a server which was DOWN, so either the 'persist' option was used and the client was sent to this server, or it was not set and the client was redispatched to another server. V : the client provided a valid cookie, and was sent to the associated server. - : does not apply (no cookie set in configuration). - the last character reports what operations were performed on the persistence cookie returned by the server (only in HTTP mode) : N : NO cookie was provided by the server, and none was inserted either. I : no cookie was provided by the server, and the proxy INSERTED one. P : a cookie was PROVIDED by the server and transmitted as-is. R : the cookie provided by the server was REWRITTEN by the proxy. D : the cookie provided by the server was DELETED by the proxy. - : does not apply (no cookie set in configuration). The combination of the two first flags give a lot of information about what was happening when the session terminated. It can be helpful to detect server saturation, network troubles, local system resource starvation, attacks, etc... The most common termination flags combinations are indicated here. Flags Reason CR The client aborted before sending a full request. Most probably the request was done by hand using a telnet client, and aborted early. cR The client timed out before sending a full request. This is sometimes caused by too large TCP MSS values on the client side for PPPoE networks which cannot transport full-sized packets, or by clients sending requests by hand and not typing fast enough. SC The server explicitly refused the connection (the proxy received a TCP RST or an ICMP in return). Under some circumstances, it can also be the network stack telling the proxy that the server is unreachable (eg: no route, or no ARP response on local network). sC The connection to the server did not complete during contimeout. PC The proxy refused to establish a connection to the server because the maxconn limit has been reached. The listener's maxconn parameter may be increased in the proxy configuration, as well as the global maxconn parameter. RC A local resource has been exhausted (memory, sockets, source ports) preventing the connection to the server from establishing. The error logs will tell precisely what was missing. Anyway, this can only be solved by system tuning. cH The client timed out during a POST request. This is sometimes caused by too large TCP MSS values for PPPoE networks which cannot transport full-sized packets. CH The client aborted while waiting for the server to start responding. It might be the server taking too long to respond or the client clicking the 'Stop' button too fast. CQ The client aborted while its session was queued, waiting for a server with enough empty slots to accept it. It might be that either all the servers were saturated or the assigned server taking too long to respond. CT The client aborted while its session was tarpitted. sQ The session spent too much time in queue and has been expired. SH The server aborted before sending its full headers, or it crashed. sH The server failed to reply during the srvtimeout delay, which indicates too long transactions, probably caused by back-end saturation. The only solutions are to fix the problem on the application or to increase the 'srvtimeout' parameter to support longer delays (at the risk of the client giving up anyway). PR The proxy blocked the client's request, either because of an invalid HTTP syntax, in which case it returned an HTTP 400 error to the client, or because a deny filter matched, in which case it returned an HTTP 403 error. PH The proxy blocked the server's response, because it was invalid, incomplete, dangerous (cache control), or matched a security filter. In any case, an HTTP 502 error is sent to the client. PT The proxy blocked the client's request and has tarpitted its connection before returning it a 500 server error. Nothing was sent to the server. cD The client did not read any data for as long as the clitimeout delay. This is often caused by network failures on the client side. CD The client unexpectedly aborted during data transfer. This is either caused by a browser crash, or by a keep-alive session between the server and the client terminated first by the client. sD The server did nothing during the srvtimeout delay. This is often caused by too short timeouts on L4 equipements before the server (firewalls, load-balancers, ...). 4.2.5) Non-printable characters ------------------------------- As of version 1.1.29, non-printable characters are not sent as-is into log files, but are converted to their two-digits hexadecimal representation, prefixed by the character '#'. The only characters that can now be logged without being escaped are between 32 and 126 (inclusive). Obviously, the escape character '#' is also encoded to avoid any ambiguity. It is the same for the character '"', as well as '{', '|' and '}' when logging headers. 4.2.6) Capturing HTTP headers and cookies ----------------------------------------- Version 1.1.23 brought cookie capture, and 1.1.29 the header capture. All this is performed using the 'capture' keyword. Cookie capture makes it easy to track a complete user session. The syntax is : capture cookie len This will enable cookie capture from both requests and responses. This way, it's easy to detect when a user switches to a new session for example, because the server will reassign it a new cookie. The FIRST cookie whose name starts with will be captured, and logged as 'NAME=value', without exceeding characters (64 max). When the cookie name is fixed and known, it's preferable to suffix '=' to it to ensure that no other cookie will be logged. Examples : ---------- # capture the first cookie whose name starts with "ASPSESSION" capture cookie ASPSESSION len 32 # capture the first cookie whose name is exactly "vgnvisitor" capture cookie vgnvisitor= len 32 In the logs, the field preceeding the completion indicator contains the cookie value as sent by the server, preceeded by the cookie value as sent by the client. Each of these field is replaced with '-' when no cookie was seen or when the option is disabled. Header captures have a different goal. They are useful to track unique request identifiers set by a previous proxy, virtual host names, user-agents, POST content-length, referrers, etc. In the response, one can search for information about the response length, how the server asked the cache to behave, or an object location during a redirection. As for cookie captures, it is both possible to include request headers and response headers at the same time. The syntax is : capture request header len capture response header len Note: Header names are not case-sensitive. Examples: --------- # keep the name of the virtual server capture request header Host len 20 # keep the amount of data uploaded during a POST capture request header Content-Length len 10 # note the expected cache behaviour on the response capture response header Cache-Control len 8 # note the URL location during a redirection capture response header Location len 20 Non-existant headers are logged as empty strings, and if one header appears more than once, only its last occurence will be kept. Request headers are grouped within braces '{' and '}' in the same order as they were declared, and delimited with a vertical bar '|' without any space. Response headers follow the same representation, but are displayed after a space following the request headers block. These blocks are displayed just before the HTTP request in the logs. Example : Config: capture request header Host len 20 capture request header Content-Length len 10 capture request header Referer len 20 capture response header Server len 20 capture response header Content-Length len 10 capture response header Cache-Control len 8 capture response header Via len 20 capture response header Location len 20 Log : Aug 9 20:26:09 localhost haproxy[2022]: 127.0.0.1:34014 [09/Aug/2004:20:26:09] relais-http netcache 0/0/0/162/+162 200 +350 - - ---- 0/0/0 0/0 {fr.adserver.yahoo.co||http://fr.f416.mail.} {|864|private||} "GET http://fr.adserver.yahoo.com/" Aug 9 20:30:46 localhost haproxy[2022]: 127.0.0.1:34020 [09/Aug/2004:20:30:46] relais-http netcache 0/0/0/182/+182 200 +279 - - ---- 0/0/0 0/0 {w.ods.org||} {Formilux/0.1.8|3495|||} "GET http://w.ods.org/sytadin.html HTTP/1.1" Aug 9 20:30:46 localhost haproxy[2022]: 127.0.0.1:34028 [09/Aug/2004:20:30:46] relais-http netcache 0/0/2/126/+128 200 +223 - - ---- 0/0/0 0/0 {www.infotrafic.com||http://w.ods.org/syt} {Apache/2.0.40 (Red H|9068|||} "GET http://www.infotrafic.com/images/live/cartesidf/grandes/idf_ne.png HTTP/1.1" 4.2.7) Examples of logs ----------------------- - haproxy[674]: 127.0.0.1:33319 [15/Oct/2003:08:31:57] relais-http Srv1 6559/0/7/147/6723 200 243 - - ---- 1/3/5 0/0 "HEAD / HTTP/1.0" => long request (6.5s) entered by hand through 'telnet'. The server replied in 147 ms, and the session ended normally ('----') - haproxy[674]: 127.0.0.1:33319 [15/Oct/2003:08:31:57] relais-http Srv1 6559/1230/7/147/6870 200 243 - - ---- 99/239/324 0/9 "HEAD / HTTP/1.0" => Idem, but the request was queued in the global queue behind 9 other requests, and waited there for 1230 ms. - haproxy[674]: 127.0.0.1:33320 [15/Oct/2003:08:32:17] relais-http Srv1 9/0/7/14/+30 200 +243 - - ---- 1/3/3 0/0 "GET /image.iso HTTP/1.0" => request for a long data transfer. The 'logasap' option was specified, so the log was produced just before transfering data. The server replied in 14 ms, 243 bytes of headers were sent to the client, and total time from accept to first data byte is 30 ms. - haproxy[674]: 127.0.0.1:33320 [15/Oct/2003:08:32:17] relais-http Srv1 9/0/7/14/30 502 243 - - PH-- 0/2/3 0/0 "GET /cgi-bin/bug.cgi? HTTP/1.0" => the proxy blocked a server response either because of an 'rspdeny' or 'rspideny' filter, or because it blocked sensible information which risked being cached. In this case, the response is replaced with a '502 bad gateway'. - haproxy[18113]: 127.0.0.1:34548 [15/Oct/2003:15:18:55] relais-http -1/-1/-1/-1/8490 -1 0 - - CR-- 0/2/2 0/0 "" => the client never completed its request and aborted itself ('C---') after 8.5s, while the proxy was waiting for the request headers ('-R--'). Nothing was sent to the server. - haproxy[18113]: 127.0.0.1:34549 [15/Oct/2003:15:19:06] relais-http -1/-1/-1/-1/50001 408 0 - - cR-- 2/2 0/0 "" => The client never completed its request, which was aborted by the time-out ('c---') after 50s, while the proxy was waiting for the request headers ('-R--'). Nothing was sent to the server, but the proxy could send a 408 return code to the client. - haproxy[18989]: 127.0.0.1:34550 [15/Oct/2003:15:24:28] relais-tcp Srv1 0/0/5007 0 cD 0/0/0 0/0 => This is a 'tcplog' entry. Client-side time-out ('c----') occured after 5s. - haproxy[18989]: 10.0.0.1:34552 [15/Oct/2003:15:26:31] relais-http Srv1 3183/-1/-1/-1/11215 503 0 - - SC-- 115/202/205 0/0 "HEAD / HTTP/1.0" => The request took 3s to complete (probably a network problem), and the connection to the server failed ('SC--') after 4 attemps of 2 seconds (config says 'retries 3'), then a 503 error code was sent to the client. There were 115 connections on this server, 202 connections on this proxy, and 205 on the global process. It is possible that the server refused the connection because of too many already established. 4.3) HTTP header manipulation ----------------------------- In HTTP mode, it is possible to rewrite, add or delete some of the request and response headers based on regular expressions. It is also possible to block a request or a response if a particular header matches a regular expression, which is enough to stops most elementary protocol attacks, and to protect against information leak from the internal network. But there is a limitation to this : since haproxy's HTTP engine knows nothing about keep-alive, only headers passed during the first request of a TCP session will be seen. All subsequent headers will be considered data only and not analyzed. Furthermore, haproxy doesn't touch data contents, it stops at the end of headers. The syntax is : reqadd to add a header to the request reqrep to modify the request reqirep same, but ignoring the case reqdel to delete a header in the request reqidel same, but ignoring the case reqallow definitely allow a request if a header matches reqiallow same, but ignoring the case reqdeny denies a request if a header matches reqideny same, but ignoring the case reqpass ignore a header matching reqipass same, but ignoring the case reqtarpit tarpit a request matching reqitarpit same, but ignoring the case rspadd to add a header to the response rsprep to modify the response rspirep same, but ignoring the case rspdel to delete the response rspidel same, but ignoring the case rspdeny replaces a response with a HTTP 502 if a header matches rspideny same, but ignoring the case is a POSIX regular expression (regex) which supports grouping through parenthesis (without the backslash). Spaces and other delimiters must be prefixed with a backslash ('\') to avoid confusion with a field delimiter. Other characters may be prefixed with a backslash to change their meaning : \t for a tab \r for a carriage return (CR) \n for a new line (LF) \ to mark a space and differentiate it from a delimiter \# to mark a sharp and differentiate it from a comment \\ to use a backslash in a regex \\\\ to use a backslash in the text (*2 for regex, *2 for haproxy) \xXX to write the ASCII hex code XX as in the C language contains the string to be used to replace the largest portion of text matching the regex. It can make use of the special characters above, and can reference a substring delimited by parenthesis in the regex, by the group numerical order from 0 to 9 (0 being the entire line). In this case, you would write a backslash ('\') immediately followed by one digit indicating the group position. represents the string which will systematically be added after the last header line. It can also use special characters above. Notes : ------- - the first line is considered as a header, which makes it possible to rewrite or filter HTTP requests URIs or response codes. - 'reqrep' is the equivalent of 'cliexp' in version 1.0, and 'rsprep' is the equivalent of 'srvexp' in 1.0. Those names are still supported but deprecated. - for performances reasons, the number of characters added to a request or to a response is limited to 4096 since version 1.1.5 (it was 256 before). This value is easy to modify in the code if needed (#define). If it is too short on occasional uses, it is possible to gain some space by removing some useless headers before adding new ones. - a denied request will generate an "HTTP 403 forbidden" response, while a denied response will generate an "HTTP 502 Bad gateway" response. - a tarpitted request will be held open on the client side for a duration defined in the contimeout parameter, or untill the client aborts. Nothing will be sent to any server. When the timeout is reached, the proxy will reply with a 500 server error response so that the attacker does not suspect it has been tarpitted. The logs may report the 500, but the termination flags will indicate 'PT' in this case. Examples : ---------- ###### a few examples ###### # rewrite 'online.fr' instead of 'free.fr' for GET and POST requests reqrep ^(GET\ .*)(.free.fr)(.*) \1.online.fr\3 reqrep ^(POST\ .*)(.free.fr)(.*) \1.online.fr\3 # force proxy connections to close reqirep ^Proxy-Connection:.* Proxy-Connection:\ close # rewrite locations rspirep ^(Location:\ )([^:]*://[^/]*)(.*) \1\3 ###### A full configuration being used on production ###### # Every header should end with a colon followed by one space. reqideny ^[^:\ ]*[\ ]*$ # block Apache chunk exploit reqideny ^Transfer-Encoding:[\ ]*chunked reqideny ^Host:\ apache- # block annoying worms that fill the logs... reqideny ^[^:\ ]*\ .*(\.|%2e)(\.|%2e)(%2f|%5c|/|\\\\) reqideny ^[^:\ ]*\ ([^\ ]*\ [^\ ]*\ |.*%00) reqideny ^[^:\ ]*\ .*