This document covers the configuration language as implemented in the version specified above. It does not provide any hints, examples, or advice. For such documentation, please refer to the Reference Manual or the Architecture Manual. The summary below is meant to help you find sections by name and navigate through the document. Note to documentation contributors : This document is formatted with 80 columns per line, with even number of spaces for indentation and without tabs. Please follow these rules strictly so that it remains easily printable everywhere. If a line needs to be printed verbatim and does not fit, please end each line with a backslash ('\') and continue on next line, indented by two characters. It is also sometimes useful to prefix all output lines (logs, console outputs) with 3 closing angle brackets ('>>>') in order to emphasize the difference between inputs and outputs when they may be ambiguous. If you add sections, please update the summary below for easier searching.
1. | Quick reminder about HTTP | |
1.1. | ||
1.2. | ||
1.2.1. | ||
1.2.2. | ||
1.3. | ||
1.3.1. | ||
1.3.2. | ||
2. |
Configuring HAProxy | |
2.1. | ||
2.2. | ||
2.3. | ||
2.4. | ||
2.5. | ||
3. |
Global parameters | |
3.1. | ||
3.2. | ||
3.3. | ||
3.4. | ||
3.5. | ||
3.6. | ||
3.7. | ||
4. |
Proxies | |
4.1. | ||
4.2. | ||
5. |
Bind and server options | |
5.1. | ||
5.2. | ||
5.3. | ||
5.3.1. | ||
5.3.2. | ||
6. |
Cache | |
6.1. | ||
6.2. | ||
6.2.1. | ||
6.2.2. | ||
7. |
Using ACLs and fetching samples | |
7.1. | ||
7.1.1. | ||
7.1.2. | ||
7.1.3. | ||
7.1.4. | ||
7.1.5. | ||
7.1.6. | ||
7.2. | ||
7.3. | ||
7.3.1. | ||
7.3.2. | ||
7.3.3. | ||
7.3.4. | ||
7.3.5. | ||
7.3.6. | ||
7.4. | ||
8. |
Logging | |
8.1. | ||
8.2. | ||
8.2.1. | ||
8.2.2. | ||
8.2.3. | ||
8.2.4. | ||
8.2.5. | ||
8.3. | ||
8.3.1. | ||
8.3.2. | ||
8.3.3. | ||
8.3.4. | ||
8.4. | ||
8.5. | ||
8.6. | ||
8.7. | ||
8.8. | ||
8.9. | ||
9. |
Supported filters | |
9.1. | ||
9.2. | ||
9.3. | ||
9.4. | ||
9.5. | ||
10. |
FastCGI applications | |
10.1. | ||
10.1.1. | ||
10.1.2. | ||
10.1.3. | ||
10.2. | ||
10.3. |
When HAProxy is running in HTTP mode, both the request and the response are fully analyzed and indexed, thus it becomes possible to build matching criteria on almost anything found in the contents. However, it is important to understand how HTTP requests and responses are formed, and how HAProxy decomposes them. It will then become easier to write correct rules and to debug existing configurations.
The HTTP protocol is transaction-driven. This means that each request will lead to one and only one response. Traditionally, a TCP connection is established from the client to the server, a request is sent by the client through the connection, the server responds, and the connection is closed. A new request will involve a new connection : [CON1] [REQ1] ... [RESP1] [CLO1] [CON2] [REQ2] ... [RESP2] [CLO2] ... In this mode, called the "HTTP close" mode, there are as many connection establishments as there are HTTP transactions. Since the connection is closed by the server after the response, the client does not need to know the content length. Due to the transactional nature of the protocol, it was possible to improve it to avoid closing a connection between two subsequent transactions. In this mode however, it is mandatory that the server indicates the content length for each response so that the client does not wait indefinitely. For this, a special header is used: "Content-length". This mode is called the "keep-alive" mode : [CON] [REQ1] ... [RESP1] [REQ2] ... [RESP2] [CLO] ... Its advantages are a reduced latency between transactions, and less processing power required on the server side. It is generally better than the close mode, but not always because the clients often limit their concurrent connections to a smaller value. Another improvement in the communications is the pipelining mode. It still uses keep-alive, but the client does not wait for the first response to send the second request. This is useful for fetching large number of images composing a page : [CON] [REQ1] [REQ2] ... [RESP1] [RESP2] [CLO] ... This can obviously have a tremendous benefit on performance because the network latency is eliminated between subsequent requests. Many HTTP agents do not correctly support pipelining since there is no way to associate a response with the corresponding request in HTTP. For this reason, it is mandatory for the server to reply in the exact same order as the requests were received. The next improvement is the multiplexed mode, as implemented in HTTP/2. This time, each transaction is assigned a single stream identifier, and all streams are multiplexed over an existing connection. Many requests can be sent in parallel by the client, and responses can arrive in any order since they also carry the stream identifier. By default HAProxy operates in keep-alive mode with regards to persistent connections: for each connection it processes each request and response, and leaves the connection idle on both sides between the end of a response and the start of a new request. When it receives HTTP/2 connections from a client, it processes all the requests in parallel and leaves the connection idling, waiting for new requests, just as if it was a keep-alive HTTP connection. HAProxy supports 4 connection modes : - keep alive : all requests and responses are processed (default) - tunnel : only the first request and response are processed, everything else is forwarded with no analysis (deprecated). - server close : the server-facing connection is closed after the response. - close : the connection is actively closed after end of response.
First, let's consider this HTTP request : Line Contents number 1 GET /serv/login.php?lang=en&profile=2 HTTP/1.1 2 Host: www.mydomain.com 3 User-agent: my small browser 4 Accept: image/jpeg, image/gif 5 Accept: image/png
Line 1 is the "request line". It is always composed of 3 fields : - a METHOD : GET - a URI : /serv/login.php?lang=en&profile=2 - a version tag : HTTP/1.1 All of them are delimited by what the standard calls LWS (linear white spaces), which are commonly spaces, but can also be tabs or line feeds/carriage returns followed by spaces/tabs. The method itself cannot contain any colon (':') and is limited to alphabetic letters. All those various combinations make it desirable that HAProxy performs the splitting itself rather than leaving it to the user to write a complex or inaccurate regular expression. The URI itself can have several forms : - A "relative URI" : /serv/login.php?lang=en&profile=2 It is a complete URL without the host part. This is generally what is received by servers, reverse proxies and transparent proxies. - An "absolute URI", also called a "URL" : http://192.168.0.12:8080/serv/login.php?lang=en&profile=2 It is composed of a "scheme" (the protocol name followed by '://'), a host name or address, optionally a colon (':') followed by a port number, then a relative URI beginning at the first slash ('/') after the address part. This is generally what proxies receive, but a server supporting HTTP/1.1 must accept this form too. - a star ('*') : this form is only accepted in association with the OPTIONS method and is not relayable. It is used to inquiry a next hop's capabilities. - an address:port combination : 192.168.0.12:80 This is used with the CONNECT method, which is used to establish TCP tunnels through HTTP proxies, generally for HTTPS, but sometimes for other protocols too. In a relative URI, two sub-parts are identified. The part before the question mark is called the "path". It is typically the relative path to static objects on the server. The part after the question mark is called the "query string". It is mostly used with GET requests sent to dynamic scripts and is very specific to the language, framework or application in use. HTTP/2 doesn't convey a version information with the request, so the version is assumed to be the same as the one of the underlying protocol (i.e. "HTTP/2").
The headers start at the second line. They are composed of a name at the beginning of the line, immediately followed by a colon (':'). Traditionally, an LWS is added after the colon but that's not required. Then come the values. Multiple identical headers may be folded into one single line, delimiting the values with commas, provided that their order is respected. This is commonly encountered in the "Cookie:" field. A header may span over multiple lines if the subsequent lines begin with an LWS. In the example in 1.2, lines 4 and 5 define a total of 3 values for the "Accept:" header. Contrary to a common misconception, header names are not case-sensitive, and their values are not either if they refer to other header names (such as the "Connection:" header). In HTTP/2, header names are always sent in lower case, as can be seen when running in debug mode. Internally, all header names are normalized to lower case so that HTTP/1.x and HTTP/2 use the exact same representation, and they are sent as-is on the other side. This explains why an HTTP/1.x request typed with camel case is delivered in lower case. The end of the headers is indicated by the first empty line. People often say that it's a double line feed, which is not exact, even if a double line feed is one valid form of empty line. Fortunately, HAProxy takes care of all these complex combinations when indexing headers, checking values and counting them, so there is no reason to worry about the way they could be written, but it is important not to accuse an application of being buggy if it does unusual, valid things. Important note: As suggested by RFC7231, HAProxy normalizes headers by replacing line breaks in the middle of headers by LWS in order to join multi-line headers. This is necessary for proper analysis and helps less capable HTTP parsers to work correctly and not to be fooled by such complex constructs.
An HTTP response looks very much like an HTTP request. Both are called HTTP messages. Let's consider this HTTP response : Line Contents number 1 HTTP/1.1 200 OK 2 Content-length: 350 3 Content-Type: text/html As a special case, HTTP supports so called "Informational responses" as status codes 1xx. These messages are special in that they don't convey any part of the response, they're just used as sort of a signaling message to ask a client to continue to post its request for instance. In the case of a status 100 response the requested information will be carried by the next non-100 response message following the informational one. This implies that multiple responses may be sent to a single request, and that this only works when keep-alive is enabled (1xx messages are HTTP/1.1 only). HAProxy handles these messages and is able to correctly forward and skip them, and only process the next non-100 response. As such, these messages are neither logged nor transformed, unless explicitly state otherwise. Status 101 messages indicate that the protocol is changing over the same connection and that haproxy must switch to tunnel mode, just as if a CONNECT had occurred. Then the Upgrade header would contain additional information about the type of protocol the connection is switching to.
Line 1 is the "response line". It is always composed of 3 fields : - a version tag : HTTP/1.1 - a status code : 200 - a reason : OK The status code is always 3-digit. The first digit indicates a general status : - 1xx = informational message to be skipped (e.g. 100, 101) - 2xx = OK, content is following (e.g. 200, 206) - 3xx = OK, no content following (e.g. 302, 304) - 4xx = error caused by the client (e.g. 401, 403, 404) - 5xx = error caused by the server (e.g. 500, 502, 503) Please refer to RFC7231 for the detailed meaning of all such codes. The "reason" field is just a hint, but is not parsed by clients. Anything can be found there, but it's a common practice to respect the well-established messages. It can be composed of one or multiple words, such as "OK", "Found", or "Authentication Required". HAProxy may emit the following status codes by itself : Code When / reason 200 access to stats page, and when replying to monitoring requests 301 when performing a redirection, depending on the configured code 302 when performing a redirection, depending on the configured code 303 when performing a redirection, depending on the configured code 307 when performing a redirection, depending on the configured code 308 when performing a redirection, depending on the configured code 400 for an invalid or too large request 401 when an authentication is required to perform the action (when accessing the stats page) 403 when a request is forbidden by a "http-request deny" rule 404 when the requested resource could not be found 408 when the request timeout strikes before the request is complete 410 when the requested resource is no longer available and will not be available again 500 when haproxy encounters an unrecoverable internal error, such as a memory allocation failure, which should never happen 502 when the server returns an empty, invalid or incomplete response, or when an "http-response deny" rule blocks the response. 503 when no server was available to handle the request, or in response to monitoring requests which match the "monitor fail" condition 504 when the response timeout strikes before the server responds The error 4xx and 5xx codes above may be customized (see "errorloc" in section 4.2).
Response headers work exactly like request headers, and as such, HAProxy uses the same parsing function for both. Please refer to paragraph 1.2.2 for more details.
HAProxy's configuration process involves 3 major sources of parameters : - the arguments from the command-line, which always take precedence - the "global" section, which sets process-wide parameters - the proxies sections which can take form of "defaults", "listen", "frontend" and "backend". The configuration file syntax consists in lines beginning with a keyword referenced in this manual, optionally followed by one or several parameters delimited by spaces.
HAProxy's configuration introduces a quoting and escaping system similar to many programming languages. The configuration file supports 3 types: escaping with a backslash, weak quoting with double quotes, and strong quoting with single quotes. If spaces have to be entered in strings, then they must be escaped by preceding them by a backslash ('\') or by quoting them. Backslashes also have to be escaped by doubling or strong quoting them. Escaping is achieved by preceding a special character by a backslash ('\'): \ to mark a space and differentiate it from a delimiter \# to mark a hash and differentiate it from a comment \\ to use a backslash \' to use a single quote and differentiate it from strong quoting \" to use a double quote and differentiate it from weak quoting Weak quoting is achieved by using double quotes (""). Weak quoting prevents the interpretation of: space as a parameter separator ' single quote as a strong quoting delimiter # hash as a comment start Weak quoting permits the interpretation of variables, if you want to use a non -interpreted dollar within a double quoted string, you should escape it with a backslash ("\$"), it does not work outside weak quoting. Interpretation of escaping and special characters are not prevented by weak quoting. Strong quoting is achieved by using single quotes (''). Inside single quotes, nothing is interpreted, it's the efficient way to quote regexes. Quoted and escaped strings are replaced in memory by their interpreted equivalent, it allows you to perform concatenation.
# those are equivalents:
log-format %{+Q}o\ %t\ %s\ %{-Q}r
log-format "%{+Q}o %t %s %{-Q}r"
log-format '%{+Q}o %t %s %{-Q}r'
log-format "%{+Q}o %t"' %s %{-Q}r'
log-format "%{+Q}o %t"' %s'\ %{-Q}r
# those are equivalents:
reqrep "^([^\ :]*)\ /static/(.*)" \1\ /\2
reqrep "^([^ :]*)\ /static/(.*)" '\1 /\2'
reqrep "^([^ :]*)\ /static/(.*)" "\1 /\2"
reqrep "^([^ :]*)\ /static/(.*)" "\1\ /\2"
HAProxy's configuration supports environment variables. Those variables are interpreted only within double quotes. Variables are expanded during the configuration parsing. Variable names must be preceded by a dollar ("$") and optionally enclosed with braces ("{}") similarly to what is done in Bourne shell. Variable names can contain alphanumerical characters or the character underscore ("_") but should not start with a digit.
bind "fd@${FD_APP1}"
log "${LOCAL_SYSLOG}:514" local0 notice # send to local server
user "$HAPROXY_USER"
Some variables are defined by HAProxy, they can be used in the configuration file, or could be inherited by a program (See 3.7. Programs): * HAPROXY_LOCALPEER: defined at the startup of the process which contains the name of the local peer. (See "-L" in the management guide.) * HAPROXY_CFGFILES: list of the configuration files loaded by HAProxy, separated by semicolons. Can be useful in the case you specified a directory. * HAPROXY_MWORKER: In master-worker mode, this variable is set to 1. * HAPROXY_CLI: configured listeners addresses of the stats socket for every processes, separated by semicolons. * HAPROXY_MASTER_CLI: In master-worker mode, listeners addresses of the master CLI, separated by semicolons. See also "external-check command" for other variables.
Some parameters involve values representing time, such as timeouts. These values are generally expressed in milliseconds (unless explicitly stated otherwise) but may be expressed in any other unit by suffixing the unit to the numeric value. It is important to consider this because it will not be repeated for every keyword. Supported units are : - us : microseconds. 1 microsecond = 1/1000000 second - ms : milliseconds. 1 millisecond = 1/1000 second. This is the default. - s : seconds. 1s = 1000ms - m : minutes. 1m = 60s = 60000ms - h : hours. 1h = 60m = 3600s = 3600000ms - d : days. 1d = 24h = 1440m = 86400s = 86400000ms
# Simple configuration for an HTTP proxy listening on port 80 on all # interfaces and forwarding requests to a single backend "servers" with a # single server "server1" listening on 127.0.0.1:8000 global daemon maxconn 256 defaults mode http timeout connect 5000ms timeout client 50000ms timeout server 50000ms frontend http-in bind *:80 default_backend servers backend servers server server1 127.0.0.1:8000 maxconn 32 # The same configuration defined with a single listen block. Shorter but # less expressive, especially in HTTP mode. global daemon maxconn 256 defaults mode http timeout connect 5000ms timeout client 50000ms timeout server 50000ms listen http-in bind *:80 server server1 127.0.0.1:8000 maxconn 32 Assuming haproxy is in $PATH, test these configurations in a shell with: $ sudo haproxy -f configuration.conf -c
Parameters in the "global" section are process-wide and often OS-specific. They are generally set once for all and do not need being changed once correct. Some of them have command-line equivalents. The following keywords are supported in the "global" section : * Process management and security - ca-base - chroot - crt-base - cpu-map - daemon - description - deviceatlas-json-file - deviceatlas-log-level - deviceatlas-separator - deviceatlas-properties-cookie - external-check - gid - group - hard-stop-after - h1-case-adjust - h1-case-adjust-file - log - log-tag - log-send-hostname - lua-load - lua-prepend-path - mworker-max-reloads - nbproc - nbthread - node - pidfile - presetenv - resetenv - uid - ulimit-n - user - set-dumpable - setenv - stats - ssl-default-bind-ciphers - ssl-default-bind-ciphersuites - ssl-default-bind-options - ssl-default-server-ciphers - ssl-default-server-ciphersuites - ssl-default-server-options - ssl-dh-param-file - ssl-server-verify - unix-bind - unsetenv - 51degrees-data-file - 51degrees-property-name-list - 51degrees-property-separator - 51degrees-cache-size - wurfl-data-file - wurfl-information-list - wurfl-information-list-separator - wurfl-cache-size - strict-limits * Performance tuning - busy-polling - max-spread-checks - maxconn - maxconnrate - maxcomprate - maxcompcpuusage - maxpipes - maxsessrate - maxsslconn - maxsslrate - maxzlibmem - noepoll - nokqueue - noevports - nopoll - nosplice - nogetaddrinfo - noreuseport - profiling.tasks - spread-checks - server-state-base - server-state-file - ssl-engine - ssl-mode-async - tune.buffers.limit - tune.buffers.reserve - tune.bufsize - tune.chksize - tune.comp.maxlevel - tune.h2.header-table-size - tune.h2.initial-window-size - tune.h2.max-concurrent-streams - tune.http.cookielen - tune.http.logurilen - tune.http.maxhdr - tune.idletimer - tune.lua.forced-yield - tune.lua.maxmem - tune.lua.session-timeout - tune.lua.task-timeout - tune.lua.service-timeout - tune.maxaccept - tune.maxpollevents - tune.maxrewrite - tune.pattern.cache-size - tune.pipesize - tune.pool-high-fd-ratio - tune.pool-low-fd-ratio - tune.rcvbuf.client - tune.rcvbuf.server - tune.recv_enough - tune.runqueue-depth - tune.sndbuf.client - tune.sndbuf.server - tune.ssl.cachesize - tune.ssl.lifetime - tune.ssl.force-private-cache - tune.ssl.maxrecord - tune.ssl.default-dh-param - tune.ssl.ssl-ctx-cache-size - tune.ssl.capture-cipherlist-size - tune.vars.global-max-size - tune.vars.proc-max-size - tune.vars.reqres-max-size - tune.vars.sess-max-size - tune.vars.txn-max-size - tune.zlib.memlevel - tune.zlib.windowsize * Debugging - debug - quiet
Assigns a default directory to fetch SSL CA certificates and CRLs from when a relative path is used with "ca-file" or "crl-file" directives. Absolute locations specified in "ca-file" and "crl-file" prevail and ignore "ca-base".
Changes current directory to <jail dir> and performs a chroot() there before dropping privileges. This increases the security level in case an unknown vulnerability would be exploited, since it would make it very hard for the attacker to exploit the system. This only works when the process is started with superuser privileges. It is important to ensure that <jail_dir> is both empty and non-writable to anyone.
On Linux 2.6 and above, it is possible to bind a process or a thread to a specific CPU set. This means that the process or the thread will never run on other CPUs. The "cpu-map" directive specifies CPU sets for process or thread sets. The first argument is a process set, eventually followed by a thread set. These sets have the format all | odd | even | number[-[number]] <number>> must be a number between 1 and 32 or 64, depending on the machine's word size. Any process IDs above nbproc and any thread IDs above nbthread are ignored. It is possible to specify a range with two such number delimited by a dash ('-'). It also is possible to specify all processes at once using "all", only odd numbers using "odd" or even numbers using "even", just like with the "bind-process" directive. The second and forthcoming arguments are CPU sets. Each CPU set is either a unique number between 0 and 31 or 63 or a range with two such numbers delimited by a dash ('-'). Multiple CPU numbers or ranges may be specified, and the processes or threads will be allowed to bind to all of them. Obviously, multiple "cpu-map" directives may be specified. Each "cpu-map" directive will replace the previous ones when they overlap. A thread will be bound on the intersection of its mapping and the one of the process on which it is attached. If the intersection is null, no specific binding will be set for the thread. Ranges can be partially defined. The higher bound can be omitted. In such case, it is replaced by the corresponding maximum value, 32 or 64 depending on the machine's word size. The prefix "auto:" can be added before the process set to let HAProxy automatically bind a process or a thread to a CPU by incrementing process/thread and CPU sets. To be valid, both sets must have the same size. No matter the declaration order of the CPU sets, it will be bound from the lowest to the highest bound. Having a process and a thread range with the "auto:" prefix is not supported. Only one range is supported, the other one must be a fixed number.
cpu-map 1-4 0-3 # bind processes 1 to 4 on the first 4 CPUs
cpu-map 1/all 0-3 # bind all threads of the first process on the
# first 4 CPUs
cpu-map 1- 0- # will be replaced by "cpu-map 1-64 0-63"
# or "cpu-map 1-32 0-31" depending on the machine's
# word size.
# all these lines bind the process 1 to the cpu 0, the process 2 to cpu 1
# and so on.
cpu-map auto:1-4 0-3
cpu-map auto:1-4 0-1 2-3
cpu-map auto:1-4 3 2 1 0
# all these lines bind the thread 1 to the cpu 0, the thread 2 to cpu 1
# and so on.
cpu-map auto:1/1-4 0-3
cpu-map auto:1/1-4 0-1 2-3
cpu-map auto:1/1-4 3 2 1 0
# bind each process to exactly one CPU using all/odd/even keyword
cpu-map auto:all 0-63
cpu-map auto:even 0-31
cpu-map auto:odd 32-63
# invalid cpu-map because process and CPU sets have different sizes.
cpu-map auto:1-4 0 # invalid
cpu-map auto:1 0-3 # invalid
# invalid cpu-map because automatic binding is used with a process range
# and a thread range.
cpu-map auto:all/all 0 # invalid
cpu-map auto:all/1-4 0 # invalid
cpu-map auto:1-4/all 0 # invalid
Assigns a default directory to fetch SSL certificates from when a relative path is used with "crtfile" directives. Absolute locations specified after "crtfile" prevail and ignore "crt-base".
Makes the process fork into background. This is the recommended mode of operation. It is equivalent to the command line "-D" argument. It can be disabled by the command line "-db" argument. This option is ignored in systemd mode.
Sets the path of the DeviceAtlas JSON data file to be loaded by the API. The path must be a valid JSON data file and accessible by HAProxy process.
Sets the level of information returned by the API. This directive is optional and set to 0 by default if not set.
Sets the character separator for the API properties results. This directive is optional and set to | by default if not set.
Sets the client cookie's name used for the detection if the DeviceAtlas Client-side component was used during the request. This directive is optional and set to DAPROPS by default if not set.
Allows the use of an external agent to perform health checks. This is disabled by default as a security precaution. See "option external-check".
Changes the process's group ID to <number>. It is recommended that the group ID is dedicated to HAProxy or to a small set of similar daemons. HAProxy must be started with a user belonging to this group, or with superuser privileges. Note that if haproxy is started from a user having supplementary groups, it will only be able to drop these groups if started with superuser privileges. See also "group" and "uid".
Similar to "gid" but uses the GID of group name <group name> from /etc/group. See also "gid" and "user".
Defines the maximum time allowed to perform a clean soft-stop.
<time> is the maximum time (by default in milliseconds) for which the instance will remain alive when a soft-stop is received via the SIGUSR1 signal.
This may be used to ensure that the instance will quit even if connections remain opened during a soft-stop (for example with long timeouts for a proxy in tcp mode). It applies both in TCP and HTTP mode.
global
hard-stop-after 30s
Defines the case adjustment to apply, when enabled, to the header name <from>, to change it to <to> before sending it to HTTP/1 clients or servers. <from> must be in lower case, and <from> and <to> must not differ except for their case. It may be repeated if several header names need to be adjusted. Duplicate entries are not allowed. If a lot of header names have to be adjusted, it might be more convenient to use "h1-case-adjust-file". Please note that no transformation will be applied unless "option h1-case-adjust-bogus-client" or "option h1-case-adjust-bogus-server" is specified in a proxy. There is no standard case for header names because, as stated in RFC7230, they are case-insensitive. So applications must handle them in a case- insensitive manner. But some bogus applications violate the standards and erroneously rely on the cases most commonly used by browsers. This problem becomes critical with HTTP/2 because all header names must be exchanged in lower case, and HAProxy follows the same convention. All header names are sent in lower case to clients and servers, regardless of the HTTP version. Applications which fail to properly process requests or responses may require to temporarily use such workarounds to adjust header names sent to them for the time it takes the application to be fixed. Please note that an application which requires such workarounds might be vulnerable to content smuggling attacks and must absolutely be fixed.
global
h1-case-adjust content-length Content-Length
See "h1-case-adjust-file", "option h1-case-adjust-bogus-client" and "option h1-case-adjust-bogus-server".
Defines a file containing a list of key/value pairs used to adjust the case of some header names before sending them to HTTP/1 clients or servers. The file <hdrs-file> must contain 2 header names per line. The first one must be in lower case and both must not differ except for their case. Lines which start with '#' are ignored, just like empty lines. Leading and trailing tabs and spaces are stripped. Duplicate entries are not allowed. Please note that no transformation will be applied unless "option h1-case-adjust-bogus-client" or "option h1-case-adjust-bogus-server" is specified in a proxy. If this directive is repeated, only the last one will be processed. It is an alternative to the directive "h1-case-adjust" if a lot of header names need to be adjusted. Please read the risks associated with using this. See "h1-case-adjust", "option h1-case-adjust-bogus-client" and "option h1-case-adjust-bogus-server".
Adds a global syslog server. Several global servers can be defined. They will receive logs for starts and exits, as well as all logs from proxies configured with "log global". <address> can be one of: - An IPv4 address optionally followed by a colon and a UDP port. If no port is specified, 514 is used by default (the standard syslog port). - An IPv6 address followed by a colon and optionally a UDP port. If no port is specified, 514 is used by default (the standard syslog port). - A filesystem path to a datagram UNIX domain socket, keeping in mind considerations for chroot (be sure the path is accessible inside the chroot) and uid/gid (be sure the path is appropriately writable). - A file descriptor number in the form "fd@<number>", which may point to a pipe, terminal, or socket. In this case unbuffered logs are used and one writev() call per log is performed. This is a bit expensive but acceptable for most workloads. Messages sent this way will not be truncated but may be dropped, in which case the DroppedLogs counter will be incremented. The writev() call is atomic even on pipes for messages up to PIPE_BUF size, which POSIX recommends to be at least 512 and which is 4096 bytes on most modern operating systems. Any larger message may be interleaved with messages from other processes. Exceptionally for debugging purposes the file descriptor may also be directed to a file, but doing so will significantly slow haproxy down as non-blocking calls will be ignored. Also there will be no way to purge nor rotate this file without restarting the process. Note that the configured syslog format is preserved, so the output is suitable for use with a TCP syslog server. See also the "short" and "raw" format below. - "stdout" / "stderr", which are respectively aliases for "fd@1" and "fd@2", see above. - A ring buffer in the form "ring@<name>", which will correspond to an in-memory ring buffer accessible over the CLI using the "show events" command, which will also list existing rings and their sizes. Such buffers are lost on reload or restart but when used as a complement this can help troubleshooting by having the logs instantly available. You may want to reference some environment variables in the address parameter, see section 2.3 about environment variables. <length> is an optional maximum line length. Log lines larger than this value will be truncated before being sent. The reason is that syslog servers act differently on log line length. All servers support the default value of 1024, but some servers simply drop larger lines while others do log them. If a server supports long lines, it may make sense to set this value here in order to avoid truncating long lines. Similarly, if a server drops long lines, it is preferable to truncate them before sending them. Accepted values are 80 to 65535 inclusive. The default value of 1024 is generally fine for all standard usages. Some specific cases of long captures or JSON-formatted logs may require larger values. You may also need to increase "tune.http.logurilen" if your request URIs are truncated. <format> is the log format used when generating syslog messages. It may be one of the following : rfc3164 The RFC3164 syslog message format. This is the default. (https://tools.ietf.org/html/rfc3164) rfc5424 The RFC5424 syslog message format. (https://tools.ietf.org/html/rfc5424) short A message containing only a level between angle brackets such as '<3>', followed by the text. The PID, date, time, process name and system name are omitted. This is designed to be used with a local log server. This format is compatible with what the systemd logger consumes. raw A message containing only the text. The level, PID, date, time, process name and system name are omitted. This is designed to be used in containers or during development, where the severity only depends on the file descriptor used (stdout/stderr). <ranges> A list of comma-separated ranges to identify the logs to sample. This is used to balance the load of the logs to send to the log server. The limits of the ranges cannot be null. They are numbered from 1. The size or period (in number of logs) of the sample must be set with <sample_size> parameter. <sample_size> The size of the sample in number of logs to consider when balancing their logging loads. It is used to balance the load of the logs to send to the syslog server. This size must be greater or equal to the maximum of the high limits of the ranges. (see also <ranges> parameter). <facility> must be one of the 24 standard syslog facilities : kern user mail daemon auth syslog lpr news uucp cron auth2 ftp ntp audit alert cron2 local0 local1 local2 local3 local4 local5 local6 local7 Note that the facility is ignored for the "short" and "raw" formats, but still required as a positional field. It is recommended to use "daemon" in this case to make it clear that it's only supposed to be used locally. An optional level can be specified to filter outgoing messages. By default, all messages are sent. If a maximum level is specified, only messages with a severity at least as important as this level will be sent. An optional minimum level can be specified. If it is set, logs emitted with a more severe level than this one will be capped to this level. This is used to avoid sending "emerg" messages on all terminals on some default syslog configurations. Eight levels are known : emerg alert crit err warning notice info debug
Sets the hostname field in the syslog header. If optional "string" parameter is set the header is set to the string contents, otherwise uses the hostname of the system. Generally used if one is not relaying logs through an intermediate syslog server or for simply customizing the hostname printed in the logs.
Sets the tag field in the syslog header to this string. It defaults to the
program name as launched from the command line, which usually is "haproxy".
Sometimes it can be useful to differentiate between multiple processes
running on the same host. See also the per-proxy "log-tag" directive.
This global directive loads and executes a Lua file. This directive can be used multiple times.
Prepends the given string followed by a semicolon to Lua's package.<type> variable. <type> must either be "path" or "cpath". If <type> is not given it defaults to "path". Lua's paths are semicolon delimited lists of patterns that specify how the `require` function attempts to find the source file of a library. Question marks (?) within a pattern will be replaced by module name. The path is evaluated left to right. This implies that paths that are prepended later will be checked earlier. As an example by specifying the following path: lua-prepend-path /usr/share/haproxy-lua/?/init.lua lua-prepend-path /usr/share/haproxy-lua/?.lua When `require "example"` is being called Lua will first attempt to load the /usr/share/haproxy-lua/example.lua script, if that does not exist the /usr/share/haproxy-lua/example/init.lua will be attempted and the default paths if that does not exist either. See https://www.lua.org/pil/8.1.html for the details within the Lua documentation.
Master-worker mode. It is equivalent to the command line "-W" argument. This mode will launch a "master" which will monitor the "workers". Using this mode, you can reload HAProxy directly by sending a SIGUSR2 signal to the master. The master-worker mode is compatible either with the foreground or daemon mode. It is recommended to use this mode with multiprocess and systemd. By default, if a worker exits with a bad return code, in the case of a segfault for example, all workers will be killed, and the master will leave. It is convenient to combine this behavior with Restart=on-failure in a systemd unit file in order to relaunch the whole process. If you don't want this behavior, you must use the keyword "no-exit-on-failure". See also "-W" in the management guide.
In master-worker mode, this option limits the number of time a worker can survive to a reload. If the worker did not leave after a reload, once its number of reloads is greater than this number, the worker will receive a SIGTERM. This option helps to keep under control the number of workers. See also "show proc" in the Management Guide.
Creates <number> processes when going daemon. This requires the "daemon" mode. By default, only one process is created, which is the recommended mode of operation. For systems limited to small sets of file descriptors per process, it may be needed to fork multiple daemons. When set to a value larger than 1, threads are automatically disabled. USING MULTIPLE PROCESSES IS HARDER TO DEBUG AND IS REALLY DISCOURAGED. See also "daemon" and "nbthread".
This setting is only available when support for threads was built in. It makes haproxy run on <number> threads. This is exclusive with "nbproc". While "nbproc" historically used to be the only way to use multiple processors, it also involved a number of shortcomings related to the lack of synchronization between processes (health-checks, peers, stick-tables, stats, ...) which do not affect threads. As such, any modern configuration is strongly encouraged to migrate away from "nbproc" to "nbthread". "nbthread" also works when HAProxy is started in foreground. On some platforms supporting CPU affinity, when nbproc is not used, the default "nbthread" value is automatically set to the number of CPUs the process is bound to upon startup. This means that the thread count can easily be adjusted from the calling process using commands like "taskset" or "cpuset". Otherwise, this value defaults to 1. The default value is reported in the output of "haproxy -vv". See also "nbproc".
Writes PIDs of all daemons into file <pidfile>. This option is equivalent to the "-p" command line argument. The file must be accessible to the user starting the process. See also "daemon".
Sets environment variable <name> to value <value>. If the variable exists, it is NOT overwritten. The changes immediately take effect so that the next line in the configuration file sees the new value. See also "setenv", "resetenv", and "unsetenv".
Removes all environment variables except the ones specified in argument. It allows to use a clean controlled environment before setting new values with setenv or unsetenv. Please note that some internal functions may make use of some environment variables, such as time manipulation functions, but also OpenSSL or even external checks. This must be used with extreme care and only after complete validation. The changes immediately take effect so that the next line in the configuration file sees the new environment. See also "setenv", "presetenv", and "unsetenv".
Limits the stats socket to a certain set of processes numbers. By default the stats socket is bound to all processes, causing a warning to be emitted when nbproc is greater than 1 because there is no way to select the target process when connecting. However, by using this setting, it becomes possible to pin the stats socket to a specific set of processes, typically the first one. The warning will automatically be disabled when this setting is used, whatever the number of processes used. The maximum process ID depends on the machine's word size (32 or 64). Ranges can be partially defined. The higher bound can be omitted. In such case, it is replaced by the corresponding maximum value. A better option consists in using the "process" setting of the "stats socket" line to force the process on each line.
Specifies the directory prefix to be prepended in front of all servers state file names which do not start with a '/'. See also "server-state-file", "load-server-state-from-file" and "server-state-file-name".
Specifies the path to the file containing state of servers. If the path starts with a slash ('/'), it is considered absolute, otherwise it is considered relative to the directory specified using "server-state-base" (if set) or to the current directory. Before reloading HAProxy, it is possible to save the servers' current state using the stats command "show servers state". The output of this command must be written in the file pointed by <file>. When starting up, before handling traffic, HAProxy will read, load and apply state for each server found in the file and available in its current running configuration. See also "server-state-base" and "show servers state", "load-server-state-from-file" and "server-state-file-name"
Sets environment variable <name> to value <value>. If the variable exists, it is overwritten. The changes immediately take effect so that the next line in the configuration file sees the new value. See also "presetenv", "resetenv", and "unsetenv".
This option is better left disabled by default and enabled only upon a developer's request. If it has been enabled, it may still be forcibly disabled by prefixing it with the "no" keyword. It has no impact on performance nor stability but will try hard to re-enable core dumps that were possibly disabled by file size limitations (ulimit -f), core size limitations (ulimit -c), or "dumpability" of a process after changing its UID/GID (such as /proc/sys/fs/suid_dumpable on Linux). Core dumps might still be limited by the current directory's permissions (check what directory the file is started from), the chroot directory's permission (it may be needed to temporarily disable the chroot directive or to move it to a dedicated writable location), or any other system-specific constraint. For example, some Linux flavours are notorious for replacing the default core file with a path to an executable not even installed on the system (check /proc/sys/kernel/core_pattern). Often, simply writing "core", "core.%p" or "/var/log/core/core.%p" addresses the issue. When trying to enable this option waiting for a rare issue to re-appear, it's often a good idea to first try to obtain such a dump by issuing, for example, "kill -11" to the haproxy process and verify that it leaves a core where expected when dying.
This setting is only available when support for OpenSSL was built in. It sets the default string describing the list of cipher algorithms ("cipher suite") that are negotiated during the SSL/TLS handshake up to TLSv1.2 for all "bind" lines which do not explicitly define theirs. The format of the string is defined in "man 1 ciphers" from OpenSSL man pages. For background information and recommendations see e.g. (https://wiki.mozilla.org/Security/Server_Side_TLS) and (https://mozilla.github.io/server-side-tls/ssl-config-generator/). For TLSv1.3 cipher configuration, please check the "ssl-default-bind-ciphersuites" keyword. Please check the "bind" keyword for more information.
This setting is only available when support for OpenSSL was built in and OpenSSL 1.1.1 or later was used to build HAProxy. It sets the default string describing the list of cipher algorithms ("cipher suite") that are negotiated during the TLSv1.3 handshake for all "bind" lines which do not explicitly define theirs. The format of the string is defined in "man 1 ciphers" from OpenSSL man pages under the section "ciphersuites". For cipher configuration for TLSv1.2 and earlier, please check the "ssl-default-bind-ciphers" keyword. Please check the "bind" keyword for more information.
This setting is only available when support for OpenSSL was built in. It sets default ssl-options to force on all "bind" lines. Please check the "bind" keyword to see available options.
global
ssl-default-bind-options ssl-min-ver TLSv1.0 no-tls-tickets
This setting is only available when support for OpenSSL was built in. It sets the default string describing the list of cipher algorithms that are negotiated during the SSL/TLS handshake up to TLSv1.2 with the server, for all "server" lines which do not explicitly define theirs. The format of the string is defined in "man 1 ciphers" from OpenSSL man pages. For background information and recommendations see e.g. (https://wiki.mozilla.org/Security/Server_Side_TLS) and (https://mozilla.github.io/server-side-tls/ssl-config-generator/). For TLSv1.3 cipher configuration, please check the "ssl-default-server-ciphersuites" keyword. Please check the "server" keyword for more information.
This setting is only available when support for OpenSSL was built in and OpenSSL 1.1.1 or later was used to build HAProxy. It sets the default string describing the list of cipher algorithms that are negotiated during the TLSv1.3 handshake with the server, for all "server" lines which do not explicitly define theirs. The format of the string is defined in "man 1 ciphers" from OpenSSL man pages under the section "ciphersuites". For cipher configuration for TLSv1.2 and earlier, please check the "ssl-default-server-ciphers" keyword. Please check the "server" keyword for more information.
This setting is only available when support for OpenSSL was built in. It sets default ssl-options to force on all "server" lines. Please check the "server" keyword to see available options.
This setting is only available when support for OpenSSL was built in. It sets
the default DH parameters that are used during the SSL/TLS handshake when
ephemeral Diffie-Hellman (DHE) key exchange is used, for all "bind" lines
which do not explicitly define theirs. It will be overridden by custom DH
parameters found in a bind certificate file if any. If custom DH parameters
are not specified either by using ssl-dh-param-file or by setting them
directly in the certificate file, pre-generated DH parameters of the size
specified by tune.ssl.default-dh-param will be used. Custom parameters are
known to be more secure and therefore their use is recommended.
Custom DH parameters may be generated by using the OpenSSL command
"openssl dhparam <size>", where size should be at least 2048, as 1024-bit DH
parameters should not be considered secure anymore.
The default behavior for SSL verify on servers side. If specified to 'none', servers certificates are not verified. The default is 'required' except if forced using cmdline option '-dV'.
Binds a UNIX socket to <path> or a TCPv4/v6 address to <address:port>. Connections to this socket will return various statistics outputs and even allow some commands to be issued to change some runtime settings. Please consult section 9.3 "Unix Socket commands" of Management Guide for more details. All parameters supported by "bind" lines are supported, for instance to restrict access to some users or their access rights. Please consult section 5.1 for more information.
The default timeout on the stats socket is set to 10 seconds. It is possible to change this value with "stats timeout". The value must be passed in milliseconds, or be suffixed by a time unit among { us, ms, s, m, h, d }.
By default, the stats socket is limited to 10 concurrent connections. It is possible to change this value with "stats maxconn".
Changes the process's user ID to <number>. It is recommended that the user ID is dedicated to HAProxy or to a small set of similar daemons. HAProxy must be started with superuser privileges in order to be able to switch to another one. See also "gid" and "user".
Sets the maximum number of per-process file-descriptors to <number>. By default, it is automatically computed, so it is recommended not to use this option.
Fixes common settings to UNIX listening sockets declared in "bind" statements. This is mainly used to simplify declaration of those UNIX sockets and reduce the risk of errors, since those settings are most commonly required but are also process-specific. The <prefix> setting can be used to force all socket path to be relative to that directory. This might be needed to access another component's chroot. Note that those paths are resolved before haproxy chroots itself, so they are absolute. The <mode>, <user>, <uid>, <group> and <gid> all have the same meaning as their homonyms used by the "bind" statement. If both are specified, the "bind" statement has priority, meaning that the "unix-bind" settings may be seen as process-wide default settings.
Removes environment variables specified in arguments. This can be useful to hide some sensitive information that are occasionally inherited from the user's environment during some operations. Variables which did not exist are silently ignored so that after the operation, it is certain that none of these variables remain. The changes immediately take effect so that the next line in the configuration file will not see these variables. See also "setenv", "presetenv", and "resetenv".
Similar to "uid" but uses the UID of user name <user name> from /etc/passwd. See also "uid" and "group".
Only letters, digits, hyphen and underscore are allowed, like in DNS names. This statement is useful in HA configurations where two or more processes or servers share the same IP address. By setting a different node-name on all nodes, it becomes easy to immediately spot what server is handling the traffic.
Add a text that describes the instance. Please note that it is required to escape certain characters (# for example) and this text is inserted into a html page so you should avoid using "<" and ">" characters.
The path of the 51Degrees data file to provide device detection services. The file should be unzipped and accessible by HAProxy with relevant permissions. Please note that this option is only available when haproxy has been compiled with USE_51DEGREES.
A list of 51Degrees property names to be load from the dataset. A full list of names is available on the 51Degrees website: https://51degrees.com/resources/property-dictionary Please note that this option is only available when haproxy has been compiled with USE_51DEGREES.
A char that will be appended to every property value in a response header containing 51Degrees results. If not set that will be set as ','. Please note that this option is only available when haproxy has been compiled with USE_51DEGREES.
Sets the size of the 51Degrees converter cache to <number> entries. This is an LRU cache which reminds previous device detections and their results. By default, this cache is disabled. Please note that this option is only available when haproxy has been compiled with USE_51DEGREES.
The path of the WURFL data file to provide device detection services. The file should be accessible by HAProxy with relevant permissions. Please note that this option is only available when haproxy has been compiled with USE_WURFL=1.
A space-delimited list of WURFL capabilities, virtual capabilities, property names we plan to use in injected headers. A full list of capability and virtual capability names is available on the Scientiamobile website : https://www.scientiamobile.com/wurflCapability Valid WURFL properties are: - wurfl_id Contains the device ID of the matched device. - wurfl_root_id Contains the device root ID of the matched device. - wurfl_isdevroot Tells if the matched device is a root device. Possible values are "TRUE" or "FALSE". - wurfl_useragent The original useragent coming with this particular web request. - wurfl_api_version Contains a string representing the currently used Libwurfl API version. - wurfl_info A string containing information on the parsed wurfl.xml and its full path. - wurfl_last_load_time Contains the UNIX timestamp of the last time WURFL has been loaded successfully. - wurfl_normalized_useragent The normalized useragent. Please note that this option is only available when haproxy has been compiled with USE_WURFL=1.
A char that will be used to separate values in a response header containing WURFL results. If not set that a comma (',') will be used by default. Please note that this option is only available when haproxy has been compiled with USE_WURFL=1.
A list of WURFL patch file paths. Note that patches are loaded during startup thus before the chroot. Please note that this option is only available when haproxy has been compiled with USE_WURFL=1.
Sets the WURFL Useragent cache size. For faster lookups, already processed user agents are kept in a LRU cache : - "0" : no cache is used. - <size> : size of lru cache in elements. Please note that this option is only available when haproxy has been compiled with USE_WURFL=1.
Makes process fail at startup when a setrlimit fails. Haproxy is tries to set the best setrlimit according to what has been calculated. If it fails, it will emit a warning. Use this option if you want an explicit failure of haproxy when those limits fail. This option is disabled by default. If it has been enabled, it may still be forcibly disabled by prefixing it with the "no" keyword.
In some situations, especially when dealing with low latency on processors supporting a variable frequency or when running inside virtual machines, each time the process waits for an I/O using the poller, the processor goes back to sleep or is offered to another VM for a long time, and it causes excessively high latencies. This option provides a solution preventing the processor from sleeping by always using a null timeout on the pollers. This results in a significant latency reduction (30 to 100 microseconds observed) at the expense of a risk to overheat the processor. It may even be used with threads, in which case improperly bound threads may heavily conflict, resulting in a worse performance and high values for the CPU stolen fields in "show info" output, indicating which threads are misconfigured. It is important not to let the process run on the same processor as the network interrupts when this option is used. It is also better to avoid using it on multiple CPU threads sharing the same core. This option is disabled by default. If it has been enabled, it may still be forcibly disabled by prefixing it with the "no" keyword. It is ignored by the "select" and "poll" pollers. This option is automatically disabled on old processes in the context of seamless reload; it avoids too much cpu conflicts when multiple processes stay around for some time waiting for the end of their current connections.
By default, haproxy tries to spread the start of health checks across the smallest health check interval of all the servers in a farm. The principle is to avoid hammering services running on the same server. But when using large check intervals (10 seconds or more), the last servers in the farm take some time before starting to be tested, which can be a problem. This parameter is used to enforce an upper bound on delay between the first and the last check, even if the servers' check intervals are larger. When servers run with shorter intervals, their intervals will be respected though.
Sets the maximum per-process number of concurrent connections to <number>. It is equivalent to the command-line argument "-n". Proxies will stop accepting connections when this limit is reached. The "ulimit-n" parameter is automatically adjusted according to this value. See also "ulimit-n". Note: the "select" poller cannot reliably use more than 1024 file descriptors on some platforms. If your platform only supports select and reports "select FAILED" on startup, you need to reduce maxconn until it works (slightly below 500 in general). If this value is not set, it will automatically be calculated based on the current file descriptors limit reported by the "ulimit -n" command, possibly reduced to a lower value if a memory limit is enforced, based on the buffer size, memory allocated to compression, SSL cache size, and use or not of SSL and the associated maxsslconn (which can also be automatic).
Sets the maximum per-process number of connections per second to <number>. Proxies will stop accepting connections when this limit is reached. It can be used to limit the global capacity regardless of each frontend capacity. It is important to note that this can only be used as a service protection measure, as there will not necessarily be a fair share between frontends when the limit is reached, so it's a good idea to also limit each frontend to some value close to its expected share. Also, lowering tune.maxaccept can improve fairness.
Sets the maximum per-process input compression rate to <number> kilobytes per second. For each session, if the maximum is reached, the compression level will be decreased during the session. If the maximum is reached at the beginning of a session, the session will not compress at all. If the maximum is not reached, the compression level will be increased up to tune.comp.maxlevel. A value of zero means there is no limit, this is the default value.
Sets the maximum CPU usage HAProxy can reach before stopping the compression for new requests or decreasing the compression level of current requests. It works like 'maxcomprate' but measures CPU usage instead of incoming data bandwidth. The value is expressed in percent of the CPU used by haproxy. In case of multiple processes (nbproc > 1), each process manages its individual usage. A value of 100 disable the limit. The default value is 100. Setting a lower value will prevent the compression work from slowing the whole process down and from introducing high latencies.
Sets the maximum per-process number of pipes to <number>. Currently, pipes are only used by kernel-based tcp splicing. Since a pipe contains two file descriptors, the "ulimit-n" value will be increased accordingly. The default value is maxconn/4, which seems to be more than enough for most heavy usages. The splice code dynamically allocates and releases pipes, and can fall back to standard copy, so setting this value too low may only impact performance.
Sets the maximum per-process number of sessions per second to <number>. Proxies will stop accepting connections when this limit is reached. It can be used to limit the global capacity regardless of each frontend capacity. It is important to note that this can only be used as a service protection measure, as there will not necessarily be a fair share between frontends when the limit is reached, so it's a good idea to also limit each frontend to some value close to its expected share. Also, lowering tune.maxaccept can improve fairness.
Sets the maximum per-process number of concurrent SSL connections to <number>. By default there is no SSL-specific limit, which means that the global maxconn setting will apply to all connections. Setting this limit avoids having openssl use too much memory and crash when malloc returns NULL (since it unfortunately does not reliably check for such conditions). Note that the limit applies both to incoming and outgoing connections, so one connection which is deciphered then ciphered accounts for 2 SSL connections. If this value is not set, but a memory limit is enforced, this value will be automatically computed based on the memory limit, maxconn, the buffer size, memory allocated to compression, SSL cache size, and use of SSL in either frontends, backends or both. If neither maxconn nor maxsslconn are specified when there is a memory limit, haproxy will automatically adjust these values so that 100% of the connections can be made over SSL with no risk, and will consider the sides where it is enabled (frontend, backend, both).
Sets the maximum per-process number of SSL sessions per second to <number>. SSL listeners will stop accepting connections when this limit is reached. It can be used to limit the global SSL CPU usage regardless of each frontend capacity. It is important to note that this can only be used as a service protection measure, as there will not necessarily be a fair share between frontends when the limit is reached, so it's a good idea to also limit each frontend to some value close to its expected share. It is also important to note that the sessions are accounted before they enter the SSL stack and not after, which also protects the stack against bad handshakes. Also, lowering tune.maxaccept can improve fairness.
Sets the maximum amount of RAM in megabytes per process usable by the zlib. When the maximum amount is reached, future sessions will not compress as long as RAM is unavailable. When sets to 0, there is no limit. The default value is 0. The value is available in bytes on the UNIX socket with "show info" on the line "MaxZlibMemUsage", the memory used by zlib is "ZlibMemUsage" in bytes.
Disables the use of the "epoll" event polling system on Linux. It is equivalent to the command-line argument "-de". The next polling system used will generally be "poll". See also "nopoll".
Disables the use of the "kqueue" event polling system on BSD. It is equivalent to the command-line argument "-dk". The next polling system used will generally be "poll". See also "nopoll".
Disables the use of the event ports event polling system on SunOS systems derived from Solaris 10 and later. It is equivalent to the command-line argument "-dv". The next polling system used will generally be "poll". See also "nopoll".
Disables the use of the "poll" event polling system. It is equivalent to the command-line argument "-dp". The next polling system used will be "select". It should never be needed to disable "poll" since it's available on all platforms supported by HAProxy. See also "nokqueue", "noepoll" and "noevports".
Disables the use of kernel tcp splicing between sockets on Linux. It is equivalent to the command line argument "-dS". Data will then be copied using conventional and more portable recv/send calls. Kernel tcp splicing is limited to some very recent instances of kernel 2.6. Most versions between 2.6.25 and 2.6.28 are buggy and will forward corrupted data, so they must not be used. This option makes it easier to globally disable kernel splicing in case of doubt. See also "option splice-auto", "option splice-request" and "option splice-response".
Disables the use of getaddrinfo(3) for name resolving. It is equivalent to the command line argument "-dG". Deprecated gethostbyname(3) will be used.
Disables the use of SO_REUSEPORT - see socket(7). It is equivalent to the command line argument "-dR".
Enables ('on') or disables ('off') per-task CPU profiling. When set to 'auto' the profiling automatically turns on a thread when it starts to suffer from an average latency of 1000 microseconds or higher as reported in the "avg_loop_us" activity field, and automatically turns off when the latency returns below 990 microseconds (this value is an average over the last 1024 loops so it does not vary quickly and tends to significantly smooth short spikes). It may also spontaneously trigger from time to time on overloaded systems, containers, or virtual machines, or when the system swaps (which must absolutely never happen on a load balancer). CPU profiling per task can be very convenient to report where the time is spent and which requests have what effect on which other request. Enabling it will typically affect the overall's performance by less than 1%, thus it is recommended to leave it to the default 'auto' value so that it only operates when a problem is identified. This feature requires a system supporting the clock_gettime(2) syscall with clock identifiers CLOCK_MONOTONIC and CLOCK_THREAD_CPUTIME_ID, otherwise the reported time will be zero. This option may be changed at run time using "set profiling" on the CLI.
Sometimes it is desirable to avoid sending agent and health checks to servers at exact intervals, for instance when many logical servers are located on the same physical server. With the help of this parameter, it becomes possible to add some randomness in the check interval between 0 and +/- 50%. A value between 2 and 5 seems to show good results. The default value remains at 0.
Sets the OpenSSL engine to <name>. List of valid values for <name> may be obtained using the command "openssl engine". This statement may be used multiple times, it will simply enable multiple crypto engines. Referencing an unsupported engine will prevent haproxy from starting. Note that many engines will lead to lower HTTPS performance than pure software with recent processors. The optional command "algo" sets the default algorithms an ENGINE will supply using the OPENSSL function ENGINE_set_default_string(). A value of "ALL" uses the engine for all cryptographic operations. If no list of algo is specified then the value of "ALL" is used. A comma-separated list of different algorithms may be specified, including: RSA, DSA, DH, EC, RAND, CIPHERS, DIGESTS, PKEY, PKEY_CRYPTO, PKEY_ASN1. This is the same format that openssl configuration file uses: https://www.openssl.org/docs/man1.0.2/apps/config.html
Adds SSL_MODE_ASYNC mode to the SSL context. This enables asynchronous TLS I/O operations if asynchronous capable SSL engines are used. The current implementation supports a maximum of 32 engines. The Openssl ASYNC API doesn't support moving read/write buffers and is not compliant with haproxy's buffer management. So the asynchronous mode is disabled on read/write operations (it is only enabled during initial and renegotiation handshakes).
Sets a hard limit on the number of buffers which may be allocated per process. The default value is zero which means unlimited. The minimum non-zero value will always be greater than "tune.buffers.reserve" and should ideally always be about twice as large. Forcing this value can be particularly useful to limit the amount of memory a process may take, while retaining a sane behavior. When this limit is reached, sessions which need a buffer wait for another one to be released by another session. Since buffers are dynamically allocated and released, the waiting time is very short and not perceptible provided that limits remain reasonable. In fact sometimes reducing the limit may even increase performance by increasing the CPU cache's efficiency. Tests have shown good results on average HTTP traffic with a limit to 1/10 of the expected global maxconn setting, which also significantly reduces memory usage. The memory savings come from the fact that a number of connections will not allocate 2*tune.bufsize. It is best not to touch this value unless advised to do so by an haproxy core developer.
Sets the number of buffers which are pre-allocated and reserved for use only during memory shortage conditions resulting in failed memory allocations. The minimum value is 2 and is also the default. There is no reason a user would want to change this value, it's mostly aimed at haproxy core developers.
Sets the buffer size to this size (in bytes). Lower values allow more sessions to coexist in the same amount of RAM, and higher values allow some applications with very large cookies to work. The default value is 16384 and can be changed at build time. It is strongly recommended not to change this from the default value, as very low values will break some services such as statistics, and values larger than default size will increase memory usage, possibly causing the system to run out of memory. At least the global maxconn parameter should be decreased by the same factor as this one is increased. In addition, use of HTTP/2 mandates that this value must be 16384 or more. If an HTTP request is larger than (tune.bufsize - tune.maxrewrite), haproxy will return HTTP 400 (Bad Request) error. Similarly if an HTTP response is larger than this size, haproxy will return HTTP 502 (Bad Gateway). Note that the value set using this parameter will automatically be rounded up to the next multiple of 8 on 32-bit machines and 16 on 64-bit machines.
Sets the check buffer size to this size (in bytes). Higher values may help find string or regex patterns in very large pages, though doing so may imply more memory and CPU usage. The default value is 16384 and can be changed at build time. It is not recommended to change this value, but to use better checks whenever possible.
Sets the maximum compression level. The compression level affects CPU usage during compression. This value affects CPU usage during compression. Each session using compression initializes the compression algorithm with this value. The default value is 1.
If compiled with DEBUG_FAIL_ALLOC, gives the percentage of chances an allocation attempt fails. Must be between 0 (no failure) and 100 (no success). This is useful to debug and make sure memory failures are handled gracefully.
Sets the HTTP/2 dynamic header table size. It defaults to 4096 bytes and cannot be larger than 65536 bytes. A larger value may help certain clients send more compact requests, depending on their capabilities. This amount of memory is consumed for each HTTP/2 connection. It is recommended not to change it.
Sets the HTTP/2 initial window size, which is the number of bytes the client can upload before waiting for an acknowledgment from haproxy. This setting only affects payload contents (i.e. the body of POST requests), not headers. The default value is 65535, which roughly allows up to 5 Mbps of upload bandwidth per client over a network showing a 100 ms ping time, or 500 Mbps over a 1-ms local network. It can make sense to increase this value to allow faster uploads, or to reduce it to increase fairness when dealing with many clients. It doesn't affect resource usage.
Sets the HTTP/2 maximum number of concurrent streams per connection (ie the number of outstanding requests on a single connection). The default value is 100. A larger one may slightly improve page load time for complex sites when visited over high latency networks, but increases the amount of resources a single client may allocate. A value of zero disables the limit so a single client may create as many streams as allocatable by haproxy. It is highly recommended not to change this value.
Sets the HTTP/2 maximum frame size that haproxy announces it is willing to receive to its peers. The default value is the largest between 16384 and the buffer size (tune.bufsize). In any case, haproxy will not announce support for frame sizes larger than buffers. The main purpose of this setting is to allow to limit the maximum frame size setting when using large buffers. Too large frame sizes might have performance impact or cause some peers to misbehave. It is highly recommended not to change this value.
Sets the maximum length of captured cookies. This is the maximum value that the "capture cookie xxx len yyy" will be allowed to take, and any upper value will automatically be truncated to this one. It is important not to set too high a value because all cookie captures still allocate this size whatever their configured value (they share a same pool). This value is per request per response, so the memory allocated is twice this value per connection. When not specified, the limit is set to 63 characters. It is recommended not to change this value.
Sets the maximum length of request URI in logs. This prevents truncating long request URIs with valuable query strings in log lines. This is not related to syslog limits. If you increase this limit, you may also increase the 'log ... len yyy' parameter. Your syslog daemon may also need specific configuration directives too. The default value is 1024.
Sets the maximum number of headers in a request. When a request comes with a number of headers greater than this value (including the first line), it is rejected with a "400 Bad Request" status code. Similarly, too large responses are blocked with "502 Bad Gateway". The default value is 101, which is enough for all usages, considering that the widely deployed Apache server uses the same limit. It can be useful to push this limit further to temporarily allow a buggy application to work by the time it gets fixed. The accepted range is 1..32767. Keep in mind that each new header consumes 32bits of memory for each session, so don't push this limit too high.
Sets the duration after which haproxy will consider that an empty buffer is probably associated with an idle stream. This is used to optimally adjust some packet sizes while forwarding large and small data alternatively. The decision to use splice() or to send large buffers in SSL is modulated by this parameter. The value is in milliseconds between 0 and 65535. A value of zero means that haproxy will not try to detect idle streams. The default is 1000, which seems to correctly detect end user pauses (e.g. read a page before clicking). There should be no reason for changing this value. Please check tune.ssl.maxrecord below.
Enables ('on') or disables ('off') the listener's multi-queue accept which
spreads the incoming traffic to all threads a "bind" line is allowed to run
on instead of taking them for itself. This provides a smoother traffic
distribution and scales much better, especially in environments where threads
may be unevenly loaded due to external activity (network interrupts colliding
with one thread for example). This option is enabled by default, but it may
be forcefully disabled for troubleshooting or for situations where it is
estimated that the operating system already provides a good enough
distribution and connections are extremely short-lived.
This directive forces the Lua engine to execute a yield each <number> of instructions executed. This permits interrupting a long script and allows the HAProxy scheduler to process other tasks like accepting connections or forwarding traffic. The default value is 10000 instructions. If HAProxy often executes some Lua code but more responsiveness is required, this value can be lowered. If the Lua code is quite long and its result is absolutely required to process the data, the <number> can be increased.
Sets the maximum amount of RAM in megabytes per process usable by Lua. By default it is zero which means unlimited. It is important to set a limit to ensure that a bug in a script will not result in the system running out of memory.
This is the execution timeout for the Lua sessions. This is useful for preventing infinite loops or spending too much time in Lua. This timeout counts only the pure Lua runtime. If the Lua does a sleep, the sleep is not taken in account. The default timeout is 4s.
Purpose is the same as "tune.lua.session-timeout", but this timeout is dedicated to the tasks. By default, this timeout isn't set because a task may remain alive during of the lifetime of HAProxy. For example, a task used to check servers.
This is the execution timeout for the Lua services. This is useful for preventing infinite loops or spending too much time in Lua. This timeout counts only the pure Lua runtime. If the Lua does a sleep, the sleep is not taken in account. The default timeout is 4s.
Sets the maximum number of consecutive connections a process may accept in a row before switching to other work. In single process mode, higher numbers give better performance at high connection rates. However in multi-process modes, keeping a bit of fairness between processes generally is better to increase performance. This value applies individually to each listener, so that the number of processes a listener is bound to is taken into account. This value defaults to 64. In multi-process mode, it is divided by twice the number of processes the listener is bound to. Setting this value to -1 completely disables the limitation. It should normally not be needed to tweak this value.
Sets the maximum amount of events that can be processed at once in a call to the polling system. The default value is adapted to the operating system. It has been noticed that reducing it below 200 tends to slightly decrease latency at the expense of network bandwidth, and increasing it above 200 tends to trade latency for slightly increased bandwidth.
Sets the reserved buffer space to this size in bytes. The reserved space is used for header rewriting or appending. The first reads on sockets will never fill more than bufsize-maxrewrite. Historically it has defaulted to half of bufsize, though that does not make much sense since there are rarely large numbers of headers to add. Setting it too high prevents processing of large requests or responses. Setting it too low prevents addition of new headers to already large requests or to POST requests. It is generally wise to set it to about 1024. It is automatically readjusted to half of bufsize if it is larger than that. This means you don't have to worry about it when changing bufsize.
Sets the size of the pattern lookup cache to <number> entries. This is an LRU cache which reminds previous lookups and their results. It is used by ACLs and maps on slow pattern lookups, namely the ones using the "sub", "reg", "dir", "dom", "end", "bin" match methods as well as the case-insensitive strings. It applies to pattern expressions which means that it will be able to memorize the result of a lookup among all the patterns specified on a configuration line (including all those loaded from files). It automatically invalidates entries which are updated using HTTP actions or on the CLI. The default cache size is set to 10000 entries, which limits its footprint to about 5 MB per process/thread on 32-bit systems and 8 MB per process/thread on 64-bit systems, as caches are thread/process local. There is a very low risk of collision in this cache, which is in the order of the size of the cache divided by 2^64. Typically, at 10000 requests per second with the default cache size of 10000 entries, there's 1% chance that a brute force attack could cause a single collision after 60 years, or 0.1% after 6 years. This is considered much lower than the risk of a memory corruption caused by aging components. If this is not acceptable, the cache can be disabled by setting this parameter to 0.
Sets the kernel pipe buffer size to this size (in bytes). By default, pipes are the default size for the system. But sometimes when using TCP splicing, it can improve performance to increase pipe sizes, especially if it is suspected that pipes are not filled and that many calls to splice() are performed. This has an impact on the kernel's memory footprint, so this must not be changed if impacts are not understood.
This setting sets the max number of file descriptors (in percentage) used by haproxy globally against the maximum number of file descriptors haproxy can use before we start killing idle connections when we can't reuse a connection and we have to create a new one. The default is 25 (one quarter of the file descriptor will mean that roughly half of the maximum front connections can keep an idle connection behind, anything beyond this probably doesn't make much sense in the general case when targeting connection reuse).
This setting sets the max number of file descriptors (in percentage) used by haproxy globally against the maximum number of file descriptors haproxy can use before we stop putting connection into the idle pool for reuse. The default is 20.
Forces the kernel socket receive buffer size on the client or the server side to the specified value in bytes. This value applies to all TCP/HTTP frontends and backends. It should normally never be set, and the default size (0) lets the kernel auto-tune this value depending on the amount of available memory. However it can sometimes help to set it to very low values (e.g. 4096) in order to save kernel memory by preventing it from buffering too large amounts of received data. Lower values will significantly increase CPU usage though.
HAProxy uses some hints to detect that a short read indicates the end of the socket buffers. One of them is that a read returns more than <recv_enough> bytes, which defaults to 10136 (7 segments of 1448 each). This default value may be changed by this setting to better deal with workloads involving lots of short messages such as telnet or SSH sessions.
Sets the maximum amount of task that can be processed at once when running tasks. The default value is 200. Increasing it may incur latency when dealing with I/Os, making it too small can incur extra overhead.
Forces the kernel socket send buffer size on the client or the server side to the specified value in bytes. This value applies to all TCP/HTTP frontends and backends. It should normally never be set, and the default size (0) lets the kernel auto-tune this value depending on the amount of available memory. However it can sometimes help to set it to very low values (e.g. 4096) in order to save kernel memory by preventing it from buffering too large amounts of received data. Lower values will significantly increase CPU usage though. Another use case is to prevent write timeouts with extremely slow clients due to the kernel waiting for a large part of the buffer to be read before notifying haproxy again.
Sets the size of the global SSL session cache, in a number of blocks. A block
is large enough to contain an encoded session without peer certificate.
An encoded session with peer certificate is stored in multiple blocks
depending on the size of the peer certificate. A block uses approximately
200 bytes of memory. The default value may be forced at build time, otherwise
defaults to 20000. When the cache is full, the most idle entries are purged
and reassigned. Higher values reduce the occurrence of such a purge, hence
the number of CPU-intensive SSL handshakes by ensuring that all users keep
their session as long as possible. All entries are pre-allocated upon startup
and are shared between all processes if "nbproc" is greater than 1. Setting
this value to 0 disables the SSL session cache.
This option disables SSL session cache sharing between all processes. It should normally not be used since it will force many renegotiations due to clients hitting a random process. But it may be required on some operating systems where none of the SSL cache synchronization method may be used. In this case, adding a first layer of hash-based load balancing before the SSL layer might limit the impact of the lack of session sharing.
Sets how long a cached SSL session may remain valid. This time is expressed in seconds and defaults to 300 (5 min). It is important to understand that it does not guarantee that sessions will last that long, because if the cache is full, the longest idle sessions will be purged despite their configured lifetime. The real usefulness of this setting is to prevent sessions from being used for too long.
Sets the maximum amount of bytes passed to SSL_write() at a time. Default value 0 means there is no limit. Over SSL/TLS, the client can decipher the data only once it has received a full record. With large records, it means that clients might have to download up to 16kB of data before starting to process them. Limiting the value can improve page load times on browsers located over high latency or low bandwidth networks. It is suggested to find optimal values which fit into 1 or 2 TCP segments (generally 1448 bytes over Ethernet with TCP timestamps enabled, or 1460 when timestamps are disabled), keeping in mind that SSL/TLS add some overhead. Typical values of 1419 and 2859 gave good results during tests. Use "strace -e trace=write" to find the best value. HAProxy will automatically switch to this setting after an idle stream has been detected (see tune.idletimer above).
Sets the maximum size of the Diffie-Hellman parameters used for generating the ephemeral/temporary Diffie-Hellman key in case of DHE key exchange. The final size will try to match the size of the server's RSA (or DSA) key (e.g, a 2048 bits temporary DH key for a 2048 bits RSA key), but will not exceed this maximum value. Default value if 1024. Only 1024 or higher values are allowed. Higher values will increase the CPU load, and values greater than 1024 bits are not supported by Java 7 and earlier clients. This value is not used if static Diffie-Hellman parameters are supplied either directly in the certificate file or by using the ssl-dh-param-file parameter.
Sets the size of the cache used to store generated certificates to <number> entries. This is a LRU cache. Because generating a SSL certificate dynamically is expensive, they are cached. The default cache size is set to 1000 entries.
Sets the maximum size of the buffer used for capturing client-hello cipher list. If the value is 0 (default value) the capture is disabled, otherwise a buffer is allocated for each SSL/TLS connection.
These five tunes help to manage the maximum amount of memory used by the variables system. "global" limits the overall amount of memory available for all scopes. "proc" limits the memory for the process scope, "sess" limits the memory for the session scope, "txn" for the transaction scope, and "reqres" limits the memory for each request or response processing. Memory accounting is hierarchical, meaning more coarse grained limits include the finer grained ones: "proc" includes "sess", "sess" includes "txn", and "txn" includes "reqres". For example, when "tune.vars.sess-max-size" is limited to 100, "tune.vars.txn-max-size" and "tune.vars.reqres-max-size" cannot exceed 100 either. If we create a variable "txn.var" that contains 100 bytes, all available space is consumed. Notice that exceeding the limits at runtime will not result in an error message, but values might be cut off or corrupted. So make sure to accurately plan for the amount of space needed to store all your variables.
Sets the memLevel parameter in zlib initialization for each session. It defines how much memory should be allocated for the internal compression state. A value of 1 uses minimum memory but is slow and reduces compression ratio, a value of 9 uses maximum memory for optimal speed. Can be a value between 1 and 9. The default value is 8.
Sets the window size (the size of the history buffer) as a parameter of the zlib initialization for each session. Larger values of this parameter result in better compression at the expense of memory usage. Can be a value between 8 and 15. The default value is 15.
Enables debug mode which dumps to stdout all exchanges, and disables forking into background. It is the equivalent of the command-line argument "-d". It should never be used in a production configuration since it may prevent full system startup.
Do not display any message during startup. It is equivalent to the command- line argument "-q".
It is possible to control access to frontend/backend/listen sections or to http stats by allowing only authenticated and authorized users. To do this, it is required to create at least one userlist and to define users.
Creates new userlist with name <listname>. Many independent userlists can be used to store authentication & authorization data for independent customers.
Adds group <groupname> to the current userlist. It is also possible to attach users to this group by using a comma separated list of names proceeded by "users" keyword.
Adds user <username> to the current userlist. Both secure (encrypted) and insecure (unencrypted) passwords can be used. Encrypted passwords are evaluated using the crypt(3) function, so depending on the system's capabilities, different algorithms are supported. For example, modern Glibc based Linux systems support MD5, SHA-256, SHA-512, and, of course, the classic DES-based method of encrypting passwords. Attention: Be aware that using encrypted passwords might cause significantly increased CPU usage, depending on the number of requests, and the algorithm used. For any of the hashed variants, the password for each request must be processed through the chosen algorithm, before it can be compared to the value specified in the config file. Most current algorithms are deliberately designed to be expensive to compute to achieve resistance against brute force attacks. They do not simply salt/hash the clear text password once, but thousands of times. This can quickly become a major factor in haproxy's overall CPU consumption!
userlist L1
group G1 users tiger,scott
group G2 users xdb,scott
user tiger password $6$k6y3o.eP$JlKBx9za9667qe4(...)xHSwRv6J.C0/D7cV91
user scott insecure-password elgato
user xdb insecure-password hello
userlist L2
group G1
group G2
user tiger password $6$k6y3o.eP$JlKBx(...)xHSwRv6J.C0/D7cV91 groups G1
user scott insecure-password elgato groups G1,G2
user xdb insecure-password hello groups G2
Please note that both lists are functionally identical.
It is possible to propagate entries of any data-types in stick-tables between several haproxy instances over TCP connections in a multi-master fashion. Each instance pushes its local updates and insertions to remote peers. The pushed values overwrite remote ones without aggregation. Interrupted exchanges are automatically detected and recovered from the last known point. In addition, during a soft restart, the old process connects to the new one using such a TCP connection to push all its entries before the new process tries to connect to other peers. That ensures very fast replication during a reload, it typically takes a fraction of a second even for large tables. Note that Server IDs are used to identify servers remotely, so it is important that configurations look similar or at least that the same IDs are forced on each server on all participants.
Creates a new peer list with name <peersect>. It is an independent section, which is referenced by one or more stick-tables.
Defines the binding parameters of the local peer of this "peers" section. Such lines are not supported with "peer" line in the same "peers" section.
Disables a peers section. It disables both listening and any synchronization related to this section. This is provided to disable synchronization of stick tables without having to comment out all "peers" references.
Defines the binding parameters for the local peer, excepted its address.
Change default options for a server in a "peers" section.
<param*> is a list of parameters for this server. The "default-server" keyword accepts an important number of options and has a complete section dedicated to it. Please refer to section 5 for more details.
This re-enables a disabled peers section which was previously disabled.
"peers" sections support the same "log" keyword as for the proxies to log information about the "peers" listener. See "log" option for proxies for more details.
Defines a peer inside a peers section. If <peername> is set to the local peer name (by default hostname, or forced using "-L" command line option), haproxy will listen for incoming remote peer connection on <ip>:<port>. Otherwise, <ip>:<port> defines where to connect to to join the remote peer, and <peername> is used at the protocol level to identify and validate the remote peer on the server side. During a soft restart, local peer <ip>:<port> is used by the old instance to connect the new one and initiate a complete replication (teaching process). It is strongly recommended to have the exact same peers declaration on all peers and to only rely on the "-L" command line argument to change the local peer name. This makes it easier to maintain coherent configuration files across all peers. You may want to reference some environment variables in the address parameter, see section 2.3 about environment variables. Note: "peer" keyword may transparently be replaced by "server" keyword (see "server" keyword explanation below).
As previously mentioned, "peer" keyword may be replaced by "server" keyword with a support for all "server" parameters found in 5.2 paragraph. If the underlying peer is local, <ip>:<port> parameters must not be present. These parameters must be provided on a "bind" line (see "bind" keyword of this "peers" section). Some of these parameters are irrelevant for "peers" sections.
# The old way.
peers mypeers
peer haproxy1 192.168.0.1:1024
peer haproxy2 192.168.0.2:1024
peer haproxy3 10.2.0.1:1024
backend mybackend
mode tcp
balance roundrobin
stick-table type ip size 20k peers mypeers
stick on src
server srv1 192.168.0.30:80
server srv2 192.168.0.31:80
Example:
peers mypeers
bind 127.0.0.11:10001 ssl crt mycerts/pem
default-server ssl verify none
server hostA 127.0.0.10:10000
server hostB #local peer
Configure a stickiness table for the current section. This line is parsed exactly the same way as the "stick-table" keyword in others section, except for the "peers" argument which is not required here and with an additional mandatory first parameter to designate the stick-table. Contrary to others sections, there may be several "table" lines in "peers" sections (see also "stick-table" keyword). Also be aware of the fact that "peers" sections have their own stick-table namespaces to avoid collisions between stick-table names identical in different "peers" section. This is internally handled prepending the "peers" sections names to the name of the stick-tables followed by a '/' character. If somewhere else in the configuration file you have to refer to such stick-tables declared in "peers" sections you must use the prefixed version of the stick-table name as follows: peers mypeers peer A ... peer B ... table t1 ... frontend fe1 tcp-request content track-sc0 src table mypeers/t1 This is also this prefixed version of the stick-table names which must be used to refer to stick-tables through the CLI. About "peers" protocol, as only "peers" belonging to the same section may communicate with each others, there is no need to do such a distinction. Several "peers" sections may declare stick-tables with the same name. This is shorter version of the stick-table name which is sent over the network. There is only a '/' character as prefix to avoid stick-table name collisions between stick-tables declared as backends and stick-table declared in "peers" sections as follows in this weird but supported configuration: peers mypeers peer A ... peer B ... table t1 type string size 10m store gpc0 backend t1 stick-table type string size 10m store gpc0 peers mypeers Here "t1" table declared in "mypeeers" section has "mypeers/t1" as global name. "t1" table declared as a backend as "t1" as global name. But at peer protocol level the former table is named "/t1", the latter is again named "t1".
It is possible to send email alerts when the state of servers changes. If configured email alerts are sent to each mailer that is configured in a mailers section. Email is sent to mailers using SMTP.
Creates a new mailer list with the name <mailersect>. It is an independent section which is referenced by one or more proxies.
Defines a mailer inside a mailers section.
mailers mymailers
mailer smtp1 192.168.0.1:587
mailer smtp2 192.168.0.2:587
backend mybackend
mode tcp
balance roundrobin
email-alert mailers mymailers
email-alert from test1@horms.org
email-alert to test2@horms.org
server srv1 192.168.0.30:80
server srv2 192.168.0.31:80
Defines the time available for a mail/connection to be made and send to the mail-server. If not defined the default value is 10 seconds. To allow for at least two SYN-ACK packets to be send during initial TCP handshake it is advised to keep this value above 4 seconds.
mailers mymailers
timeout mail 20s
mailer smtp1 192.168.0.1:587
In master-worker mode, it is possible to launch external binaries with the master, these processes are called programs. These programs are launched and managed the same way as the workers. During a reload of HAProxy, those processes are dealing with the same sequence as a worker: - the master is re-executed - the master sends a SIGUSR1 signal to the program - if "option start-on-reload" is not disabled, the master launches a new instance of the program During a stop, or restart, a SIGTERM is sent to the programs.
This is a new program section, this section will create an instance <name> which is visible in "show proc" on the master CLI. (See "9.4. Master CLI" in the management guide).
Define the command to start with optional arguments. The command is looked up in the current PATH if it does not include an absolute path. This is a mandatory option of the program section. Arguments containing spaces must be enclosed in quotes or double quotes or be prefixed by a backslash.
Changes the executed command user ID to the <user name> from /etc/passwd.
See also "group".
Changes the executed command group ID to the <group name> from /etc/group.
See also "user".
Start (or not) a new instance of the program upon a reload of the master. The default is to start a new instance. This option may only be used in a program section.
Proxy configuration can be located in a set of sections : - defaults [<name>] - frontend <name> - backend <name> - listen <name> A "defaults" section sets default parameters for all other sections following its declaration. Those default parameters are reset by the next "defaults" section. See below for the list of parameters which can be set in a "defaults" section. The name is optional but its use is encouraged for better readability. A "frontend" section describes a set of listening sockets accepting client connections. A "backend" section describes a set of servers to which the proxy will connect to forward incoming connections. A "listen" section defines a complete proxy with its frontend and backend parts combined in one section. It is generally useful for TCP-only traffic. All proxy names must be formed from upper and lower case letters, digits, '-' (dash), '_' (underscore) , '.' (dot) and ':' (colon). ACL names are case-sensitive, which means that "www" and "WWW" are two different proxies. Historically, all proxy names could overlap, it just caused troubles in the logs. Since the introduction of content switching, it is mandatory that two proxies with overlapping capabilities (frontend/backend) have different names. However, it is still permitted that a frontend and a backend share the same name, as this configuration seems to be commonly encountered. Right now, two major proxy modes are supported : "tcp", also known as layer 4, and "http", also known as layer 7. In layer 4 mode, HAProxy simply forwards bidirectional traffic between two sides. In layer 7 mode, HAProxy analyzes the protocol, and can interact with it by allowing, blocking, switching, adding, modifying, or removing arbitrary contents in requests or responses, based on arbitrary criteria. In HTTP mode, the processing applied to requests and responses flowing over a connection depends in the combination of the frontend's HTTP options and the backend's. HAProxy supports 3 connection modes : - KAL : keep alive ("option http-keep-alive") which is the default mode : all requests and responses are processed, and connections remain open but idle between responses and new requests. - SCL: server close ("option http-server-close") : the server-facing connection is closed after the end of the response is received, but the client-facing connection remains open. - CLO: close ("option httpclose"): the connection is closed after the end of the response and "Connection: close" appended in both directions. The effective mode that will be applied to a connection passing through a frontend and a backend can be determined by both proxy modes according to the following matrix, but in short, the modes are symmetric, keep-alive is the weakest option and close is the strongest. Backend mode | KAL | SCL | CLO ----+-----+-----+---- KAL | KAL | SCL | CLO ----+-----+-----+---- mode SCL | SCL | SCL | CLO ----+-----+-----+---- CLO | CLO | CLO | CLO
The following list of keywords is supported. Most of them may only be used in a limited set of section types. Some of them are marked as "deprecated" because they are inherited from an old syntax which may be confusing or functionally limited, and there are new recommended keywords to replace them. Keywords marked with "(*)" can be optionally inverted using the "no" prefix, e.g. "no option contstats". This makes sense when the option has been enabled by default and must be disabled for a specific instance. Such options may also be prefixed with "default" in order to restore default settings regardless of what has been specified in a previous "defaults" section.
This section provides a description of each keyword and its usage.
Declare or complete an access list.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
acl invalid_src src 0.0.0.0/7 224.0.0.0/3
acl invalid_src src_port 0:1023
acl local_dst hdr(host) -i localhost
See section 7 about ACL usage.
Give hints to the system about the approximate listen backlog desired size
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<conns> is the number of pending connections. Depending on the operating system, it may represent the number of already acknowledged connections, of non-acknowledged ones, or both.
In order to protect against SYN flood attacks, one solution is to increase the system's SYN backlog size. Depending on the system, sometimes it is just tunable via a system parameter, sometimes it is not adjustable at all, and sometimes the system relies on hints given by the application at the time of the listen() syscall. By default, HAProxy passes the frontend's maxconn value to the listen() syscall. On systems which can make use of this value, it can sometimes be useful to be able to specify a different value, hence this backlog parameter. On Linux 2.4, the parameter is ignored by the system. On Linux 2.6, it is used as a hint and the system accepts up to the smallest greater power of two, and never more than some limits (usually 32768).
Define the load balancing algorithm to be used in a backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<algorithm> is the algorithm used to select a server when doing load balancing. This only applies when no persistence information is available, or when a connection is redispatched to another server. <algorithm> may be one of the following : roundrobin Each server is used in turns, according to their weights. This is the smoothest and fairest algorithm when the server's processing time remains equally distributed. This algorithm is dynamic, which means that server weights may be adjusted on the fly for slow starts for instance. It is limited by design to 4095 active servers per backend. Note that in some large farms, when a server becomes up after having been down for a very short time, it may sometimes take a few hundreds requests for it to be re-integrated into the farm and start receiving traffic. This is normal, though very rare. It is indicated here in case you would have the chance to observe it, so that you don't worry. static-rr Each server is used in turns, according to their weights. This algorithm is as similar to roundrobin except that it is static, which means that changing a server's weight on the fly will have no effect. On the other hand, it has no design limitation on the number of servers, and when a server goes up, it is always immediately reintroduced into the farm, once the full map is recomputed. It also uses slightly less CPU to run (around -1%). leastconn The server with the lowest number of connections receives the connection. Round-robin is performed within groups of servers of the same load to ensure that all servers will be used. Use of this algorithm is recommended where very long sessions are expected, such as LDAP, SQL, TSE, etc... but is not very well suited for protocols using short sessions such as HTTP. This algorithm is dynamic, which means that server weights may be adjusted on the fly for slow starts for instance. first The first server with available connection slots receives the connection. The servers are chosen from the lowest numeric identifier to the highest (see server parameter "id"), which defaults to the server's position in the farm. Once a server reaches its maxconn value, the next server is used. It does not make sense to use this algorithm without setting maxconn. The purpose of this algorithm is to always use the smallest number of servers so that extra servers can be powered off during non-intensive hours. This algorithm ignores the server weight, and brings more benefit to long session such as RDP or IMAP than HTTP, though it can be useful there too. In order to use this algorithm efficiently, it is recommended that a cloud controller regularly checks server usage to turn them off when unused, and regularly checks backend queue to turn new servers on when the queue inflates. Alternatively, using "http-check send-state" may inform servers on the load. source The source IP address is hashed and divided by the total weight of the running servers to designate which server will receive the request. This ensures that the same client IP address will always reach the same server as long as no server goes down or up. If the hash result changes due to the number of running servers changing, many clients will be directed to a different server. This algorithm is generally used in TCP mode where no cookie may be inserted. It may also be used on the Internet to provide a best-effort stickiness to clients which refuse session cookies. This algorithm is static by default, which means that changing a server's weight on the fly will have no effect, but this can be changed using "hash-type". uri This algorithm hashes either the left part of the URI (before the question mark) or the whole URI (if the "whole" parameter is present) and divides the hash value by the total weight of the running servers. The result designates which server will receive the request. This ensures that the same URI will always be directed to the same server as long as no server goes up or down. This is used with proxy caches and anti-virus proxies in order to maximize the cache hit rate. Note that this algorithm may only be used in an HTTP backend. This algorithm is static by default, which means that changing a server's weight on the fly will have no effect, but this can be changed using "hash-type". This algorithm supports two optional parameters "len" and "depth", both followed by a positive integer number. These options may be helpful when it is needed to balance servers based on the beginning of the URI only. The "len" parameter indicates that the algorithm should only consider that many characters at the beginning of the URI to compute the hash. Note that having "len" set to 1 rarely makes sense since most URIs start with a leading "/". The "depth" parameter indicates the maximum directory depth to be used to compute the hash. One level is counted for each slash in the request. If both parameters are specified, the evaluation stops when either is reached. A "path-only" parameter indicates that the hashing key starts at the first '/' of the path. This can be used to ignore the authority part of absolute URIs, and to make sure that HTTP/1 and HTTP/2 URIs will provide the same hash. url_param The URL parameter specified in argument will be looked up in the query string of each HTTP GET request. If the modifier "check_post" is used, then an HTTP POST request entity will be searched for the parameter argument, when it is not found in a query string after a question mark ('?') in the URL. The message body will only start to be analyzed once either the advertised amount of data has been received or the request buffer is full. In the unlikely event that chunked encoding is used, only the first chunk is scanned. Parameter values separated by a chunk boundary, may be randomly balanced if at all. This keyword used to support an optional <max_wait> parameter which is now ignored. If the parameter is found followed by an equal sign ('=') and a value, then the value is hashed and divided by the total weight of the running servers. The result designates which server will receive the request. This is used to track user identifiers in requests and ensure that a same user ID will always be sent to the same server as long as no server goes up or down. If no value is found or if the parameter is not found, then a round robin algorithm is applied. Note that this algorithm may only be used in an HTTP backend. This algorithm is static by default, which means that changing a server's weight on the fly will have no effect, but this can be changed using "hash-type". hdr(<name>) The HTTP header <name> will be looked up in each HTTP request. Just as with the equivalent ACL 'hdr()' function, the header name in parenthesis is not case sensitive. If the header is absent or if it does not contain any value, the roundrobin algorithm is applied instead. An optional 'use_domain_only' parameter is available, for reducing the hash algorithm to the main domain part with some specific headers such as 'Host'. For instance, in the Host value "haproxy.1wt.eu", only "1wt" will be considered. This algorithm is static by default, which means that changing a server's weight on the fly will have no effect, but this can be changed using "hash-type". random random(<draws>) A random number will be used as the key for the consistent hashing function. This means that the servers' weights are respected, dynamic weight changes immediately take effect, as well as new server additions. Random load balancing can be useful with large farms or when servers are frequently added or removed as it may avoid the hammering effect that could result from roundrobin or leastconn in this situation. The hash-balance-factor directive can be used to further improve fairness of the load balancing, especially in situations where servers show highly variable response times. When an argument <draws> is present, it must be an integer value one or greater, indicating the number of draws before selecting the least loaded of these servers. It was indeed demonstrated that picking the least loaded of two servers is enough to significantly improve the fairness of the algorithm, by always avoiding to pick the most loaded server within a farm and getting rid of any bias that could be induced by the unfair distribution of the consistent list. Higher values N will take away N-1 of the highest loaded servers at the expense of performance. With very high values, the algorithm will converge towards the leastconn's result but much slower. The default value is 2, which generally shows very good distribution and performance. This algorithm is also known as the Power of Two Random Choices and is described here : http://www.eecs.harvard.edu/~michaelm/postscripts/handbook2001.pdf rdp-cookie rdp-cookie(<name>) The RDP cookie <name> (or "mstshash" if omitted) will be looked up and hashed for each incoming TCP request. Just as with the equivalent ACL 'req_rdp_cookie()' function, the name is not case-sensitive. This mechanism is useful as a degraded persistence mode, as it makes it possible to always send the same user (or the same session ID) to the same server. If the cookie is not found, the normal roundrobin algorithm is used instead. Note that for this to work, the frontend must ensure that an RDP cookie is already present in the request buffer. For this you must use 'tcp-request content accept' rule combined with a 'req_rdp_cookie_cnt' ACL. This algorithm is static by default, which means that changing a server's weight on the fly will have no effect, but this can be changed using "hash-type". See also the rdp_cookie pattern fetch function. <arguments> is an optional list of arguments which may be needed by some algorithms. Right now, only "url_param" and "uri" support an optional argument.
The load balancing algorithm of a backend is set to roundrobin when no other algorithm, mode nor option have been set. The algorithm may only be set once for each backend. With authentication schemes that require the same connection like NTLM, URI based algorithms must not be used, as they would cause subsequent requests to be routed to different backend servers, breaking the invalid assumptions NTLM relies on.
balance roundrobin
balance url_param userid
balance url_param session_id check_post 64
balance hdr(User-Agent)
balance hdr(host)
balance hdr(Host) use_domain_only
Note: the following caveats and limitations on using the "check_post" extension with "url_param" must be considered : - all POST requests are eligible 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 http_end) - using a <max_wait> value larger than the request buffer size does not make sense and is useless. The buffer size is set at build time, and defaults to 16 kB. - 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 (RFC7230 3.3.1) 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. Scanning 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.
Define one or several listening addresses and/or ports in a frontend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<address> is optional and can be a host name, an IPv4 address, an IPv6 address, or '*'. It designates the address the frontend will listen on. If unset, all IPv4 addresses of the system will be listened on. The same will apply for '*' or the system's special address "0.0.0.0". The IPv6 equivalent is '::'. Optionally, an address family prefix may be used before the address to force the family regardless of the address format, which can be useful to specify a path to a unix socket with no slash ('/'). Currently supported prefixes are : - 'ipv4@' -> address is always IPv4 - 'ipv6@' -> address is always IPv6 - 'unix@' -> address is a path to a local unix socket - 'abns@' -> address is in abstract namespace (Linux only). Note: since abstract sockets are not "rebindable", they do not cope well with multi-process mode during soft-restart, so it is better to avoid them if nbproc is greater than 1. The effect is that if the new process fails to start, only one of the old ones will be able to rebind to the socket. - 'fd@<n>' -> use file descriptor <n> inherited from the parent. The fd must be bound and may or may not already be listening. - 'sockpair@<n>'-> like fd@ but you must use the fd of a connected unix socket or of a socketpair. The bind waits to receive a FD over the unix socket and uses it as if it was the FD of an accept(). Should be used carefully. You may want to reference some environment variables in the address parameter, see section 2.3 about environment variables. <port_range> is either a unique TCP port, or a port range for which the proxy will accept connections for the IP address specified above. The port is mandatory for TCP listeners. Note that in the case of an IPv6 address, the port is always the number after the last colon (':'). A range can either 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 <address:port> couple consumes one socket (= a file descriptor), so it's easy to consume lots of descriptors with a simple range, and to run out of sockets. Also, each <address:port> couple must be used only once among all instances running on a same system. Please note that binding to ports lower than 1024 generally require particular privileges to start the program, which are independent of the 'uid' parameter. <path> is a UNIX socket path beginning with a slash ('/'). This is alternative to the TCP listening port. HAProxy will then receive UNIX connections on the socket located at this place. The path must begin with a slash and by default is absolute. It can be relative to the prefix defined by "unix-bind" in the global section. Note that the total length of the prefix followed by the socket path cannot exceed some system limits for UNIX sockets, which commonly are set to 107 characters. <param*> is a list of parameters common to all sockets declared on the same line. These numerous parameters depend on OS and build options and have a complete section dedicated to them. Please refer to section 5 to for more details.
It is possible to specify a list of address:port combinations delimited by
commas. The frontend will then listen on all of these addresses. There is no
fixed limit to the number of addresses and ports which can be listened on in
a frontend, as well as there is no limit to the number of "bind" statements
in a frontend.
listen http_proxy
bind :80,:443
bind 10.0.0.1:10080,10.0.0.1:10443
bind /var/run/ssl-frontend.sock user root mode 600 accept-proxy
listen http_https_proxy
bind :80
bind :443 ssl crt /etc/haproxy/site.pem
listen http_https_proxy_explicit
bind ipv6@:80
bind ipv4@public_ssl:443 ssl crt /etc/haproxy/site.pem
bind unix@ssl-frontend.sock user root mode 600 accept-proxy
listen external_bind_app1
bind "fd@${FD_APP1}"
Note: regarding Linux's abstract namespace sockets, HAProxy uses the whole sun_path length is used for the address length. Some other programs such as socat use the string length only by default. Pass the option ",unix-tightsocklen=0" to any abstract socket definition in socat to make it compatible with HAProxy's.
Limit visibility of an instance to a certain set of processes numbers.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
all All process will see this instance. This is the default. It may be used to override a default value. odd This instance will be enabled on processes 1,3,5,...63. This option may be combined with other numbers. even This instance will be enabled on processes 2,4,6,...64. This option may be combined with other numbers. Do not use it with less than 2 processes otherwise some instances might be missing from all processes. process_num The instance will be enabled on this process number or range, whose values must all be between 1 and 32 or 64 depending on the machine's word size. Ranges can be partially defined. The higher bound can be omitted. In such case, it is replaced by the corresponding maximum value. If a proxy is bound to process numbers greater than the configured global.nbproc, it will either be forced to process #1 if a single process was specified, or to all processes otherwise.
This keyword limits binding of certain instances to certain processes. This is useful in order not to have too many processes listening to the same ports. For instance, on a dual-core machine, it might make sense to set 'nbproc 2' in the global section, then distributes the listeners among 'odd' and 'even' instances. At the moment, it is not possible to reference more than 32 or 64 processes using this keyword, but this should be more than enough for most setups. Please note that 'all' really means all processes regardless of the machine's word size, and is not limited to the first 32 or 64. Each "bind" line may further be limited to a subset of the proxy's processes, please consult the "process" bind keyword in section 5.1. When a frontend has no explicit "bind-process" line, it tries to bind to all the processes referenced by its "bind" lines. That means that frontends can easily adapt to their listeners' processes. If some backends are referenced by frontends bound to other processes, the backend automatically inherits the frontend's processes.
listen app_ip1
bind 10.0.0.1:80
bind-process odd
listen app_ip2
bind 10.0.0.2:80
bind-process even
listen management
bind 10.0.0.3:80
bind-process 1 2 3 4
listen management
bind 10.0.0.4:80
bind-process 1-4
Capture and log a cookie in the request and in the response.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<name> is the beginning of the name of the cookie to capture. In order to match the exact name, simply suffix the name with an equal sign ('='). The full name will appear in the logs, which is useful with application servers which adjust both the cookie name and value (e.g. ASPSESSIONXXX). <length> is the maximum number of characters to report in the logs, which include the cookie name, the equal sign and the value, all in the standard "name=value" form. The string will be truncated on the right if it exceeds <length>.
Only the first cookie is captured. Both the "cookie" request headers and the "set-cookie" response headers are monitored. This is particularly useful to check for application bugs causing session crossing or stealing between users, because generally the user's cookies can only change on a login page. When the cookie was not presented by the client, the associated log column will report "-". When a request does not cause a cookie to be assigned by the server, a "-" is reported in the response column. The capture is performed in the frontend only because it is necessary that the log format does not change for a given frontend depending on the backends. This may change in the future. Note that there can be only one "capture cookie" statement in a frontend. The maximum capture length is set by the global "tune.http.cookielen" setting and defaults to 63 characters. It is not possible to specify a capture in a "defaults" section.
capture cookie ASPSESSION len 32
Capture and log the last occurrence of the specified request header.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<name> is the name of the header to capture. The header names are not case-sensitive, but it is a common practice to write them as they appear in the requests, with the first letter of each word in upper case. The header name will not appear in the logs, only the value is reported, but the position in the logs is respected. <length> is the maximum number of characters to extract from the value and report in the logs. The string will be truncated on the right if it exceeds <length>.
The complete value of the last occurrence of the header is captured. The value will be added to the logs between braces ('{}'). If multiple headers are captured, they will be delimited by a vertical bar ('|') and will appear in the same order they were declared in the configuration. Non-existent headers will be logged just as an empty string. Common uses for request header captures include the "Host" field in virtual hosting environments, the "Content-length" when uploads are supported, "User-agent" to quickly differentiate between real users and robots, and "X-Forwarded-For" in proxied environments to find where the request came from. Note that when capturing headers such as "User-agent", some spaces may be logged, making the log analysis more difficult. Thus be careful about what you log if you know your log parser is not smart enough to rely on the braces. There is no limit to the number of captured request headers nor to their length, though it is wise to keep them low to limit memory usage per session. In order to keep log format consistent for a same frontend, header captures can only be declared in a frontend. It is not possible to specify a capture in a "defaults" section.
capture request header Host len 15
capture request header X-Forwarded-For len 15
capture request header Referer len 15
Capture and log the last occurrence of the specified response header.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<name> is the name of the header to capture. The header names are not case-sensitive, but it is a common practice to write them as they appear in the response, with the first letter of each word in upper case. The header name will not appear in the logs, only the value is reported, but the position in the logs is respected. <length> is the maximum number of characters to extract from the value and report in the logs. The string will be truncated on the right if it exceeds <length>.
The complete value of the last occurrence of the header is captured. The result will be added to the logs between braces ('{}') after the captured request headers. If multiple headers are captured, they will be delimited by a vertical bar ('|') and will appear in the same order they were declared in the configuration. Non-existent headers will be logged just as an empty string. Common uses for response header captures include the "Content-length" header which indicates how many bytes are expected to be returned, the "Location" header to track redirections. There is no limit to the number of captured response headers nor to their length, though it is wise to keep them low to limit memory usage per session. In order to keep log format consistent for a same frontend, header captures can only be declared in a frontend. It is not possible to specify a capture in a "defaults" section.
capture response header Content-length len 9
capture response header Location len 15
Enable HTTP compression.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
algo is followed by the list of supported compression algorithms. type is followed by the list of MIME types that will be compressed. offload makes haproxy work as a compression offloader only (see notes).
The currently supported algorithms are : identity this is mostly for debugging, and it was useful for developing the compression feature. Identity does not apply any change on data. gzip applies gzip compression. This setting is only available when support for zlib or libslz was built in. deflate same as "gzip", but with deflate algorithm and zlib format. Note that this algorithm has ambiguous support on many browsers and no support at all from recent ones. It is strongly recommended not to use it for anything else than experimentation. This setting is only available when support for zlib or libslz was built in. raw-deflate same as "deflate" without the zlib wrapper, and used as an alternative when the browser wants "deflate". All major browsers understand it and despite violating the standards, it is known to work better than "deflate", at least on MSIE and some versions of Safari. Do not use it in conjunction with "deflate", use either one or the other since both react to the same Accept-Encoding token. This setting is only available when support for zlib or libslz was built in. Compression will be activated depending on the Accept-Encoding request header. With identity, it does not take care of that header. If backend servers support HTTP compression, these directives will be no-op: haproxy will see the compressed response and will not compress again. If backend servers do not support HTTP compression and there is Accept-Encoding header in request, haproxy will compress the matching response. The "offload" setting makes haproxy remove the Accept-Encoding header to prevent backend servers from compressing responses. It is strongly recommended not to do this because this means that all the compression work will be done on the single point where haproxy is located. However in some deployment scenarios, haproxy may be installed in front of a buggy gateway with broken HTTP compression implementation which can't be turned off. In that case haproxy can be used to prevent that gateway from emitting invalid payloads. In this case, simply removing the header in the configuration does not work because it applies before the header is parsed, so that prevents haproxy from compressing. The "offload" setting should then be used for such scenarios. Note: for now, the "offload" setting is ignored when set in a defaults section. Compression is disabled when: * the request does not advertise a supported compression algorithm in the "Accept-Encoding" header * the response message is not HTTP/1.1 * HTTP status code is not one of 200, 201, 202, or 203 * response contain neither a "Content-Length" header nor a "Transfer-Encoding" whose last value is "chunked" * response contains a "Content-Type" header whose first value starts with "multipart" * the response contains the "no-transform" value in the "Cache-control" header * User-Agent matches "Mozilla/4" unless it is MSIE 6 with XP SP2, or MSIE 7 and later * The response contains a "Content-Encoding" header, indicating that the response is already compressed (see compression offload) * The response contains an invalid "ETag" header or multiple ETag headers Note: The compression does not emit the Warning header.
compression algo gzip
compression type text/html text/plain
Enable cookie-based persistence in a backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<name> is the name of the cookie which will be monitored, modified or inserted in order to bring persistence. This cookie is sent to the client via a "Set-Cookie" header in the response, and is brought back by the client in a "Cookie" header in all requests. Special care should be taken to choose a name which does not conflict with any likely application cookie. Also, if the same backends are subject to be used by the same clients (e.g. HTTP/HTTPS), care should be taken to use different cookie names between all backends if persistence between them is not desired. rewrite This keyword indicates that the cookie will be provided by the server and that haproxy will have to modify its value to set the server's identifier in it. This mode is handy when the management of complex combinations of "Set-cookie" and "Cache-control" headers is left to the application. The application can then decide whether or not it is appropriate to emit a persistence cookie. Since all responses should be monitored, this mode doesn't work in HTTP tunnel mode. Unless the application behavior is very complex and/or broken, it is advised not to start with this mode for new deployments. This keyword is incompatible with "insert" and "prefix". insert This keyword indicates that the persistence cookie will have to be inserted by haproxy in server responses if the client did not already have a cookie that would have permitted it to access this server. When used without the "preserve" option, if the server emits a cookie with the same name, it will be removed before processing. For this reason, this mode can be used to upgrade existing configurations running in the "rewrite" mode. The cookie will only be a session cookie and will not be stored on the client's disk. By default, unless the "indirect" option is added, the server will see the cookies emitted by the client. Due to caching effects, it is generally wise to add the "nocache" or "postonly" keywords (see below). The "insert" keyword is not compatible with "rewrite" and "prefix". prefix This keyword indicates that instead of relying on a dedicated cookie for the persistence, an existing one will be completed. This may be needed in some specific environments where the client does not support more than one single cookie and the application already needs it. In this case, whenever the server sets a cookie named <name>, it will be prefixed with the server's identifier and a delimiter. The prefix will be removed from all client requests so that the server still finds the cookie it emitted. Since all requests and responses are subject to being modified, this mode doesn't work with tunnel mode. The "prefix" keyword is not compatible with "rewrite" and "insert". Note: it is highly recommended not to use "indirect" with "prefix", otherwise server cookie updates would not be sent to clients. indirect When this option is specified, no cookie will be emitted to a client which already has a valid one for the server which has processed the request. If the server sets such a cookie itself, it will be removed, unless the "preserve" option is also set. In "insert" mode, this will additionally remove cookies from the requests transmitted to the server, making the persistence mechanism totally transparent from an application point of view. Note: it is highly recommended not to use "indirect" with "prefix", otherwise server cookie updates would not be sent to clients. nocache This option is recommended in conjunction with the insert mode when there is a cache between the client and HAProxy, as it ensures that a cacheable response will be tagged non-cacheable if a cookie needs to be inserted. This is important because if all persistence cookies are added on a cacheable home page for instance, then all customers will then fetch the page from an outer cache and will all share the same persistence cookie, leading to one server receiving much more traffic than others. See also the "insert" and "postonly" options. postonly This option ensures that cookie insertion will only be performed on responses to POST requests. It is an alternative to the "nocache" option, because POST responses are not cacheable, so this ensures that the persistence cookie will never get cached. Since most sites do not need any sort of persistence before the first POST which generally is a login request, this is a very efficient method to optimize caching without risking to find a persistence cookie in the cache. See also the "insert" and "nocache" options. preserve This option may only be used with "insert" and/or "indirect". It allows the server to emit the persistence cookie itself. In this case, if a cookie is found in the response, haproxy will leave it untouched. This is useful in order to end persistence after a logout request for instance. For this, the server just has to emit a cookie with an invalid value (e.g. empty) or with a date in the past. By combining this mechanism with the "disable-on-404" check option, it is possible to perform a completely graceful shutdown because users will definitely leave the server after they logout. httponly This option tells haproxy to add an "HttpOnly" cookie attribute when a cookie is inserted. This attribute is used so that a user agent doesn't share the cookie with non-HTTP components. Please check RFC6265 for more information on this attribute. secure This option tells haproxy to add a "Secure" cookie attribute when a cookie is inserted. This attribute is used so that a user agent never emits this cookie over non-secure channels, which means that a cookie learned with this flag will be presented only over SSL/TLS connections. Please check RFC6265 for more information on this attribute. domain This option allows to specify the domain at which a cookie is inserted. It requires exactly one parameter: a valid domain name. If the domain begins with a dot, the browser is allowed to use it for any host ending with that name. It is also possible to specify several domain names by invoking this option multiple times. Some browsers might have small limits on the number of domains, so be careful when doing that. For the record, sending 10 domains to MSIE 6 or Firefox 2 works as expected. maxidle This option allows inserted cookies to be ignored after some idle time. It only works with insert-mode cookies. When a cookie is sent to the client, the date this cookie was emitted is sent too. Upon further presentations of this cookie, if the date is older than the delay indicated by the parameter (in seconds), it will be ignored. Otherwise, it will be refreshed if needed when the response is sent to the client. This is particularly useful to prevent users who never close their browsers from remaining for too long on the same server (e.g. after a farm size change). When this option is set and a cookie has no date, it is always accepted, but gets refreshed in the response. This maintains the ability for admins to access their sites. Cookies that have a date in the future further than 24 hours are ignored. Doing so lets admins fix timezone issues without risking kicking users off the site. maxlife This option allows inserted cookies to be ignored after some life time, whether they're in use or not. It only works with insert mode cookies. When a cookie is first sent to the client, the date this cookie was emitted is sent too. Upon further presentations of this cookie, if the date is older than the delay indicated by the parameter (in seconds), it will be ignored. If the cookie in the request has no date, it is accepted and a date will be set. Cookies that have a date in the future further than 24 hours are ignored. Doing so lets admins fix timezone issues without risking kicking users off the site. Contrary to maxidle, this value is not refreshed, only the first visit date counts. Both maxidle and maxlife may be used at the time. This is particularly useful to prevent users who never close their browsers from remaining for too long on the same server (e.g. after a farm size change). This is stronger than the maxidle method in that it forces a redispatch after some absolute delay. dynamic Activate dynamic cookies. When used, a session cookie is dynamically created for each server, based on the IP and port of the server, and a secret key, specified in the "dynamic-cookie-key" backend directive. The cookie will be regenerated each time the IP address change, and is only generated for IPv4/IPv6. attr This option tells haproxy to add an extra attribute when a cookie is inserted. The attribute value can contain any characters except control ones or ";". This option may be repeated.
There can be only one persistence cookie per HTTP backend, and it can be declared in a defaults section. The value of the cookie will be the value indicated after the "cookie" keyword in a "server" statement. If no cookie is declared for a given server, the cookie is not set.
cookie JSESSIONID prefix
cookie SRV insert indirect nocache
cookie SRV insert postonly indirect
cookie SRV insert indirect nocache maxidle 30m maxlife 8h
Declares a capture slot.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<length> is the length allowed for the capture.
This declaration is only available in the frontend or listen section, but the reserved slot can be used in the backends. The "request" keyword allocates a capture slot for use in the request, and "response" allocates a capture slot for use in the response.
Change default options for a server in a backend
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<param*> is a list of parameters for this server. The "default-server" keyword accepts an important number of options and has a complete section dedicated to it. Please refer to section 5 for more details.
default-server inter 1000 weight 13
Specify the backend to use when no "use_backend" rule has been matched.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<backend> is the name of the backend to use.
When doing content-switching between frontend and backends using the "use_backend" keyword, it is often useful to indicate which backend will be used when no rule has matched. It generally is the dynamic backend which will catch all undetermined requests.
use_backend dynamic if url_dyn
use_backend static if url_css url_img extension_img
default_backend dynamic
Describe a listen, frontend or backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
Allows to add a sentence to describe the related object in the HAProxy HTML stats page. The description will be printed on the right of the object name it describes. No need to backslash spaces in the <string> arguments.
Disable a proxy, frontend or backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
The "disabled" keyword is used to disable an instance, mainly in order to liberate a listening port or to temporarily disable a service. The instance will still be created and its configuration will be checked, but it will be created in the "stopped" state and will appear as such in the statistics. It will not receive any traffic nor will it send any health-checks or logs. It is possible to disable many instances at once by adding the "disabled" keyword in a "defaults" section.
Set a default server address
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<address> is the IPv4 address of the default server. Alternatively, a resolvable hostname is supported, but this name will be resolved during start-up. <ports> is a mandatory port specification. All connections will be sent to this port, and it is not permitted to use port offsets as is possible with normal servers.
The "dispatch" keyword designates a default server for use when no other server can take the connection. In the past it was used to forward non persistent connections to an auxiliary load balancer. Due to its simple syntax, it has also been used for simple TCP relays. It is recommended not to use it for more clarity, and to use the "server" directive instead.
Set the dynamic cookie secret key for a backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When dynamic cookies are enabled (see the "dynamic" directive for cookie),
a dynamic cookie is created for each server (unless one is explicitly
specified on the "server" line), using a hash of the IP address of the
server, the TCP port, and the secret key.
That way, we can ensure session persistence across multiple load-balancers,
even if servers are dynamically added or removed.
Enable a proxy, frontend or backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
The "enabled" keyword is used to explicitly enable an instance, when the defaults has been set to "disabled". This is very rarely used.
Return a file contents instead of errors generated by HAProxy
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<code> is the HTTP status code. Currently, HAProxy is capable of generating codes 200, 400, 403, 404, 405, 408, 410, 413, 425, 429, 500, 502, 503, and 504. <file> designates a file containing the full HTTP response. It is recommended to follow the common practice of appending ".http" to the filename so that people do not confuse the response with HTML error pages, and to use absolute paths, since files are read before any chroot is performed.
It is important to understand that this keyword is not meant to rewrite errors returned by the server, but errors detected and returned by HAProxy. This is why the list of supported errors is limited to a small set. Code 200 is emitted in response to requests matching a "monitor-uri" rule. The files are returned verbatim on the TCP socket. This allows any trick such as redirections to another URL or site, as well as tricks to clean cookies, force enable or disable caching, etc... The package provides default error files returning the same contents as default errors. The files should not exceed the configured buffer size (BUFSIZE), which generally is 8 or 16 kB, otherwise they will be truncated. It is also wise not to put any reference to local contents (e.g. images) in order to avoid loops between the client and HAProxy when all servers are down, causing an error to be returned instead of an image. For better HTTP compliance, it is recommended that all header lines end with CR-LF and not LF alone. The files are read at the same time as the configuration and kept in memory. For this reason, the errors continue to be returned even when the process is chrooted, and no file change is considered while the process is running. A simple method for developing those files consists in associating them to the 403 status code and interrogating a blocked URL.
errorfile 400 /etc/haproxy/errorfiles/400badreq.http
errorfile 408 /dev/null # work around Chrome pre-connect bug
errorfile 403 /etc/haproxy/errorfiles/403forbid.http
errorfile 503 /etc/haproxy/errorfiles/503sorry.http
Return an HTTP redirection to a URL instead of errors generated by HAProxy
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<code> is the HTTP status code. Currently, HAProxy is capable of generating codes 200, 400, 403, 404, 405, 408, 410, 413, 425, 429, 500, 502, 503, and 504. <url> it is the exact contents of the "Location" header. It may contain either a relative URI to an error page hosted on the same site, or an absolute URI designating an error page on another site. Special care should be given to relative URIs to avoid redirect loops if the URI itself may generate the same error (e.g. 500).
It is important to understand that this keyword is not meant to rewrite errors returned by the server, but errors detected and returned by HAProxy. This is why the list of supported errors is limited to a small set. Code 200 is emitted in response to requests matching a "monitor-uri" rule. Note that both keyword return the HTTP 302 status code, which tells the client to fetch the designated URL using the same HTTP method. This can be quite problematic in case of non-GET methods such as POST, because the URL sent to the client might not be allowed for something other than GET. To work around this problem, please use "errorloc303" which send the HTTP 303 status code, indicating to the client that the URL must be fetched with a GET request.
Return an HTTP redirection to a URL instead of errors generated by HAProxy
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<code> is the HTTP status code. Currently, HAProxy is capable of generating codes 200, 400, 403, 404, 405, 408, 410, 413, 425, 429, 500, 502, 503, and 504. <url> it is the exact contents of the "Location" header. It may contain either a relative URI to an error page hosted on the same site, or an absolute URI designating an error page on another site. Special care should be given to relative URIs to avoid redirect loops if the URI itself may generate the same error (e.g. 500).
It is important to understand that this keyword is not meant to rewrite errors returned by the server, but errors detected and returned by HAProxy. This is why the list of supported errors is limited to a small set. Code 200 is emitted in response to requests matching a "monitor-uri" rule. Note that both keyword return the HTTP 303 status code, which tells the client to fetch the designated URL using the same HTTP GET method. This solves the usual problems associated with "errorloc" and the 302 code. It is possible that some very old browsers designed before HTTP/1.1 do not support it, but no such problem has been reported till now.
Declare the from email address to be used in both the envelope and header of email alerts. This is the address that email alerts are sent from.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<emailaddr> is the from email address to use when sending email alerts
Also requires "email-alert mailers" and "email-alert to" to be set and if so sending email alerts is enabled for the proxy.
Declare the maximum log level of messages for which email alerts will be sent. This acts as a filter on the sending of email alerts.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<level> One of the 8 syslog levels: emerg alert crit err warning notice info debug The above syslog levels are ordered from lowest to highest.
By default level is alert Also requires "email-alert from", "email-alert mailers" and "email-alert to" to be set and if so sending email alerts is enabled for the proxy. Alerts are sent when : * An un-paused server is marked as down and <level> is alert or lower * A paused server is marked as down and <level> is notice or lower * A server is marked as up or enters the drain state and <level> is notice or lower * "option log-health-checks" is enabled, <level> is info or lower, and a health check status update occurs
Declare the mailers to be used when sending email alerts
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<mailersect> is the name of the mailers section to send email alerts.
Also requires "email-alert from" and "email-alert to" to be set and if so sending email alerts is enabled for the proxy.
Declare the to hostname address to be used when communicating with mailers.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<hostname> is the hostname to use when communicating with mailers
By default the systems hostname is used. Also requires "email-alert from", "email-alert mailers" and "email-alert to" to be set and if so sending email alerts is enabled for the proxy.
Declare both the recipient address in the envelope and to address in the header of email alerts. This is the address that email alerts are sent to.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<emailaddr> is the to email address to use when sending email alerts
Also requires "email-alert mailers" and "email-alert to" to be set and if so sending email alerts is enabled for the proxy.
Declare a condition to force persistence on down servers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
By default, requests are not dispatched to down servers. It is possible to force this using "option persist", but it is unconditional and redispatches to a valid server if "option redispatch" is set. That leaves with very little possibilities to force some requests to reach a server which is artificially marked down for maintenance operations. The "force-persist" statement allows one to declare various ACL-based conditions which, when met, will cause a request to ignore the down status of a server and still try to connect to it. That makes it possible to start a server, still replying an error to the health checks, and run a specially configured browser to test the service. Among the handy methods, one could use a specific source IP address, or a specific cookie. The cookie also has the advantage that it can easily be added/removed on the browser from a test page. Once the service is validated, it is then possible to open the service to the world by returning a valid response to health checks. The forced persistence is enabled when an "if" condition is met, or unless an "unless" condition is met. The final redispatch is always disabled when this is used.
Add the filter <name> in the filter list attached to the proxy.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
<name> is the name of the filter. Officially supported filters are referenced in section 9. <param*> is a list of parameters accepted by the filter <name>. The parsing of these parameters are the responsibility of the filter. Please refer to the documentation of the corresponding filter (section 9) for all details on the supported parameters.
Multiple occurrences of the filter line can be used for the same proxy. The same filter can be referenced many times if needed.
listen
bind *:80
filter trace name BEFORE-HTTP-COMP
filter compression
filter trace name AFTER-HTTP-COMP
compression algo gzip
compression offload
server srv1 192.168.0.1:80
Specify at what backend load the servers will reach their maxconn
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<conns> is the number of connections on the backend which will make the servers use the maximal number of connections.
When a server has a "maxconn" parameter specified, it means that its number of concurrent connections will never go higher. Additionally, if it has a "minconn" parameter, it indicates a dynamic limit following the backend's load. The server will then always accept at least <minconn> connections, never more than <maxconn>, and the limit will be on the ramp between both values when the backend has less than <conns> concurrent connections. This makes it possible to limit the load on the servers during normal loads, but push it further for important loads without overloading the servers during exceptional loads. Since it's hard to get this value right, haproxy automatically sets it to 10% of the sum of the maxconns of all frontends that may branch to this backend (based on "use_backend" and "default_backend" rules). That way it's safe to leave it unset. However, "use_backend" involving dynamic names are not counted since there is no way to know if they could match or not.
# The servers will accept between 100 and 1000 concurrent connections each
# and the maximum of 1000 will be reached when the backend reaches 10000
# connections.
backend dynamic
fullconn 10000
server srv1 dyn1:80 minconn 100 maxconn 1000
server srv2 dyn2:80 minconn 100 maxconn 1000
Maintain a proxy operational for some time after a soft stop
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<time> is the time (by default in milliseconds) for which the instance will remain operational with the frontend sockets still listening when a soft-stop is received via the SIGUSR1 signal.
This may be used to ensure that the services disappear in a certain order. This was designed so that frontends which are dedicated to monitoring by an external equipment fail immediately while other ones remain up for the time needed by the equipment to detect the failure. Note that currently, there is very little benefit in using this parameter, and it may in fact complicate the soft-reconfiguration process more than simplify it.
Specify the balancing factor for bounded-load consistent hashing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | no | yes |
<factor> is the control for the maximum number of concurrent requests to send to a server, expressed as a percentage of the average number of concurrent requests across all of the active servers.
Specifying a "hash-balance-factor" for a server with "hash-type consistent" enables an algorithm that prevents any one server from getting too many requests at once, even if some hash buckets receive many more requests than others. Setting <factor> to 0 (the default) disables the feature. Otherwise, <factor> is a percentage greater than 100. For example, if <factor> is 150, then no server will be allowed to have a load more than 1.5 times the average. If server weights are used, they will be respected. If the first-choice server is disqualified, the algorithm will choose another server based on the request hash, until a server with additional capacity is found. A higher <factor> allows more imbalance between the servers, while a lower <factor> means that more servers will be checked on average, affecting performance. Reasonable values are from 125 to 200. This setting is also used by "balance random" which internally relies on the consistent hashing mechanism.
Specify a method to use for mapping hashes to servers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<method> is the method used to select a server from the hash computed by the <function> : map-based the hash table is a static array containing all alive servers. The hashes will be very smooth, will consider weights, but will be static in that weight changes while a server is up will be ignored. This means that there will be no slow start. Also, since a server is selected by its position in the array, most mappings are changed when the server count changes. This means that when a server goes up or down, or when a server is added to a farm, most connections will be redistributed to different servers. This can be inconvenient with caches for instance. consistent the hash table is a tree filled with many occurrences of each server. The hash key is looked up in the tree and the closest server is chosen. This hash is dynamic, it supports changing weights while the servers are up, so it is compatible with the slow start feature. It has the advantage that when a server goes up or down, only its associations are moved. When a server is added to the farm, only a few part of the mappings are redistributed, making it an ideal method for caches. However, due to its principle, the distribution will never be very smooth and it may sometimes be necessary to adjust a server's weight or its ID to get a more balanced distribution. In order to get the same distribution on multiple load balancers, it is important that all servers have the exact same IDs. Note: consistent hash uses sdbm and avalanche if no hash function is specified. <function> is the hash function to be used : sdbm this function was created initially for sdbm (a public-domain reimplementation of ndbm) database library. It was found to do well in scrambling bits, causing better distribution of the keys and fewer splits. It also happens to be a good general hashing function with good distribution, unless the total server weight is a multiple of 64, in which case applying the avalanche modifier may help. djb2 this function was first proposed by Dan Bernstein many years ago on comp.lang.c. Studies have shown that for certain workload this function provides a better distribution than sdbm. It generally works well with text-based inputs though it can perform extremely poorly with numeric-only input or when the total server weight is a multiple of 33, unless the avalanche modifier is also used. wt6 this function was designed for haproxy while testing other functions in the past. It is not as smooth as the other ones, but is much less sensible to the input data set or to the number of servers. It can make sense as an alternative to sdbm+avalanche or djb2+avalanche for consistent hashing or when hashing on numeric data such as a source IP address or a visitor identifier in a URL parameter. crc32 this is the most common CRC32 implementation as used in Ethernet, gzip, PNG, etc. It is slower than the other ones but may provide a better distribution or less predictable results especially when used on strings. <modifier> indicates an optional method applied after hashing the key : avalanche This directive indicates that the result from the hash function above should not be used in its raw form but that a 4-byte full avalanche hash must be applied first. The purpose of this step is to mix the resulting bits from the previous hash in order to avoid any undesired effect when the input contains some limited values or when the number of servers is a multiple of one of the hash's components (64 for SDBM, 33 for DJB2). Enabling avalanche tends to make the result less predictable, but it's also not as smooth as when using the original function. Some testing might be needed with some workloads. This hash is one of the many proposed by Bob Jenkins.
The default hash type is "map-based" and is recommended for most usages. The default function is "sdbm", the selection of a function should be based on the range of the values being hashed.
Enable a maintenance mode upon HTTP/404 response to health-checks
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When this option is set, a server which returns an HTTP code 404 will be excluded from further load-balancing, but will still receive persistent connections. This provides a very convenient method for Web administrators to perform a graceful shutdown of their servers. It is also important to note that a server which is detected as failed while it was in this mode will not generate an alert, just a notice. If the server responds 2xx or 3xx again, it will immediately be reinserted into the farm. The status on the stats page reports "NOLB" for a server in this mode. It is important to note that this option only works in conjunction with the "httpchk" option. If this option is used with "http-check expect", then it has precedence over it so that 404 responses will still be considered as soft-stop.
Make HTTP health checks consider response contents or specific status codes
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<match> is a keyword indicating how to look for a specific pattern in the response. The keyword may be one of "status", "rstatus", "string", or "rstring". The keyword may be preceded by an exclamation mark ("!") to negate the match. Spaces are allowed between the exclamation mark and the keyword. See below for more details on the supported keywords. <pattern> is the pattern to look for. It may be a string or a regular expression. If the pattern contains spaces, they must be escaped with the usual backslash ('\').
By default, "option httpchk" considers that response statuses 2xx and 3xx are valid, and that others are invalid. When "http-check expect" is used, it defines what is considered valid or invalid. Only one "http-check" statement is supported in a backend. If a server fails to respond or times out, the check obviously fails. The available matches are : status <string> : test the exact string match for the HTTP status code. A health check response will be considered valid if the response's status code is exactly this string. If the "status" keyword is prefixed with "!", then the response will be considered invalid if the status code matches. rstatus <regex> : test a regular expression for the HTTP status code. A health check response will be considered valid if the response's status code matches the expression. If the "rstatus" keyword is prefixed with "!", then the response will be considered invalid if the status code matches. This is mostly used to check for multiple codes. string <string> : test the exact string match in the HTTP response body. A health check response will be considered valid if the response's body contains this exact string. If the "string" keyword is prefixed with "!", then the response will be considered invalid if the body contains this string. This can be used to look for a mandatory word at the end of a dynamic page, or to detect a failure when a specific error appears on the check page (e.g. a stack trace). rstring <regex> : test a regular expression on the HTTP response body. A health check response will be considered valid if the response's body matches this expression. If the "rstring" keyword is prefixed with "!", then the response will be considered invalid if the body matches the expression. This can be used to look for a mandatory word at the end of a dynamic page, or to detect a failure when a specific error appears on the check page (e.g. a stack trace). It is important to note that the responses will be limited to a certain size defined by the global "tune.chksize" option, which defaults to 16384 bytes. Thus, too large responses may not contain the mandatory pattern when using "string" or "rstring". If a large response is absolutely required, it is possible to change the default max size by setting the global variable. However, it is worth keeping in mind that parsing very large responses can waste some CPU cycles, especially when regular expressions are used, and that it is always better to focus the checks on smaller resources. Also "http-check expect" doesn't support HTTP keep-alive. Keep in mind that it will automatically append a "Connection: close" header, meaning that this header should not be present in the request provided by "option httpchk". Last, if "http-check expect" is combined with "http-check disable-on-404", then this last one has precedence when the server responds with 404.
# only accept status 200 as valid
http-check expect status 200
# consider SQL errors as errors
http-check expect ! string SQL\ Error
# consider status 5xx only as errors
http-check expect ! rstatus ^5
# check that we have a correct hexadecimal tag before /html
http-check expect rstring <!--tag:[0-9a-f]*--></html>
Add a possible list of headers and/or a body to the request sent during HTTP health checks.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
hdr <name> <value> adds the HTTP header field whose name is specified in <name> and whose value is defined by <value> to the request sent during HTTP health checks. body <string> add the body defined by <string> to the request sent sent during HTTP health checks. If defined, the "Content-Length" header is thus automatically added to the request.
In addition to the request line defined by the "option httpchk" directive, this one is the valid way to add some headers and optionally a body to the request sent during HTTP health checks. If a body is defined, the associate "Content-Length" header is automatically added. The old trick consisting to add headers after the version string on the "option httpchk" line is now deprecated. Note also the "Connection: close" header is still added if a "http-check expect" direcive is defined independently of this directive, just like the state header if the directive "http-check send-state" is defined.
Enable emission of a state header with HTTP health checks
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When this option is set, haproxy will systematically send a special header "X-Haproxy-Server-State" with a list of parameters indicating to each server how they are seen by haproxy. This can be used for instance when a server is manipulated without access to haproxy and the operator needs to know whether haproxy still sees it up or not, or if the server is the last one in a farm. The header is composed of fields delimited by semi-colons, the first of which is a word ("UP", "DOWN", "NOLB"), possibly followed by a number of valid checks on the total number before transition, just as appears in the stats interface. Next headers are in the form "<variable>=<value>", indicating in no specific order some values available in the stats interface : - a variable "address", containing the address of the backend server. This corresponds to the <address> field in the server declaration. For unix domain sockets, it will read "unix". - a variable "port", containing the port of the backend server. This corresponds to the <port> field in the server declaration. For unix domain sockets, it will read "unix". - a variable "name", containing the name of the backend followed by a slash ("/") then the name of the server. This can be used when a server is checked in multiple backends. - a variable "node" containing the name of the haproxy node, as set in the global "node" variable, otherwise the system's hostname if unspecified. - a variable "weight" indicating the weight of the server, a slash ("/") and the total weight of the farm (just counting usable servers). This helps to know if other servers are available to handle the load when this one fails. - a variable "scur" indicating the current number of concurrent connections on the server, followed by a slash ("/") then the total number of connections on all servers of the same backend. - a variable "qcur" indicating the current number of requests in the server's queue. Example of a header received by the application server : >>> X-Haproxy-Server-State: UP 2/3; name=bck/srv2; node=lb1; weight=1/2; \ scur=13/22; qcur=0
Access control for Layer 7 requests
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
The http-request statement defines a set of rules which apply to layer 7 processing. The rules are evaluated in their declaration order when they are met in a frontend, listen or backend section. Any rule may optionally be followed by an ACL-based condition, in which case it will only be evaluated if the condition is true. The first keyword is the rule's action. The supported actions are described below. There is no limit to the number of http-request statements per instance.
acl nagios src 192.168.129.3
acl local_net src 192.168.0.0/16
acl auth_ok http_auth(L1)
http-request allow if nagios
http-request allow if local_net auth_ok
http-request auth realm Gimme if local_net auth_ok
http-request deny
acl key req.hdr(X-Add-Acl-Key) -m found
acl add path /addacl
acl del path /delacl
acl myhost hdr(Host) -f myhost.lst
http-request add-acl(myhost.lst) %[req.hdr(X-Add-Acl-Key)] if key add
http-request del-acl(myhost.lst) %[req.hdr(X-Add-Acl-Key)] if key del
acl value req.hdr(X-Value) -m found
acl setmap path /setmap
acl delmap path /delmap
use_backend bk_appli if { hdr(Host),map_str(map.lst) -m found }
http-request set-map(map.lst) %[src] %[req.hdr(X-Value)] if setmap value
http-request del-map(map.lst) %[src] if delmap
This is used to add a new entry into an ACL. The ACL must be loaded from a file (even a dummy empty file). The file name of the ACL to be updated is passed between parentheses. It takes one argument: <key fmt>, which follows log-format rules, to collect content of the new entry. It performs a lookup in the ACL before insertion, to avoid duplicated (or more) values. This lookup is done by a linear search and can be expensive with large lists! It is the equivalent of the "add acl" command from the stats socket, but can be triggered by an HTTP request.
This appends an HTTP header field whose name is specified in <name> and whose value is defined by <fmt> which follows the log-format rules (see Custom Log Format in section 8.2.4). This is particularly useful to pass connection-specific information to the server (e.g. the client's SSL certificate), or to combine several headers into one. This rule is not final, so it is possible to add other similar rules. Note that header addition is performed immediately, so one rule might reuse the resulting header from a previous rule.
This stops the evaluation of the rules and lets the request pass the check.
No further "http-request" rules are evaluated.
This stops the evaluation of the rules and immediately responds with an
HTTP 401 or 407 error code to invite the user to present a valid user name
and password. No further "http-request" rules are evaluated. An optional
"realm" parameter is supported, it sets the authentication realm that is
returned with the response (typically the application's name).
acl auth_ok http_auth_group(L1) G1
http-request auth unless auth_ok
See section 6.2 about cache setup.
This captures sample expression <sample> from the request buffer, and converts it to a string of at most <len> characters. The resulting string is stored into the next request "capture" slot, so it will possibly appear next to some captured HTTP headers. It will then automatically appear in the logs, and it will be possible to extract it using sample fetch rules to feed it into headers or anything. The length should be limited given that this size will be allocated for each capture during the whole session life. Please check section 7.3 (Fetching samples) and "capture request header" for more information. If the keyword "id" is used instead of "len", the action tries to store the captured string in a previously declared capture slot. This is useful to run captures in backends. The slot id can be declared by a previous directive "http-request capture" or with the "declare capture" keyword. When using this action in a backend, double check that the relevant frontend(s) have the required capture slots otherwise, this rule will be ignored at run time. This can't be detected at configuration parsing time due to HAProxy's ability to dynamically resolve backend name at runtime.
This is used to delete an entry from an ACL. The ACL must be loaded from a file (even a dummy empty file). The file name of the ACL to be updated is passed between parentheses. It takes one argument: <key fmt>, which follows log-format rules, to collect content of the entry to delete. It is the equivalent of the "del acl" command from the stats socket, but can be triggered by an HTTP request.
This removes all HTTP header fields whose name is specified in <name>.
This is used to delete an entry from a MAP. The MAP must be loaded from a file (even a dummy empty file). The file name of the MAP to be updated is passed between parentheses. It takes one argument: <key fmt>, which follows log-format rules, to collect content of the entry to delete. It takes one argument: "file name" It is the equivalent of the "del map" command from the stats socket, but can be triggered by an HTTP request.
This stops the evaluation of the rules and immediately rejects the request and emits an HTTP 403 error, or optionally the status code specified as an argument to "deny_status". The list of permitted status codes is limited to those that can be overridden by the "errorfile" directive. No further "http-request" rules are evaluated.
This disables any attempt to retry the request if it fails for any other reason than a connection failure. This can be useful for example to make sure POST requests aren't retried on failure.
This action performs a DNS resolution of the output of <expr> and stores the result in the variable <var>. It uses the DNS resolvers section pointed by <resolvers>. It is possible to choose a resolution preference using the optional arguments 'ipv4' or 'ipv6'. When performing the DNS resolution, the client side connection is on pause waiting till the end of the resolution. If an IP address can be found, it is stored into <var>. If any kind of error occurs, then <var> is not set. One can use this action to discover a server IP address at run time and based on information found in the request (IE a Host header). If this action is used to find the server's IP address (using the "set-dst" action), then the server IP address in the backend must be set to 0.0.0.0.
resolvers mydns
nameserver local 127.0.0.53:53
nameserver google 8.8.8.8:53
timeout retry 1s
hold valid 10s
hold nx 3s
hold other 3s
hold obsolete 0s
accepted_payload_size 8192
frontend fe
bind 10.42.0.1:80
http-request do-resolve(txn.myip,mydns,ipv4) hdr(Host),lower
http-request capture var(txn.myip) len 40
# return 503 when the variable is not set,
# which mean DNS resolution error
use_backend b_503 unless { var(txn.myip) -m found }
default_backend be
backend b_503
# dummy backend used to return 503.
# one can use the errorfile directive to send a nice
# 503 error page to end users
backend be
# rule to prevent HAProxy from reconnecting to services
# on the local network (forged DNS name used to scan the network)
http-request deny if { var(txn.myip) -m ip 127.0.0.0/8 10.0.0.0/8 }
http-request set-dst var(txn.myip)
server clear 0.0.0.0:0
NOTE: Don't forget to set the "protection" rules to ensure HAProxy won't be used to scan the network or worst won't loop over itself...
This is used to build an HTTP 103 Early Hints response prior to any other one. This appends an HTTP header field to this response whose name is specified in <name> and whose value is defined by <fmt> which follows the log-format rules (see Custom Log Format in section 8.2.4). This is particularly useful to pass to the client some Link headers to preload resources required to render the HTML documents. See RFC 8297 for more information.
This performs an HTTP redirection based on a redirect rule. This is exactly the same as the "redirect" statement except that it inserts a redirect rule which can be processed in the middle of other "http-request" rules and that these rules use the "log-format" strings. See the "redirect" keyword for the rule's syntax.
This stops the evaluation of the rules and immediately closes the connection without sending any response. It acts similarly to the "tcp-request content reject" rules. It can be useful to force an immediate connection closure on HTTP/2 connections.
This matches the value of all occurrences of header field <name> against <match-regex>. Matching is performed case-sensitively. Matching values are completely replaced by <replace-fmt>. Format characters are allowed in <replace-fmt> and work like <fmt> arguments in "http-request add-header". Standard back-references using the backslash ('\') followed by a number are supported. This action acts on whole header lines, regardless of the number of values they may contain. Thus it is well-suited to process headers naturally containing commas in their value, such as If-Modified-Since. Headers that contain a comma-separated list of values, such as Accept, should be processed using "http-request replace-value".
http-request replace-header Cookie foo=([^;]*);(.*) foo=\1;ip=%bi;\2
# applied to:
Cookie: foo=foobar; expires=Tue, 14-Jun-2016 01:40:45 GMT;
# outputs:
Cookie: foo=foobar;ip=192.168.1.20; expires=Tue, 14-Jun-2016 01:40:45 GMT;
# assuming the backend IP is 192.168.1.20
http-request replace-header User-Agent curl foo
# applied to:
User-Agent: curl/7.47.0
# outputs:
User-Agent: foo
This works like "replace-header" except that it works on the request's path component instead of a header. The path component starts at the first '/' after an optional scheme+authority and ends before the question mark. Thus, the replacement does not modify the scheme, the authority and the query-string. It is worth noting that regular expressions may be more expensive to evaluate than certain ACLs, so rare replacements may benefit from a condition to avoid performing the evaluation at all if it does not match.
# prefix /foo : turn /bar?q=1 into /foo/bar?q=1 :
http-request replace-path (.*) /foo\1
# strip /foo : turn /foo/bar?q=1 into /bar?q=1
http-request replace-path /foo/(.*) /\1
# or more efficient if only some requests match :
http-request replace-path /foo/(.*) /\1 if { url_beg /foo/ }
This works like "replace-header" except that it works on the request's URI part instead of a header. The URI part may contain an optional scheme, authority or query string. These are considered to be part of the value that is matched against. It is worth noting that regular expressions may be more expensive to evaluate than certain ACLs, so rare replacements may benefit from a condition to avoid performing the evaluation at all if it does not match. IMPORTANT NOTE: historically in HTTP/1.x, the vast majority of requests sent by browsers use the "origin form", which differs from the "absolute form" in that they do not contain a scheme nor authority in the URI portion. Mostly only requests sent to proxies, those forged by hand and some emitted by certain applications use the absolute form. As such, "replace-uri" usually works fine most of the time in HTTP/1.x with rules starting with a "/". But with HTTP/2, clients are encouraged to send absolute URIs only, which look like the ones HTTP/1 clients use to talk to proxies. Such partial replace-uri rules may then fail in HTTP/2 when they work in HTTP/1. Either the rules need to be adapted to optionally match a scheme and authority, or replace-path should be used.
# rewrite all "http" absolute requests to "https":
http-request replace-uri ^http://(.*) https://\1
# prefix /foo : turn /bar?q=1 into /foo/bar?q=1 :
http-request replace-uri ([^/:]*://[^/]*)?(.*) \1/foo\2
This works like "replace-header" except that it matches the regex against every comma-delimited value of the header field <name> instead of the entire header. This is suited for all headers which are allowed to carry more than one value. An example could be the Accept header.
http-request replace-value X-Forwarded-For ^192\.168\.(.*)$ 172.16.\1
# applied to:
X-Forwarded-For: 192.168.10.1, 192.168.13.24, 10.0.0.37
# outputs:
X-Forwarded-For: 172.16.10.1, 172.16.13.24, 10.0.0.37
This actions increments the GPC0 or GPC1 counter according with the sticky counter designated by <sc-id>. If an error occurs, this action silently fails and the actions evaluation continues.
This action sets the 32-bit unsigned GPT0 tag according to the sticky counter designated by <sc-id> and the value of <int>/<expr>. The expected result is a boolean. If an error occurs, this action silently fails and the actions evaluation continues.
This is used to set the destination IP address to the value of specified expression. Useful when a proxy in front of HAProxy rewrites destination IP, but provides the correct IP in a HTTP header; or you want to mask the IP for privacy. If you want to connect to the new address/port, use '0.0.0.0:0' as a server address in the backend.
<expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
http-request set-dst hdr(x-dst)
http-request set-dst dst,ipmask(24)
When possible, set-dst preserves the original destination port as long as the address family allows it, otherwise the destination port is set to 0.
This is used to set the destination port address to the value of specified expression. If you want to connect to the new address/port, use '0.0.0.0:0' as a server address in the backend.
<expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
http-request set-dst-port hdr(x-port)
http-request set-dst-port int(4000)
When possible, set-dst-port preserves the original destination address as long as the address family supports a port, otherwise it forces the destination address to IPv4 "0.0.0.0" before rewriting the port.
This does the same as "http-request add-header" except that the header name is first removed if it existed. This is useful when passing security information to the server, where the header must not be manipulated by external users. Note that the new value is computed before the removal so it is possible to concatenate a value to an existing header.
http-request set-header X-Haproxy-Current-Date %T
http-request set-header X-SSL %[ssl_fc]
http-request set-header X-SSL-Session_ID %[ssl_fc_session_id,hex]
http-request set-header X-SSL-Client-Verify %[ssl_c_verify]
http-request set-header X-SSL-Client-DN %{+Q}[ssl_c_s_dn]
http-request set-header X-SSL-Client-CN %{+Q}[ssl_c_s_dn(cn)]
http-request set-header X-SSL-Issuer %{+Q}[ssl_c_i_dn]
http-request set-header X-SSL-Client-NotBefore %{+Q}[ssl_c_notbefore]
http-request set-header X-SSL-Client-NotAfter %{+Q}[ssl_c_notafter]
This is used to change the log level of the current request when a certain
condition is met. Valid levels are the 8 syslog levels (see the "log"
keyword) plus the special level "silent" which disables logging for this
request. This rule is not final so the last matching rule wins. This rule
can be useful to disable health checks coming from another equipment.
This is used to add a new entry into a MAP. The MAP must be loaded from a file (even a dummy empty file). The file name of the MAP to be updated is passed between parentheses. It takes 2 arguments: <key fmt>, which follows log-format rules, used to collect MAP key, and <value fmt>, which follows log-format rules, used to collect content for the new entry. It performs a lookup in the MAP before insertion, to avoid duplicated (or more) values. This lookup is done by a linear search and can be expensive with large lists! It is the equivalent of the "set map" command from the stats socket, but can be triggered by an HTTP request.
This is used to set the Netfilter MARK on all packets sent to the client to the value passed in <mark> on platforms which support it. This value is an unsigned 32 bit value which can be matched by netfilter and by the routing table. It can be expressed both in decimal or hexadecimal format (prefixed by "0x"). This can be useful to force certain packets to take a different route (for example a cheaper network path for bulk downloads). This works on Linux kernels 2.6.32 and above and requires admin privileges.
This rewrites the request method with the result of the evaluation of format string <fmt>. There should be very few valid reasons for having to do so as this is more likely to break something than to fix it.
This sets the "nice" factor of the current request being processed. It only has effect against the other requests being processed at the same time. The default value is 0, unless altered by the "nice" setting on the "bind" line. The accepted range is -1024..1024. The higher the value, the nicest the request will be. Lower values will make the request more important than other ones. This can be useful to improve the speed of some requests, or lower the priority of non-important requests. Using this setting without prior experimentation can cause some major slowdown.
This rewrites the request path with the result of the evaluation of format string <fmt>. The query string, if any, is left intact. If a scheme and authority is found before the path, they are left intact as well. If the request doesn't have a path ("*"), this one is replaced with the format. This can be used to prepend a directory component in front of a path for example. See also "http-request set-query" and "http-request set-uri".
# prepend the host name before the path
http-request set-path /%[hdr(host)]%[path]
This is used to set the queue priority class of the current request. The value must be a sample expression which converts to an integer in the range -2047..2047. Results outside this range will be truncated. The priority class determines the order in which queued requests are processed. Lower values have higher priority.
This is used to set the queue priority timestamp offset of the current request. The value must be a sample expression which converts to an integer in the range -524287..524287. Results outside this range will be truncated. When a request is queued, it is ordered first by the priority class, then by the current timestamp adjusted by the given offset in milliseconds. Lower values have higher priority. Note that the resulting timestamp is is only tracked with enough precision for 524,287ms (8m44s287ms). If the request is queued long enough to where the adjusted timestamp exceeds this value, it will be misidentified as highest priority. Thus it is important to set "timeout queue" to a value, where when combined with the offset, does not exceed this limit.
This rewrites the request's query string which appears after the first question mark ("?") with the result of the evaluation of format string <fmt>. The part prior to the question mark is left intact. If the request doesn't contain a question mark and the new value is not empty, then one is added at the end of the URI, followed by the new value. If a question mark was present, it will never be removed even if the value is empty. This can be used to add or remove parameters from the query string. See also "http-request set-query" and "http-request set-uri".
# replace "%3D" with "=" in the query string
http-request set-query %[query,regsub(%3D,=,g)]
This is used to set the source IP address to the value of specified expression. Useful when a proxy in front of HAProxy rewrites source IP, but provides the correct IP in a HTTP header; or you want to mask source IP for privacy. All subsequent calls to "src" fetch will return this value (see example).
<expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
See also "option forwardfor".
http-request set-src hdr(x-forwarded-for)
http-request set-src src,ipmask(24)
# After the masking this will track connections
# based on the IP address with the last byte zeroed out.
http-request track-sc0 src
When possible, set-src preserves the original source port as long as the address family allows it, otherwise the source port is set to 0.
This is used to set the source port address to the value of specified expression.
<expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
http-request set-src-port hdr(x-port)
http-request set-src-port int(4000)
When possible, set-src-port preserves the original source address as long as the address family supports a port, otherwise it forces the source address to IPv4 "0.0.0.0" before rewriting the port.
This is used to set the TOS or DSCP field value of packets sent to the client to the value passed in <tos> on platforms which support this. This value represents the whole 8 bits of the IP TOS field, and can be expressed both in decimal or hexadecimal format (prefixed by "0x"). Note that only the 6 higher bits are used in DSCP or TOS, and the two lower bits are always 0. This can be used to adjust some routing behavior on border routers based on some information from the request. See RFC 2474, 2597, 3260 and 4594 for more information.
This rewrites the request URI with the result of the evaluation of format string <fmt>. The scheme, authority, path and query string are all replaced at once. This can be used to rewrite hosts in front of proxies, or to perform complex modifications to the URI such as moving parts between the path and the query string. See also "http-request set-path" and "http-request set-query".
This is used to set the contents of a variable. The variable is declared inline.
<var-name> The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9' and '_'. <expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
http-request set-var(req.my_var) req.fhdr(user-agent),lower
This action is used to trigger sending of a group of SPOE messages. To do so, the SPOE engine used to send messages must be defined, as well as the SPOE group to send. Of course, the SPOE engine must refer to an existing SPOE filter. If not engine name is provided on the SPOE filter line, the SPOE agent name must be used.
<engine-name> The SPOE engine name. <group-name> The SPOE group name as specified in the engine configuration.
This stops the evaluation of the rules and makes the client-facing connection suddenly disappear using a system-dependent way that tries to prevent the client from being notified. The effect it then that the client still sees an established connection while there's none on HAProxy. The purpose is to achieve a comparable effect to "tarpit" except that it doesn't use any local resource at all on the machine running HAProxy. It can resist much higher loads than "tarpit", and slow down stronger attackers. It is important to understand the impact of using this mechanism. All stateful equipment placed between the client and HAProxy (firewalls, proxies, load balancers) will also keep the established connection for a long time and may suffer from this action. On modern Linux systems running with enough privileges, the TCP_REPAIR socket option is used to block the emission of a TCP reset. On other systems, the socket's TTL is reduced to 1 so that the TCP reset doesn't pass the first router, though it's still delivered to local networks. Do not use it unless you fully understand how it works.
This stops the evaluation of the rules and immediately blocks the request without responding for a delay specified by "timeout tarpit" or "timeout connect" if the former is not set. After that delay, if the client is still connected, an HTTP error 500 (or optionally the status code specified as an argument to "deny_status") is returned so that the client does not suspect it has been tarpitted. Logs will report the flags "PT". The goal of the tarpit rule is to slow down robots during an attack when they're limited on the number of concurrent requests. It can be very efficient against very dumb robots, and will significantly reduce the load on firewalls compared to a "deny" rule. But when facing "correctly" developed robots, it can make things worse by forcing haproxy and the front firewall to support insane number of concurrent connections. See also the "silent-drop" action.
This enables tracking of sticky counters from current request. These rules do not stop evaluation and do not change default action. The number of counters that may be simultaneously tracked by the same connection is set in MAX_SESS_STKCTR at build time (reported in haproxy -vv) which defaults to 3, so the track-sc number is between 0 and (MAX_SESS_STCKTR-1). The first "track-sc0" rule executed enables tracking of the counters of the specified table as the first set. The first "track-sc1" rule executed enables tracking of the counters of the specified table as the second set. The first "track-sc2" rule executed enables tracking of the counters of the specified table as the third set. It is a recommended practice to use the first set of counters for the per-frontend counters and the second set for the per-backend ones. But this is just a guideline, all may be used everywhere.
<key> is mandatory, and is a sample expression rule as described in section 7.3. It describes what elements of the incoming request or connection will be analyzed, extracted, combined, and used to select which table entry to update the counters. <table> is an optional table to be used instead of the default one, which is the stick-table declared in the current proxy. All the counters for the matches and updates for the key will then be performed in that table until the session ends.
Once a "track-sc*" rule is executed, the key is looked up in the table and if it is not found, an entry is allocated for it. Then a pointer to that entry is kept during all the session's life, and this entry's counters are updated as often as possible, every time the session's counters are updated, and also systematically when the session ends. Counters are only updated for events that happen after the tracking has been started. As an exception, connection counters and request counters are systematically updated so that they reflect useful information. If the entry tracks concurrent connection counters, one connection is counted for as long as the entry is tracked, and the entry will not expire during that time. Tracking counters also provides a performance advantage over just checking the keys, because only one table lookup is performed for all ACL checks that make use of it.
This is used to unset a variable. See above for details about <var-name>.
http-request unset-var(req.my_var)
This directive executes the configured HTTP service to reply to the request
and stops the evaluation of the rules. An HTTP service may choose to reply by
sending any valid HTTP response or it may immediately close the connection
without sending any response. Outside natives services, for instance the
Prometheus exporter, it is possible to write your own services in Lua. No
further "http-request" rules are evaluated.
<service-name> is mandatory. It is the service to call
http-request use-service prometheus-exporter if { path /metrics }
This will delay the processing of the request until the SSL handshake happened. This is mostly useful to delay processing early data until we're sure they are valid.
Access control for Layer 7 responses
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
The http-response statement defines a set of rules which apply to layer 7 processing. The rules are evaluated in their declaration order when they are met in a frontend, listen or backend section. Any rule may optionally be followed by an ACL-based condition, in which case it will only be evaluated if the condition is true. Since these rules apply on responses, the backend rules are applied first, followed by the frontend's rules. The first keyword is the rule's action. The supported actions are described below. There is no limit to the number of http-response statements per instance.
acl key_acl res.hdr(X-Acl-Key) -m found
acl myhost hdr(Host) -f myhost.lst
http-response add-acl(myhost.lst) %[res.hdr(X-Acl-Key)] if key_acl
http-response del-acl(myhost.lst) %[res.hdr(X-Acl-Key)] if key_acl
acl value res.hdr(X-Value) -m found
use_backend bk_appli if { hdr(Host),map_str(map.lst) -m found }
http-response set-map(map.lst) %[src] %[res.hdr(X-Value)] if value
http-response del-map(map.lst) %[src] if ! value
This is used to add a new entry into an ACL. The ACL must be loaded from a file (even a dummy empty file). The file name of the ACL to be updated is passed between parentheses. It takes one argument: <key fmt>, which follows log-format rules, to collect content of the new entry. It performs a lookup in the ACL before insertion, to avoid duplicated (or more) values. This lookup is done by a linear search and can be expensive with large lists! It is the equivalent of the "add acl" command from the stats socket, but can be triggered by an HTTP response.
This appends an HTTP header field whose name is specified in <name> and whose value is defined by <fmt> which follows the log-format rules (see Custom Log Format in section 8.2.4). This may be used to send a cookie to a client for example, or to pass some internal information. This rule is not final, so it is possible to add other similar rules. Note that header addition is performed immediately, so one rule might reuse the resulting header from a previous rule.
This stops the evaluation of the rules and lets the response pass the check.
No further "http-response" rules are evaluated for the current section.
See section 6.2 about cache setup.
This captures sample expression <sample> from the response buffer, and converts it to a string. The resulting string is stored into the next request "capture" slot, so it will possibly appear next to some captured HTTP headers. It will then automatically appear in the logs, and it will be possible to extract it using sample fetch rules to feed it into headers or anything. Please check section 7.3 (Fetching samples) and "capture response header" for more information. The keyword "id" is the id of the capture slot which is used for storing the string. The capture slot must be defined in an associated frontend. This is useful to run captures in backends. The slot id can be declared by a previous directive "http-response capture" or with the "declare capture" keyword. When using this action in a backend, double check that the relevant frontend(s) have the required capture slots otherwise, this rule will be ignored at run time. This can't be detected at configuration parsing time due to HAProxy's ability to dynamically resolve backend name at runtime.
This is used to delete an entry from an ACL. The ACL must be loaded from a file (even a dummy empty file). The file name of the ACL to be updated is passed between parentheses. It takes one argument: <key fmt>, which follows log-format rules, to collect content of the entry to delete. It is the equivalent of the "del acl" command from the stats socket, but can be triggered by an HTTP response.
This removes all HTTP header fields whose name is specified in <name>.
This is used to delete an entry from a MAP. The MAP must be loaded from a file (even a dummy empty file). The file name of the MAP to be updated is passed between parentheses. It takes one argument: <key fmt>, which follows log-format rules, to collect content of the entry to delete. It takes one argument: "file name" It is the equivalent of the "del map" command from the stats socket, but can be triggered by an HTTP response.
This stops the evaluation of the rules and immediately rejects the response
and emits an HTTP 502 error. No further "http-response" rules are evaluated.
This performs an HTTP redirection based on a redirect rule. This supports a format string similarly to "http-request redirect" rules, with the exception that only the "location" type of redirect is possible on the response. See the "redirect" keyword for the rule's syntax. When a redirect rule is applied during a response, connections to the server are closed so that no data can be forwarded from the server to the client.
This works like "http-request replace-header" except that it works on the server's response instead of the client's request.
http-response replace-header Set-Cookie (C=[^;]*);(.*) \1;ip=%bi;\2
# applied to:
Set-Cookie: C=1; expires=Tue, 14-Jun-2016 01:40:45 GMT
# outputs:
Set-Cookie: C=1;ip=192.168.1.20; expires=Tue, 14-Jun-2016 01:40:45 GMT
# assuming the backend IP is 192.168.1.20.
This works like "http-response replace-value" except that it works on the server's response instead of the client's request.
http-response replace-value Cache-control ^public$ private
# applied to:
Cache-Control: max-age=3600, public
# outputs:
Cache-Control: max-age=3600, private
This action increments the GPC0 or GPC1 counter according with the sticky counter designated by <sc-id>. If an error occurs, this action silently fails and the actions evaluation continues.
This action sets the 32-bit unsigned GPT0 tag according to the sticky counter designated by <sc-id> and the value of <int>/<expr>. The expected result is a boolean. If an error occurs, this action silently fails and the actions evaluation continues.
This action is used to trigger sending of a group of SPOE messages. To do so, the SPOE engine used to send messages must be defined, as well as the SPOE group to send. Of course, the SPOE engine must refer to an existing SPOE filter. If not engine name is provided on the SPOE filter line, the SPOE agent name must be used.
<engine-name> The SPOE engine name. <group-name> The SPOE group name as specified in the engine configuration.
This does the same as "add-header" except that the header name is first removed if it existed. This is useful when passing security information to the server, where the header must not be manipulated by external users.
This is used to change the log level of the current request when a certain
condition is met. Valid levels are the 8 syslog levels (see the "log"
keyword) plus the special level "silent" which disables logging for this
request. This rule is not final so the last matching rule wins. This rule can
be useful to disable health checks coming from another equipment.
This is used to add a new entry into a MAP. The MAP must be loaded from a file (even a dummy empty file). The file name of the MAP to be updated is passed between parentheses. It takes 2 arguments: <key fmt>, which follows log-format rules, used to collect MAP key, and <value fmt>, which follows log-format rules, used to collect content for the new entry. It performs a lookup in the MAP before insertion, to avoid duplicated (or more) values. This lookup is done by a linear search and can be expensive with large lists! It is the equivalent of the "set map" command from the stats socket, but can be triggered by an HTTP response.
This is used to set the Netfilter MARK on all packets sent to the client to the value passed in <mark> on platforms which support it. This value is an unsigned 32 bit value which can be matched by netfilter and by the routing table. It can be expressed both in decimal or hexadecimal format (prefixed by "0x"). This can be useful to force certain packets to take a different route (for example a cheaper network path for bulk downloads). This works on Linux kernels 2.6.32 and above and requires admin privileges.
This sets the "nice" factor of the current request being processed. It only has effect against the other requests being processed at the same time. The default value is 0, unless altered by the "nice" setting on the "bind" line. The accepted range is -1024..1024. The higher the value, the nicest the request will be. Lower values will make the request more important than other ones. This can be useful to improve the speed of some requests, or lower the priority of non-important requests. Using this setting without prior experimentation can cause some major slowdown.
This replaces the response status code with <status> which must be an integer between 100 and 999. Optionally, a custom reason text can be provided defined by <str>, or the default reason for the specified code will be used as a fallback.
# return "431 Request Header Fields Too Large"
http-response set-status 431
# return "503 Slow Down", custom reason
http-response set-status 503 reason "Slow Down".
This is used to set the TOS or DSCP field value of packets sent to the client to the value passed in <tos> on platforms which support this. This value represents the whole 8 bits of the IP TOS field, and can be expressed both in decimal or hexadecimal format (prefixed by "0x"). Note that only the 6 higher bits are used in DSCP or TOS, and the two lower bits are always 0. This can be used to adjust some routing behavior on border routers based on some information from the request. See RFC 2474, 2597, 3260 and 4594 for more information.
This is used to set the contents of a variable. The variable is declared inline.
<var-name> The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'. <expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
http-response set-var(sess.last_redir) res.hdr(location)
This stops the evaluation of the rules and makes the client-facing connection suddenly disappear using a system-dependent way that tries to prevent the client from being notified. The effect it then that the client still sees an established connection while there's none on HAProxy. The purpose is to achieve a comparable effect to "tarpit" except that it doesn't use any local resource at all on the machine running HAProxy. It can resist much higher loads than "tarpit", and slow down stronger attackers. It is important to understand the impact of using this mechanism. All stateful equipment placed between the client and HAProxy (firewalls, proxies, load balancers) will also keep the established connection for a long time and may suffer from this action. On modern Linux systems running with enough privileges, the TCP_REPAIR socket option is used to block the emission of a TCP reset. On other systems, the socket's TTL is reduced to 1 so that the TCP reset doesn't pass the first router, though it's still delivered to local networks. Do not use it unless you fully understand how it works.
This enables tracking of sticky counters from current response. Please refer to "http-request track-sc" for a complete description. The only difference from "http-request track-sc" is the <key> sample expression can only make use of samples in response (e.g. res.*, status etc.) and samples below Layer 6 (e.g. SSL-related samples, see section 7.3.4). If the sample is not supported, haproxy will fail and warn while parsing the config.
This is used to unset a variable. See "http-response set-var" for details about <var-name>.
http-response unset-var(sess.last_redir)
Declare how idle HTTP connections may be shared between requests
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
By default, a connection established between haproxy and the backend server which is considered safe for reuse is moved back to the server's idle connections pool so that any other request can make use of it. This is the "safe" strategy below. The argument indicates the desired connection reuse strategy : - "never" : idle connections are never shared between sessions. This mode may be enforced to cancel a different strategy inherited from a defaults section or for troubleshooting. For example, if an old bogus application considers that multiple requests over the same connection come from the same client and it is not possible to fix the application, it may be desirable to disable connection sharing in a single backend. An example of such an application could be an old haproxy using cookie insertion in tunnel mode and not checking any request past the first one. - "safe" : this is the default and the recommended strategy. The first request of a session is always sent over its own connection, and only subsequent requests may be dispatched over other existing connections. This ensures that in case the server closes the connection when the request is being sent, the browser can decide to silently retry it. Since it is exactly equivalent to regular keep-alive, there should be no side effects. - "aggressive" : this mode may be useful in webservices environments where all servers are not necessarily known and where it would be appreciable to deliver most first requests over existing connections. In this case, first requests are only delivered over existing connections that have been reused at least once, proving that the server correctly supports connection reuse. It should only be used when it's sure that the client can retry a failed request once in a while and where the benefit of aggressive connection reuse significantly outweighs the downsides of rare connection failures. - "always" : this mode is only recommended when the path to the server is known for never breaking existing connections quickly after releasing them. It allows the first request of a session to be sent to an existing connection. This can provide a significant performance increase over the "safe" strategy when the backend is a cache farm, since such components tend to show a consistent behavior and will benefit from the connection sharing. It is recommended that the "http-keep-alive" timeout remains low in this mode so that no dead connections remain usable. In most cases, this will lead to the same performance gains as "aggressive" but with more risks. It should only be used when it improves the situation over "aggressive". When http connection sharing is enabled, a great care is taken to respect the connection properties and compatibility. Specifically : - connections made with "usesrc" followed by a client-dependent value ("client", "clientip", "hdr_ip") are marked private and never shared; - connections sent to a server with a TLS SNI extension are marked private and are never shared; - connections with certain bogus authentication schemes (relying on the connection) like NTLM are detected, marked private and are never shared; A connection pool is involved and configurable with "pool-max-conn". Note: connection reuse improves the accuracy of the "server maxconn" setting, because almost no new connection will be established while idle connections remain available. This is particularly true with the "always" strategy.
Add the server name to a request. Use the header string given by <header>
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<header> The header string to use to send the server name
The "http-send-name-header" statement causes the header field named <header> to be set to the name of the target server at the moment the request is about to be sent on the wire. Any existing occurrences of this header are removed. Upon retries and redispatches, the header field is updated to always reflect the server being attempted to connect to. Given that this header is modified very late in the connection setup, it may have unexpected effects on already modified headers. For example using it with transport-level header such as connection, content-length, transfer-encoding and so on will likely result in invalid requests being sent to the server. Additionally it has been reported that this directive is currently being used as a way to overwrite the Host header field in outgoing requests; while this trick has been known to work as a side effect of the feature for some time, it is not officially supported and might possibly not work anymore in a future version depending on the technical difficulties this feature induces. A long-term solution instead consists in fixing the application which required this trick so that it binds to the correct host name.
Set a persistent ID to a proxy.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
Set a persistent ID for the proxy. This ID must be unique and positive. An unused ID will automatically be assigned if unset. The first assigned value will be 1. This ID is currently only returned in statistics.
Declare a condition to ignore persistence
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
By default, when cookie persistence is enabled, every requests containing the cookie are unconditionally persistent (assuming the target server is up and running). The "ignore-persist" statement allows one to declare various ACL-based conditions which, when met, will cause a request to ignore persistence. This is sometimes useful to load balance requests for static files, which often don't require persistence. This can also be used to fully disable persistence for a specific User-Agent (for example, some web crawler bots). The persistence is ignored when an "if" condition is met, or unless an "unless" condition is met.
acl url_static path_beg /static /images /img /css
acl url_static path_end .gif .png .jpg .css .js
ignore-persist if url_static
Allow seamless reload of HAProxy
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
This directive points HAProxy to a file where server state from previous running process has been saved. That way, when starting up, before handling traffic, the new process can apply old states to servers exactly has if no reload occurred. The purpose of the "load-server-state-from-file" directive is to tell haproxy which file to use. For now, only 2 arguments to either prevent loading state or load states from a file containing all backends and servers. The state file can be generated by running the command "show servers state" over the stats socket and redirect output. The format of the file is versioned and is very specific. To understand it, please read the documentation of the "show servers state" command (chapter 9.3 of Management Guide).
global load the content of the file pointed by the global directive named "server-state-file". local load the content of the file pointed by the directive "server-state-file-name" if set. If not set, then the backend name is used as a file name. none don't load any stat for this backend
Notes: - server's IP address is preserved across reloads by default, but the order can be changed thanks to the server's "init-addr" setting. This means that an IP address change performed on the CLI at run time will be preserved, and that any change to the local resolver (e.g. /etc/hosts) will possibly not have any effect if the state file is in use. - server's weight is applied from previous running process unless it has has changed between previous and new configuration files.
Minimal configurationglobal stats socket /tmp/socket server-state-file /tmp/server_state defaults load-server-state-from-file global backend bk server s1 127.0.0.1:22 check weight 11 server s2 127.0.0.1:22 check weight 12
Then one can run : socat /tmp/socket - <<< "show servers state" > /tmp/server_state Content of the file /tmp/server_state would be like this: 1 # <field names skipped for the doc example> 1 bk 1 s1 127.0.0.1 2 0 11 11 4 6 3 4 6 0 0 1 bk 2 s2 127.0.0.1 2 0 12 12 4 6 3 4 6 0 0
Minimal configurationglobal stats socket /tmp/socket server-state-base /etc/haproxy/states defaults load-server-state-from-file local backend bk server s1 127.0.0.1:22 check weight 11 server s2 127.0.0.1:22 check weight 12
Then one can run : socat /tmp/socket - <<< "show servers state bk" > /etc/haproxy/states/bk Content of the file /etc/haproxy/states/bk would be like this: 1 # <field names skipped for the doc example> 1 bk 1 s1 127.0.0.1 2 0 11 11 4 6 3 4 6 0 0 1 bk 2 s2 127.0.0.1 2 0 12 12 4 6 3 4 6 0 0
Enable per-instance logging of events and traffic.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
Prefix : no should be used when the logger list must be flushed. For example, if you don't want to inherit from the default logger list. This prefix does not allow arguments.
global should be used when the instance's logging parameters are the same as the global ones. This is the most common usage. "global" replaces <address>, <facility> and <level> with those of the log entries found in the "global" section. Only one "log global" statement may be used per instance, and this form takes no other parameter. <address> indicates where to send the logs. It takes the same format as for the "global" section's logs, and can be one of : - An IPv4 address optionally followed by a colon (':') and a UDP port. If no port is specified, 514 is used by default (the standard syslog port). - An IPv6 address followed by a colon (':') and optionally a UDP port. If no port is specified, 514 is used by default (the standard syslog port). - A filesystem path to a UNIX domain socket, keeping in mind considerations for chroot (be sure the path is accessible inside the chroot) and uid/gid (be sure the path is appropriately writable). - A file descriptor number in the form "fd@<number>", which may point to a pipe, terminal, or socket. In this case unbuffered logs are used and one writev() call per log is performed. This is a bit expensive but acceptable for most workloads. Messages sent this way will not be truncated but may be dropped, in which case the DroppedLogs counter will be incremented. The writev() call is atomic even on pipes for messages up to PIPE_BUF size, which POSIX recommends to be at least 512 and which is 4096 bytes on most modern operating systems. Any larger message may be interleaved with messages from other processes. Exceptionally for debugging purposes the file descriptor may also be directed to a file, but doing so will significantly slow haproxy down as non-blocking calls will be ignored. Also there will be no way to purge nor rotate this file without restarting the process. Note that the configured syslog format is preserved, so the output is suitable for use with a TCP syslog server. See also the "short" and "raw" formats below. - "stdout" / "stderr", which are respectively aliases for "fd@1" and "fd@2", see above. - A ring buffer in the form "ring@<name>", which will correspond to an in-memory ring buffer accessible over the CLI using the "show events" command, which will also list existing rings and their sizes. Such buffers are lost on reload or restart but when used as a complement this can help troubleshooting by having the logs instantly available. You may want to reference some environment variables in the address parameter, see section 2.3 about environment variables. <length> is an optional maximum line length. Log lines larger than this value will be truncated before being sent. The reason is that syslog servers act differently on log line length. All servers support the default value of 1024, but some servers simply drop larger lines while others do log them. If a server supports long lines, it may make sense to set this value here in order to avoid truncating long lines. Similarly, if a server drops long lines, it is preferable to truncate them before sending them. Accepted values are 80 to 65535 inclusive. The default value of 1024 is generally fine for all standard usages. Some specific cases of long captures or JSON-formatted logs may require larger values. <ranges> A list of comma-separated ranges to identify the logs to sample. This is used to balance the load of the logs to send to the log server. The limits of the ranges cannot be null. They are numbered from 1. The size or period (in number of logs) of the sample must be set with <sample_size> parameter. <sample_size> The size of the sample in number of logs to consider when balancing their logging loads. It is used to balance the load of the logs to send to the syslog server. This size must be greater or equal to the maximum of the high limits of the ranges. (see also <ranges> parameter). <format> is the log format used when generating syslog messages. It may be one of the following : rfc3164 The RFC3164 syslog message format. This is the default. (https://tools.ietf.org/html/rfc3164) rfc5424 The RFC5424 syslog message format. (https://tools.ietf.org/html/rfc5424) short A message containing only a level between angle brackets such as '<3>', followed by the text. The PID, date, time, process name and system name are omitted. This is designed to be used with a local log server. This format is compatible with what the systemd logger consumes. raw A message containing only the text. The level, PID, date, time, process name and system name are omitted. This is designed to be used in containers or during development, where the severity only depends on the file descriptor used (stdout/stderr). <facility> must be one of the 24 standard syslog facilities : kern user mail daemon auth syslog lpr news uucp cron auth2 ftp ntp audit alert cron2 local0 local1 local2 local3 local4 local5 local6 local7 Note that the facility is ignored for the "short" and "raw" formats, but still required as a positional field. It is recommended to use "daemon" in this case to make it clear that it's only supposed to be used locally. <level> is optional and can be specified to filter outgoing messages. By default, all messages are sent. If a level is specified, only messages with a severity at least as important as this level will be sent. An optional minimum level can be specified. If it is set, logs emitted with a more severe level than this one will be capped to this level. This is used to avoid sending "emerg" messages on all terminals on some default syslog configurations. Eight levels are known : emerg alert crit err warning notice info debug
It is important to keep in mind that it is the frontend which decides what to log from a connection, and that in case of content switching, the log entries from the backend will be ignored. Connections are logged at level "info". However, backend log declaration define how and where servers status changes will be logged. Level "notice" will be used to indicate a server going up, "warning" will be used for termination signals and definitive service termination, and "alert" will be used for when a server goes down. Note : According to RFC3164, messages are truncated to 1024 bytes before being emitted.
log global
log stdout format short daemon # send log to systemd
log stdout format raw daemon # send everything to stdout
log stderr format raw daemon notice # send important events to stderr
log 127.0.0.1:514 local0 notice # only send important events
log 127.0.0.1:514 local0 notice notice # same but limit output level
log "${LOCAL_SYSLOG}:514" local0 notice # send to local server
Specifies the log format string to use for traffic logs
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
This directive specifies the log format string that will be used for all logs resulting from traffic passing through the frontend using this line. If the directive is used in a defaults section, all subsequent frontends will use the same log format. Please see section 8.2.4 which covers the log format string in depth. "log-format" directive overrides previous "option tcplog", "log-format" and "option httplog" directives.
Specifies the RFC5424 structured-data log format string
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
This directive specifies the RFC5424 structured-data log format string that will be used for all logs resulting from traffic passing through the frontend using this line. If the directive is used in a defaults section, all subsequent frontends will use the same log format. Please see section 8.2.4 which covers the log format string in depth. See https://tools.ietf.org/html/rfc5424#section-6.3 for more information about the RFC5424 structured-data part. Note : This log format string will be used only for loggers that have set log format to "rfc5424".
log-format-sd [exampleSDID@1234\ bytes=\"%B\"\ status=\"%ST\"]
Specifies the log tag to use for all outgoing logs
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
Sets the tag field in the syslog header to this string. It defaults to the
log-tag set in the global section, otherwise the program name as launched
from the command line, which usually is "haproxy". Sometimes it can be useful
to differentiate between multiple processes running on the same host, or to
differentiate customer instances running in the same process. In the backend,
logs about servers up/down will use this tag. As a hint, it can be convenient
to set a log-tag related to a hosted customer in a defaults section then put
all the frontends and backends for that customer, then start another customer
in a new defaults section. See also the global "log-tag" directive.
Set the maximum server queue size for maintaining keep-alive connections
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
HTTP keep-alive tries to reuse the same server connection whenever possible, but sometimes it can be counter-productive, for example if a server has a lot of connections while other ones are idle. This is especially true for static servers. The purpose of this setting is to set a threshold on the number of queued connections at which haproxy stops trying to reuse the same server and prefers to find another one. The default value, -1, means there is no limit. A value of zero means that keep-alive requests will never be queued. For very close servers which can be reached with a low latency and which are not sensible to breaking keep-alive, a low value is recommended (e.g. local static server can use a value of 10 or less). For remote servers suffering from a high latency, higher values might be needed to cover for the latency and/or the cost of picking a different server. Note that this has no impact on responses which are maintained to the same server consecutively to a 401 response. They will still go to the same server even if they have to be queued.
Set the maximum number of outgoing connections we can keep idling for a given client session. The default is 5 (it precisely equals MAX_SRV_LIST which is defined at build time).
Fix the maximum number of concurrent connections on a frontend
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<conns> is the maximum number of concurrent connections the frontend will accept to serve. Excess connections will be queued by the system in the socket's listen queue and will be served once a connection closes.
If the system supports it, it can be useful on big sites to raise this limit
very high so that haproxy manages connection queues, instead of leaving the
clients with unanswered connection attempts. This value should not exceed the
global maxconn. Also, keep in mind that a connection contains two buffers
of tune.bufsize (16kB by default) each, as well as some other data resulting
in about 33 kB of RAM being consumed per established connection. That means
that a medium system equipped with 1GB of RAM can withstand around
20000-25000 concurrent connections if properly tuned.
Also, when <conns> is set to large values, it is possible that the servers
are not sized to accept such loads, and for this reason it is generally wise
to assign them some reasonable connection limits.
When this value is set to zero, which is the default, the global "maxconn"
value is used.
Set the running mode or protocol of the instance
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
tcp The instance will work in pure TCP mode. A full-duplex connection will be established between clients and servers, and no layer 7 examination will be performed. This is the default mode. It should be used for SSL, SSH, SMTP, ... http The instance will work in HTTP mode. The client request will be analyzed in depth before connecting to any server. Any request which is not RFC-compliant will be rejected. Layer 7 filtering, processing and switching will be possible. This is the mode which brings HAProxy most of its value. health The instance will work in "health" mode. It will just reply "OK" to incoming connections and close the connection. Alternatively, If the "httpchk" option is set, "HTTP/1.0 200 OK" will be sent instead. Nothing will be logged in either case. This mode is used to reply to external components health checks. This mode is deprecated and should not be used anymore as it is possible to do the same and even better by combining TCP or HTTP modes with the "monitor" keyword.
When doing content switching, it is mandatory that the frontend and the backend are in the same mode (generally HTTP), otherwise the configuration will be refused.
defaults http_instances
mode http
Add a condition to report a failure to a monitor HTTP request.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
if <cond> the monitor request will fail if the condition is satisfied, and will succeed otherwise. The condition should describe a combined test which must induce a failure if all conditions are met, for instance a low number of servers both in a backend and its backup. unless <cond> the monitor request will succeed only if the condition is satisfied, and will fail otherwise. Such a condition may be based on a test on the presence of a minimum number of active servers in a list of backends.
This statement adds a condition which can force the response to a monitor request to report a failure. By default, when an external component queries the URI dedicated to monitoring, a 200 response is returned. When one of the conditions above is met, haproxy will return 503 instead of 200. This is very useful to report a site failure to an external component which may base routing advertisements between multiple sites on the availability reported by haproxy. In this case, one would rely on an ACL involving the "nbsrv" criterion. Note that "monitor fail" only works in HTTP mode. Both status messages may be tweaked using "errorfile" or "errorloc" if needed.
frontend www
mode http
acl site_dead nbsrv(dynamic) lt 2
acl site_dead nbsrv(static) lt 2
monitor-uri /site_alive
monitor fail if site_dead
Declare a source network which is limited to monitor requests
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<source> is the source IPv4 address or network which will only be able to get monitor responses to any request. It can be either an IPv4 address, a host name, or an address followed by a slash ('/') followed by a mask.
In TCP mode, any connection coming from a source matching <source> will cause the connection to be immediately closed without any log. This allows another equipment to probe the port and verify that it is still listening, without forwarding the connection to a remote server. In HTTP mode, a connection coming from a source matching <source> will be accepted, the following response will be sent without waiting for a request, then the connection will be closed : "HTTP/1.0 200 OK". This is normally enough for any front-end HTTP probe to detect that the service is UP and running without forwarding the request to a backend server. Note that this response is sent in raw format, without any transformation. This is important as it means that it will not be SSL-encrypted on SSL listeners. Monitor requests are processed very early, just after tcp-request connection ACLs which are the only ones able to block them. These connections are short lived and never wait for any data from the client. They cannot be logged, and it is the intended purpose. They are only used to report HAProxy's health to an upper component, nothing more. Please note that "monitor fail" rules do not apply to connections intercepted by "monitor-net". Last, please note that only one "monitor-net" statement can be specified in a frontend. If more than one is found, only the last one will be considered.
# addresses .252 and .253 are just probing us.
frontend www
monitor-net 192.168.0.252/31
Intercept a URI used by external components' monitor requests
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<uri> is the exact URI which we want to intercept to return HAProxy's health status instead of forwarding the request.
When an HTTP request referencing <uri> will be received on a frontend, HAProxy will not forward it nor log it, but instead will return either "HTTP/1.0 200 OK" or "HTTP/1.0 503 Service unavailable", depending on failure conditions defined with "monitor fail". This is normally enough for any front-end HTTP probe to detect that the service is UP and running without forwarding the request to a backend server. Note that the HTTP method, the version and all headers are ignored, but the request must at least be valid at the HTTP level. This keyword may only be used with an HTTP-mode frontend. Monitor requests are processed very early, just after the request is parsed and even before any "http-request". The only rulesets applied before are the tcp-request ones. They cannot be logged either, and it is the intended purpose. They are only used to report HAProxy's health to an upper component, nothing more. However, it is possible to add any number of conditions using "monitor fail" and ACLs so that the result can be adjusted to whatever check can be imagined (most often the number of available servers in a backend). Note: if <uri> starts by a slash ('/'), the matching is performed against the request's path instead of the request's uri. It is a workaround to let the HTTP/2 requests match the monitor-uri. Indeed, in HTTP/2, clients are encouraged to send absolute URIs only.
# Use /haproxy_test to report haproxy's status
frontend www
mode http
monitor-uri /haproxy_test
Enable or disable early dropping of aborted requests pending in queues.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
In presence of very high loads, the servers will take some time to respond. The per-instance 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, and the servers as well, because the request will eventually be served, then aborted at the first error encountered while delivering the response. As there is no way to distinguish between a full STOP and a simple output close 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 behavior (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 the risk of being the single component to break rare but valid traffic is extremely low, which adds to the temptation to be able to abort a session early while still not served and not pollute the servers. In HAProxy, the user can choose the desired behavior using the option "abortonclose". By default (without the option) the behavior is HTTP compliant and aborted requests will be served. But when the option is specified, a session with an incoming channel closed will be aborted while it is still possible, either pending in the queue for a connection slot, or during the connection establishment if the server has not yet acknowledged the connection request. 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. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable relaxing of HTTP request parsing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
By default, HAProxy complies with RFC7230 in terms of message parsing. This means that invalid characters in header names are not permitted and cause an error to be returned to the client. This is the desired behavior as such forbidden characters are essentially used to build attacks exploiting server weaknesses, and bypass security filtering. Sometimes, a buggy browser or server will emit invalid header names for whatever reason (configuration, implementation) and the issue will not be immediately fixed. In such a case, it is possible to relax HAProxy's header name parser to accept any character even if that does not make sense, by specifying this option. Similarly, the list of characters allowed to appear in a URI is well defined by RFC3986, and chars 0-31, 32 (space), 34 ('"'), 60 ('<'), 62 ('>'), 92 ('\'), 94 ('^'), 96 ('`'), 123 ('{'), 124 ('|'), 125 ('}'), 127 (delete) and anything above are not allowed at all. HAProxy always blocks a number of them (0..32, 127). The remaining ones are blocked by default unless this option is enabled. This option also relaxes the test on the HTTP version, it allows HTTP/0.9 requests to pass through (no version specified) and multiple digits for both the major and the minor version. This option should never be enabled by default as it hides application bugs and open security breaches. It should only be deployed after a problem has been confirmed. When this option is enabled, erroneous header names will still be accepted in requests, but the complete request will be captured in order to permit later analysis using the "show errors" request on the UNIX stats socket. Similarly, requests containing invalid chars in the URI part will be logged. Doing this also helps confirming that the issue has been solved. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable relaxing of HTTP response parsing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
By default, HAProxy complies with RFC7230 in terms of message parsing. This means that invalid characters in header names are not permitted and cause an error to be returned to the client. This is the desired behavior as such forbidden characters are essentially used to build attacks exploiting server weaknesses, and bypass security filtering. Sometimes, a buggy browser or server will emit invalid header names for whatever reason (configuration, implementation) and the issue will not be immediately fixed. In such a case, it is possible to relax HAProxy's header name parser to accept any character even if that does not make sense, by specifying this option. This option also relaxes the test on the HTTP version format, it allows multiple digits for both the major and the minor version. This option should never be enabled by default as it hides application bugs and open security breaches. It should only be deployed after a problem has been confirmed. When this option is enabled, erroneous header names will still be accepted in responses, but the complete response will be captured in order to permit later analysis using the "show errors" request on the UNIX stats socket. Doing this also helps confirming that the issue has been solved. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Use either all backup servers at a time or only the first one
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
By default, the first operational backup server gets all traffic when normal servers are all down. Sometimes, it may be preferred to use multiple backups at once, because one will not be enough. When "option allbackups" is enabled, the load balancing will be performed among all backup servers when all normal ones are unavailable. The same load balancing algorithm will be used and the servers' weights will be respected. Thus, there will not be any priority order between the backup servers anymore. This option is mostly used with static server farms dedicated to return a "sorry" page when an application is completely offline. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Analyze all server responses and block responses with cacheable cookies
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
Some high-level frameworks set application cookies everywhere and do not always let enough control to the developer to manage how the responses should be cached. When a session cookie is returned on a cacheable object, there is a high risk of session crossing or stealing between users traversing the same caches. In some situations, it is better to block the response than to let some sensitive session information go in the wild. The option "checkcache" enables deep inspection of all server responses for strict compliance with HTTP specification in terms of cacheability. It carefully checks "Cache-control", "Pragma" and "Set-cookie" headers in server response to check if there's a risk of caching a cookie on a client-side proxy. When this option is enabled, the only responses which can be delivered to the client are : - all those without "Set-Cookie" header; - all those with a return code other than 200, 203, 204, 206, 300, 301, 404, 405, 410, 414, 501, provided that the server has not set a "Cache-control: public" header field; - all those that result from a request using a method other than GET, HEAD, OPTIONS, TRACE, provided that the server has not set a 'Cache-Control: public' header field; - those with a 'Pragma: no-cache' header - those with a 'Cache-control: private' header - those with a 'Cache-control: no-store' header - those with a 'Cache-control: max-age=0' header - those with a 'Cache-control: s-maxage=0' header - those with a 'Cache-control: no-cache' header - those with a 'Cache-control: no-cache="set-cookie"' header - those with a 'Cache-control: no-cache="set-cookie,' header (allowing other fields after set-cookie) If a response doesn't respect these requirements, then it will be blocked just as if it was from an "http-response deny" rule, with an "HTTP 502 bad gateway". The session state shows "PH--" meaning that the proxy blocked the response during headers processing. Additionally, an alert will be sent in the logs so that admins are informed that there's something to be fixed. Due to the high impact on the application, the application should be tested in depth with the option enabled before going to production. It is also a good practice to always activate it during tests, even if it is not used in production, as it will report potentially dangerous application behaviors. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable the sending of TCP keepalive packets on the client side
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
When there is a firewall or any session-aware component between a client and a server, and when the protocol involves very long sessions with long idle periods (e.g. remote desktops), there is a risk that one of the intermediate components decides to expire a session which has remained idle for too long. Enabling socket-level TCP keep-alives makes the system regularly send packets to the other end of the connection, leaving it active. The delay between keep-alive probes is controlled by the system only and depends both on the operating system and its tuning parameters. It is important to understand that keep-alive packets are neither emitted nor received at the application level. It is only the network stacks which sees them. For this reason, even if one side of the proxy already uses keep-alives to maintain its connection alive, those keep-alive packets will not be forwarded to the other side of the proxy. Please note that this has nothing to do with HTTP keep-alive. Using option "clitcpka" enables the emission of TCP keep-alive probes on the client side of a connection, which should help when session expirations are noticed between HAProxy and a client. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable continuous traffic statistics updates
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
By default, counters used for statistics calculation are incremented only when a session finishes. It works quite well when serving small objects, but with big ones (for example large images or archives) or with A/V streaming, a graph generated from haproxy counters looks like a hedgehog. With this option enabled counters get incremented frequently along the session, typically every 5 seconds, which is often enough to produce clean graphs. Recounting touches a hotpath directly so it is not not enabled by default, as it can cause a lot of wakeups for very large session counts and cause a small performance drop.
Enable or disable logging of normal, successful connections
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
There are large sites dealing with several thousand connections per second and for which logging is a major pain. Some of them are even forced to turn logs off and cannot debug production issues. Setting this option ensures that normal connections, those which experience no error, no timeout, no retry nor redispatch, will not be logged. This leaves disk space for anomalies. In HTTP mode, the response status code is checked and return codes 5xx will still be logged. It is strongly discouraged to use this option as most of the time, the key to complex issues is in the normal logs which will not be logged here. If you need to separate logs, see the "log-separate-errors" option instead.
Enable or disable logging of null connections
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
In certain environments, there are components which will regularly connect to various systems to ensure that they are still alive. It can be the case from another load balancer as well as from monitoring systems. By default, even a simple port probe or scan will produce a log. If those connections pollute the logs too much, it is possible to enable option "dontlognull" to indicate that a connection on which no data has been transferred will not be logged, which typically corresponds to those probes. Note that errors will still be returned to the client and accounted for in the stats. If this is not what is desired, option http-ignore-probes can be used instead. It is generally recommended not to use this option in uncontrolled environments (e.g. internet), otherwise scans and other malicious activities would not be logged. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable insertion of the X-Forwarded-For header to requests sent to servers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<network> is an optional argument used to disable this option for sources matching <network> <name> an optional argument to specify a different "X-Forwarded-For" header name.
Since HAProxy works in reverse-proxy mode, the servers see its IP address as their client address. This is sometimes annoying when the client's IP address is expected in server logs. To solve this problem, the well-known HTTP header "X-Forwarded-For" may be added by HAProxy to all requests sent to the server. This header contains a value representing the client's IP address. Since this header is always appended at the end of the existing header list, the server must be configured to always use the last occurrence of this header only. See the server's manual to find how to enable use of this standard header. Note that only the last occurrence of the header must be used, since it is really possible that the client has already brought one. The keyword "header" may be used to supply a different header name to replace the default "X-Forwarded-For". This can be useful where you might already have a "X-Forwarded-For" header from a different application (e.g. stunnel), and you need preserve it. Also if your backend server doesn't use the "X-Forwarded-For" header and requires different one (e.g. Zeus Web Servers require "X-Cluster-Client-IP"). Sometimes, a same HAProxy instance may be shared between a direct client access and a reverse-proxy access (for instance when an SSL reverse-proxy is used to decrypt HTTPS traffic). It is possible to disable the addition of the header for a known source address or network by adding the "except" keyword followed by the network address. In this case, any source IP matching the network will not cause an addition of this header. Most common uses are with private networks or 127.0.0.1. Alternatively, the keyword "if-none" states that the header will only be added if it is not present. This should only be used in perfectly trusted environment, as this might cause a security issue if headers reaching haproxy are under the control of the end-user. This option may be specified either in the frontend or in the backend. If at least one of them uses it, the header will be added. Note that the backend's setting of the header subargument takes precedence over the frontend's if both are defined. In the case of the "if-none" argument, if at least one of the frontend or the backend does not specify it, it wants the addition to be mandatory, so it wins.
# Public HTTP address also used by stunnel on the same machine
frontend www
mode http
option forwardfor except 127.0.0.1 # stunnel already adds the header
# Those servers want the IP Address in X-Client
backend www
mode http
option forwardfor header X-Client
Enable or disable the case adjustment of HTTP/1 headers sent to bogus clients
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
There is no standard case for header names because, as stated in RFC7230, they are case-insensitive. So applications must handle them in a case- insensitive manner. But some bogus applications violate the standards and erroneously rely on the cases most commonly used by browsers. This problem becomes critical with HTTP/2 because all header names must be exchanged in lower case, and HAProxy follows the same convention. All header names are sent in lower case to clients and servers, regardless of the HTTP version. When HAProxy receives an HTTP/1 response, its header names are converted to lower case and manipulated and sent this way to the clients. If a client is known to violate the HTTP standards and to fail to process a response coming from HAProxy, it is possible to transform the lower case header names to a different format when the response is formatted and sent to the client, by enabling this option and specifying the list of headers to be reformatted using the global directives "h1-case-adjust" or "h1-case-adjust-file". This must only be a temporary workaround for the time it takes the client to be fixed, because clients which require such workarounds might be vulnerable to content smuggling attacks and must absolutely be fixed. Please note that this option will not affect standards-compliant clients. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable the case adjustment of HTTP/1 headers sent to bogus servers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
There is no standard case for header names because, as stated in RFC7230, they are case-insensitive. So applications must handle them in a case- insensitive manner. But some bogus applications violate the standards and erroneously rely on the cases most commonly used by browsers. This problem becomes critical with HTTP/2 because all header names must be exchanged in lower case, and HAProxy follows the same convention. All header names are sent in lower case to clients and servers, regardless of the HTTP version. When HAProxy receives an HTTP/1 request, its header names are converted to lower case and manipulated and sent this way to the servers. If a server is known to violate the HTTP standards and to fail to process a request coming from HAProxy, it is possible to transform the lower case header names to a different format when the request is formatted and sent to the server, by enabling this option and specifying the list of headers to be reformatted using the global directives "h1-case-adjust" or "h1-case-adjust-file". This must only be a temporary workaround for the time it takes the server to be fixed, because servers which require such workarounds might be vulnerable to content smuggling attacks and must absolutely be fixed. Please note that this option will not affect standards-compliant servers. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable waiting for whole HTTP request body before proceeding
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
It is sometimes desirable to wait for the body of an HTTP request before taking a decision. This is what is being done by "balance url_param" for example. The first use case is to buffer requests from slow clients before connecting to the server. Another use case consists in taking the routing decision based on the request body's contents. This option placed in a frontend or backend forces the HTTP processing to wait until either the whole body is received or the request buffer is full. It can have undesired side effects with some applications abusing HTTP by expecting unbuffered transmissions between the frontend and the backend, so this should definitely not be used by default.
Enable or disable logging of null connections and request timeouts
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
Recently some browsers started to implement a "pre-connect" feature consisting in speculatively connecting to some recently visited web sites just in case the user would like to visit them. This results in many connections being established to web sites, which end up in 408 Request Timeout if the timeout strikes first, or 400 Bad Request when the browser decides to close them first. These ones pollute the log and feed the error counters. There was already "option dontlognull" but it's insufficient in this case. Instead, this option does the following things : - prevent any 400/408 message from being sent to the client if nothing was received over a connection before it was closed; - prevent any log from being emitted in this situation; - prevent any error counter from being incremented That way the empty connection is silently ignored. Note that it is better not to use this unless it is clear that it is needed, because it will hide real problems. The most common reason for not receiving a request and seeing a 408 is due to an MTU inconsistency between the client and an intermediary element such as a VPN, which blocks too large packets. These issues are generally seen with POST requests as well as GET with large cookies. The logs are often the only way to detect them. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable HTTP keep-alive from client to server
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
By default HAProxy operates in keep-alive mode with regards to persistent connections: for each connection it processes each request and response, and leaves the connection idle on both sides between the end of a response and the start of a new request. This mode may be changed by several options such as "option http-server-close" or "option httpclose". This option allows to set back the keep-alive mode, which can be useful when another mode was used in a defaults section. Setting "option http-keep-alive" enables HTTP keep-alive mode on the client- and server- sides. This provides the lowest latency on the client side (slow network) and the fastest session reuse on the server side at the expense of maintaining idle connections to the servers. In general, it is possible with this option to achieve approximately twice the request rate that the "http-server-close" option achieves on small objects. There are mainly two situations where this option may be useful : - when the server is non-HTTP compliant and authenticates the connection instead of requests (e.g. NTLM authentication) - when the cost of establishing the connection to the server is significant compared to the cost of retrieving the associated object from the server. This last case can happen when the server is a fast static server of cache. In this case, the server will need to be properly tuned to support high enough connection counts because connections will last until the client sends another request. If the client request has to go to another backend or another server due to content switching or the load balancing algorithm, the idle connection will immediately be closed and a new one re-opened. Option "prefer-last-server" is available to try optimize server selection so that if the server currently attached to an idle connection is usable, it will be used. At the moment, logs will not indicate whether requests came from the same session or not. The accept date reported in the logs corresponds to the end of the previous request, and the request time corresponds to the time spent waiting for a new request. The keep-alive request time is still bound to the timeout defined by "timeout http-keep-alive" or "timeout http-request" if not set. This option disables and replaces any previous "option httpclose" or "option http-server-close". When backend and frontend options differ, all of these 4 options have precedence over "option http-keep-alive".
Instruct the system to favor low interactive delays over performance in HTTP
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
In HTTP, each payload is unidirectional and has no notion of interactivity. Any agent is expected to queue data somewhat for a reasonably low delay. There are some very rare server-to-server applications that abuse the HTTP protocol and expect the payload phase to be highly interactive, with many interleaved data chunks in both directions within a single request. This is absolutely not supported by the HTTP specification and will not work across most proxies or servers. When such applications attempt to do this through haproxy, it works but they will experience high delays due to the network optimizations which favor performance by instructing the system to wait for enough data to be available in order to only send full packets. Typical delays are around 200 ms per round trip. Note that this only happens with abnormal uses. Normal uses such as CONNECT requests nor WebSockets are not affected. When "option http-no-delay" is present in either the frontend or the backend used by a connection, all such optimizations will be disabled in order to make the exchanges as fast as possible. Of course this offers no guarantee on the functionality, as it may break at any other place. But if it works via HAProxy, it will work as fast as possible. This option should never be used by default, and should never be used at all unless such a buggy application is discovered. The impact of using this option is an increase of bandwidth usage and CPU usage, which may significantly lower performance in high latency environments.
Define whether haproxy will announce keepalive to the server or not
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When running with "option http-server-close" or "option httpclose", haproxy adds a "Connection: close" header to the request forwarded to the server. Unfortunately, when some servers see this header, they automatically refrain from using the chunked encoding for responses of unknown length, while this is totally unrelated. The immediate effect is that this prevents haproxy from maintaining the client connection alive. A second effect is that a client or a cache could receive an incomplete response without being aware of it, and consider the response complete. By setting "option http-pretend-keepalive", haproxy will make the server believe it will keep the connection alive. The server will then not fall back to the abnormal undesired above. When haproxy gets the whole response, it will close the connection with the server just as it would do with the "option httpclose". That way the client gets a normal response and the connection is correctly closed on the server side. It is recommended not to enable this option by default, because most servers will more efficiently close the connection themselves after the last packet, and release its buffers slightly earlier. Also, the added packet on the network could slightly reduce the overall peak performance. However it is worth noting that when this option is enabled, haproxy will have slightly less work to do. So if haproxy is the bottleneck on the whole architecture, enabling this option might save a few CPU cycles. This option may be set in backend and listen sections. Using it in a frontend section will be ignored and a warning will be reported during startup. It is a backend related option, so there is no real reason to set it on a frontend. This option may be combined with "option httpclose", which will cause keepalive to be announced to the server and close to be announced to the client. This practice is discouraged though. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable HTTP connection closing on the server side
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
By default HAProxy operates in keep-alive mode with regards to persistent connections: for each connection it processes each request and response, and leaves the connection idle on both sides between the end of a response and the start of a new request. This mode may be changed by several options such as "option http-server-close" or "option httpclose". Setting "option http-server-close" enables HTTP connection-close mode on the server side while keeping the ability to support HTTP keep-alive and pipelining on the client side. This provides the lowest latency on the client side (slow network) and the fastest session reuse on the server side to save server resources, similarly to "option httpclose". It also permits non-keepalive capable servers to be served in keep-alive mode to the clients if they conform to the requirements of RFC7230. Please note that some servers do not always conform to those requirements when they see "Connection: close" in the request. The effect will be that keep-alive will never be used. A workaround consists in enabling "option http-pretend-keepalive". At the moment, logs will not indicate whether requests came from the same session or not. The accept date reported in the logs corresponds to the end of the previous request, and the request time corresponds to the time spent waiting for a new request. The keep-alive request time is still bound to the timeout defined by "timeout http-keep-alive" or "timeout http-request" if not set. This option may be set both in a frontend and in a backend. It is enabled if at least one of the frontend or backend holding a connection has it enabled. It disables and replaces any previous "option httpclose" or "option http-keep-alive". Please check section 4 ("Proxies") to see how this option combines with others when frontend and backend options differ. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Make use of non-standard Proxy-Connection header instead of Connection
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
While RFC7230 explicitly states that HTTP/1.1 agents must use the Connection header to indicate their wish of persistent or non-persistent connections, both browsers and proxies ignore this header for proxied connections and make use of the undocumented, non-standard Proxy-Connection header instead. The issue begins when trying to put a load balancer between browsers and such proxies, because there will be a difference between what haproxy understands and what the client and the proxy agree on. By setting this option in a frontend, haproxy can automatically switch to use that non-standard header if it sees proxied requests. A proxied request is defined here as one where the URI begins with neither a '/' nor a '*'. This is incompatible with the HTTP tunnel mode. Note that this option can only be specified in a frontend and will affect the request along its whole life. Also, when this option is set, a request which requires authentication will automatically switch to use proxy authentication headers if it is itself a proxied request. That makes it possible to check or enforce authentication in front of an existing proxy. This option should normally never be used, except in front of a proxy.
Enable HTTP protocol to check on the servers health
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<method> is the optional HTTP method used with the requests. When not set, the "OPTIONS" method is used, as it generally requires low server processing and is easy to filter out from the logs. Any method may be used, though it is not recommended to invent non-standard ones. <uri> is the URI referenced in the HTTP requests. It defaults to " / " which is accessible by default on almost any server, but may be changed to any other URI. Query strings are permitted. <version> is the optional HTTP version string. It defaults to "HTTP/1.0" but some servers might behave incorrectly in HTTP 1.0, so turning it to HTTP/1.1 may sometimes help. Note that the Host field is mandatory in HTTP/1.1, use "http-check send" directive to add it.
By default, server health checks only consist in trying to establish a TCP connection. When "option httpchk" is specified, a complete HTTP request is sent once the TCP connection is established, and responses 2xx and 3xx are considered valid, while all other ones indicate a server failure, including the lack of any response. The port and interval are specified in the server configuration. This option does not necessarily require an HTTP backend, it also works with plain TCP backends. This is particularly useful to check simple scripts bound to some dedicated ports using the inetd daemon. Note : For a while, there was no way to add headers or body in the request used for HTTP health checks. So a workaround was to hide it at the end of the version string with a "\r\n" after the version. It is now deprecated. The directive "http-check send" must be used instead.
# Relay HTTPS traffic to Apache instance and check service availability
# using HTTP request "OPTIONS * HTTP/1.1" on port 80.
backend https_relay
mode tcp
option httpchk OPTIONS * HTTP/1.1
http-check send hdr Host www
server apache1 192.168.1.1:443 check port 80
Enable or disable HTTP connection closing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
By default HAProxy operates in keep-alive mode with regards to persistent connections: for each connection it processes each request and response, and leaves the connection idle on both sides between the end of a response and the start of a new request. This mode may be changed by several options such as "option http-server-close" or "option httpclose". If "option httpclose" is set, HAProxy will close connections with the server and the client as soon as the request and the response are received. It will also check if a "Connection: close" header is already set in each direction, and will add one if missing. Any "Connection" header different from "close" will also be removed. This option may also be combined with "option http-pretend-keepalive", which will disable sending of the "Connection: close" header, but will still cause the connection to be closed once the whole response is received. This option may be set both in a frontend and in a backend. It is enabled if at least one of the frontend or backend holding a connection has it enabled. It disables and replaces any previous "option http-server-close" or "option http-keep-alive". Please check section 4 ("Proxies") to see how this option combines with others when frontend and backend options differ. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable logging of HTTP request, session state and timers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
clf if the "clf" argument is added, then the output format will be the CLF format instead of HAProxy's default HTTP format. You can use this when you need to feed HAProxy's logs through a specific log analyzer which only support the CLF format and which is not extensible.
By default, the log output format is very poor, as it only contains the source and destination addresses, and the instance name. By specifying "option httplog", each log line turns into a much richer format including, but not limited to, the HTTP request, the connection timers, the session status, the connections numbers, the captured headers and cookies, the frontend, backend and server name, and of course the source address and ports. Specifying only "option httplog" will automatically clear the 'clf' mode if it was set by default. "option httplog" overrides any previous "log-format" directive.
Enable or disable plain HTTP proxy mode
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
It sometimes happens that people need a pure HTTP proxy which understands basic proxy requests without caching nor any fancy feature. In this case, it may be worth setting up an HAProxy instance with the "option http_proxy" set. In this mode, no server is declared, and the connection is forwarded to the IP address and port found in the URL after the "http://" scheme. No host address resolution is performed, so this only works when pure IP addresses are passed. Since this option's usage perimeter is rather limited, it will probably be used only by experts who know they need exactly it. This is incompatible with the HTTP tunnel mode. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
# this backend understands HTTP proxy requests and forwards them directly.
backend direct_forward
option httpclose
option http_proxy
Enable or disable independent timeout processing for both directions
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
By default, when data is sent over a socket, both the write timeout and the read timeout for that socket are refreshed, because we consider that there is activity on that socket, and we have no other means of guessing if we should receive data or not. While this default behavior is desirable for almost all applications, there exists a situation where it is desirable to disable it, and only refresh the read timeout if there are incoming data. This happens on sessions with large timeouts and low amounts of exchanged data such as telnet session. If the server suddenly disappears, the output data accumulates in the system's socket buffers, both timeouts are correctly refreshed, and there is no way to know the server does not receive them, so we don't timeout. However, when the underlying protocol always echoes sent data, it would be enough by itself to detect the issue using the read timeout. Note that this problem does not happen with more verbose protocols because data won't accumulate long in the socket buffers. When this option is set on the frontend, it will disable read timeout updates on data sent to the client. There probably is little use of this case. When the option is set on the backend, it will disable read timeout updates on data sent to the server. Doing so will typically break large HTTP posts from slow lines, so use it with caution.
Use LDAPv3 health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
It is possible to test that the server correctly talks LDAPv3 instead of just testing that it accepts the TCP connection. When this option is set, an LDAPv3 anonymous simple bind message is sent to the server, and the response is analyzed to find an LDAPv3 bind response message. The server is considered valid only when the LDAP response contains success resultCode (http://tools.ietf.org/html/rfc4511#section-4.1.9). Logging of bind requests is server dependent see your documentation how to configure it.
option ldap-check
Use external processes for server health checks
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
It is possible to test the health of a server using an external command.
This is achieved by running the executable set using "external-check
command".
Requires the "external-check" global to be set.
Enable or disable logging of health checks status updates
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
By default, failed health check are logged if server is UP and successful health checks are logged if server is DOWN, so the amount of additional information is limited. When this option is enabled, any change of the health check status or to the server's health will be logged, so that it becomes possible to know that a server was failing occasional checks before crashing, or exactly when it failed to respond a valid HTTP status, then when the port started to reject connections, then when the server stopped responding at all. Note that status changes not caused by health checks (e.g. enable/disable on the CLI) are intentionally not logged by this option.
Change log level for non-completely successful connections
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
Sometimes looking for errors in logs is not easy. This option makes haproxy raise the level of logs containing potentially interesting information such as errors, timeouts, retries, redispatches, or HTTP status codes 5xx. The level changes from "info" to "err". This makes it possible to log them separately to a different file with most syslog daemons. Be careful not to remove them from the original file, otherwise you would lose ordering which provides very important information. Using this option, large sites dealing with several thousand connections per second may log normal traffic to a rotating buffer and only archive smaller error logs.
Enable or disable early logging.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
By default, logs are emitted when all the log format variables and sample fetches used in the definition of the log-format string return a value, or when the session is terminated. This allows the built in log-format strings to account for the transfer time, or the number of bytes in log messages. When handling long lived connections such as large file transfers or RDP, it may take a while for the request or connection to appear in the logs. Using "option logasap", the log message is created as soon as the server connection is established in mode tcp, or as soon as the server sends the complete headers in mode http. Missing information in the logs will be the total number of bytes which will only indicate the amount of data transfered before the message was created and the total time which will not take the remainder of the connection life or transfer time into account. For the case of HTTP, it is good practice to capture the Content-Length response header so that the logs at least indicate how many bytes are expected to be transfered.
listen http_proxy 0.0.0.0:80
mode http
option httplog
option logasap
log 192.168.2.200 local3
>>> Feb 6 12:14:14 localhost \
haproxy[14389]: 10.0.1.2:33317 [06/Feb/2009:12:14:14.655] http-in \
static/srv1 9/10/7/14/+30 200 +243 - - ---- 3/1/1/1/0 1/0 \
"GET /image.iso HTTP/1.0"
Use MySQL health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<username> This is the username which will be used when connecting to MySQL server. post-41 Send post v4.1 client compatible checks
If you specify a username, the check consists of sending two MySQL packet,
one Client Authentication packet, and one QUIT packet, to correctly close
MySQL session. We then parse the MySQL Handshake Initialization packet and/or
Error packet. It is a basic but useful test which does not produce error nor
aborted connect on the server. However, it requires adding an authorization
in the MySQL table, like this :
USE mysql;
INSERT INTO user (Host,User) values ('<ip_of_haproxy>','<username>');
FLUSH PRIVILEGES;
If you don't specify a username (it is deprecated and not recommended), the
check only consists in parsing the Mysql Handshake Initialization packet or
Error packet, we don't send anything in this mode. It was reported that it
can generate lockout if check is too frequent and/or if there is not enough
traffic. In fact, you need in this case to check MySQL "max_connect_errors"
value as if a connection is established successfully within fewer than MySQL
"max_connect_errors" attempts after a previous connection was interrupted,
the error count for the host is cleared to zero. If HAProxy's server get
blocked, the "FLUSH HOSTS" statement is the only way to unblock it.
Remember that this does not check database presence nor database consistency.
To do this, you can use an external check with xinetd for example.
The check requires MySQL >=3.22, for older version, please use TCP check.
Most often, an incoming MySQL server needs to see the client's IP address for
various purposes, including IP privilege matching and connection logging.
When possible, it is often wise to masquerade the client's IP address when
connecting to the server using the "usesrc" argument of the "source" keyword,
which requires the transparent proxy feature to be compiled in, and the MySQL
server to route the client via the machine hosting haproxy.
Enable or disable immediate session resource cleaning after close
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
When clients or servers abort connections in a dirty way (e.g. they are physically disconnected), the session timeouts triggers and the session is closed. But it will remain in FIN_WAIT1 state for some time in the system, using some resources and possibly limiting the ability to establish newer connections. When this happens, it is possible to activate "option nolinger" which forces the system to immediately remove any socket's pending data on close. Thus, the session is instantly purged from the system's tables. This usually has side effects such as increased number of TCP resets due to old retransmits getting immediately rejected. Some firewalls may sometimes complain about this too. For this reason, it is not recommended to use this option when not absolutely needed. You know that you need it when you have thousands of FIN_WAIT1 sessions on your system (TIME_WAIT ones do not count). This option may be used both on frontends and backends, depending on the side where it is required. Use it on the frontend for clients, and on the backend for servers. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable insertion of the X-Original-To header to requests sent to servers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<network> is an optional argument used to disable this option for sources matching <network> <name> an optional argument to specify a different "X-Original-To" header name.
Since HAProxy can work in transparent mode, every request from a client can be redirected to the proxy and HAProxy itself can proxy every request to a complex SQUID environment and the destination host from SO_ORIGINAL_DST will be lost. This is annoying when you want access rules based on destination ip addresses. To solve this problem, a new HTTP header "X-Original-To" may be added by HAProxy to all requests sent to the server. This header contains a value representing the original destination IP address. Since this must be configured to always use the last occurrence of this header only. Note that only the last occurrence of the header must be used, since it is really possible that the client has already brought one. The keyword "header" may be used to supply a different header name to replace the default "X-Original-To". This can be useful where you might already have a "X-Original-To" header from a different application, and you need preserve it. Also if your backend server doesn't use the "X-Original-To" header and requires different one. Sometimes, a same HAProxy instance may be shared between a direct client access and a reverse-proxy access (for instance when an SSL reverse-proxy is used to decrypt HTTPS traffic). It is possible to disable the addition of the header for a known source address or network by adding the "except" keyword followed by the network address. In this case, any source IP matching the network will not cause an addition of this header. Most common uses are with private networks or 127.0.0.1. This option may be specified either in the frontend or in the backend. If at least one of them uses it, the header will be added. Note that the backend's setting of the header subargument takes precedence over the frontend's if both are defined.
# Original Destination address
frontend www
mode http
option originalto except 127.0.0.1
# Those servers want the IP Address in X-Client-Dst
backend www
mode http
option originalto header X-Client-Dst
Enable or disable forced persistence on down servers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When an HTTP request reaches a backend with a cookie which references a dead server, by default it is redispatched to another server. It is possible to force the request to be sent to the dead server first using "option persist" if absolutely needed. A common use case is when servers are under extreme load and spend their time flapping. In this case, the users would still be directed to the server they opened the session on, in the hope they would be correctly served. It is recommended to use "option redispatch" in conjunction with this option so that in the event it would not be possible to connect to the server at all (server definitely dead), the client would finally be redirected to another valid server. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Use PostgreSQL health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<username> This is the username which will be used when connecting to PostgreSQL server.
The check sends a PostgreSQL StartupMessage and waits for either Authentication request or ErrorResponse message. It is a basic but useful test which does not produce error nor aborted connect on the server. This check is identical with the "mysql-check".
Allow multiple load balanced requests to remain on the same server
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When the load balancing algorithm in use is not deterministic, and a previous request was sent to a server to which haproxy still holds a connection, it is sometimes desirable that subsequent requests on a same session go to the same server as much as possible. Note that this is different from persistence, as we only indicate a preference which haproxy tries to apply without any form of warranty. The real use is for keep-alive connections sent to servers. When this option is used, haproxy will try to reuse the same connection that is attached to the server instead of rebalancing to another server, causing a close of the connection. This can make sense for static file servers. It does not make much sense to use this in combination with hashing algorithms. Note, haproxy already automatically tries to stick to a server which sends a 401 or to a proxy which sends a 407 (authentication required), when the load balancing algorithm is not deterministic. This is mandatory for use with the broken NTLM authentication challenge, and significantly helps in troubleshooting some faulty applications. Option prefer-last-server might be desirable in these environments as well, to avoid redistributing the traffic after every other response. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable session redistribution in case of connection failure
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<interval> The optional integer value that controls how often redispatches occur when retrying connections. Positive value P indicates a redispatch is desired on every Pth retry, and negative value N indicate a redispatch is desired on the Nth retry prior to the last retry. For example, the default of -1 preserves the historical behavior of redispatching on the last retry, a positive value of 1 would indicate a redispatch on every retry, and a positive value of 3 would indicate a redispatch on every third retry. You can disable redispatches with a value of 0.
In HTTP mode, if a server designated by a cookie is down, clients may definitely stick to it because they cannot flush the cookie, so they will not be able to access the service anymore. Specifying "option redispatch" will allow the proxy to break cookie or consistent hash based persistence and redistribute them to a working server. It also allows to retry connections to another server in case of multiple connection failures. Of course, it requires having "retries" set to a nonzero value. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Use redis health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
It is possible to test that the server correctly talks REDIS protocol instead of just testing that it accepts the TCP connection. When this option is set, a PING redis command is sent to the server, and the response is analyzed to find the "+PONG" response message.
option redis-check
Use SMTP health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<hello> is an optional argument. It is the "hello" command to use. It can be either "HELO" (for SMTP) or "EHLO" (for ESMTP). All other values will be turned into the default command ("HELO"). <domain> is the domain name to present to the server. It may only be specified (and is mandatory) if the hello command has been specified. By default, "localhost" is used.
When "option smtpchk" is set, the health checks will consist in TCP connections followed by an SMTP command. By default, this command is "HELO localhost". The server's return code is analyzed and only return codes starting with a "2" will be considered as valid. All other responses, including a lack of response will constitute an error and will indicate a dead server. This test is meant to be used with SMTP servers or relays. Depending on the request, it is possible that some servers do not log each connection attempt, so you may want to experiment to improve the behavior. Using telnet on port 25 is often easier than adjusting the configuration. Most often, an incoming SMTP server needs to see the client's IP address for various purposes, including spam filtering, anti-spoofing and logging. When possible, it is often wise to masquerade the client's IP address when connecting to the server using the "usesrc" argument of the "source" keyword, which requires the transparent proxy feature to be compiled in.
option smtpchk HELO mydomain.org
Enable or disable collecting & providing separate statistics for each socket.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
Enable or disable automatic kernel acceleration on sockets in both directions
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
When this option is enabled either on a frontend or on a backend, haproxy will automatically evaluate the opportunity to use kernel tcp splicing to forward data between the client and the server, in either direction. HAProxy uses heuristics to estimate if kernel splicing might improve performance or not. Both directions are handled independently. Note that the heuristics used are not much aggressive in order to limit excessive use of splicing. This option requires splicing to be enabled at compile time, and may be globally disabled with the global option "nosplice". Since splice uses pipes, using it requires that there are enough spare pipes. Important note: kernel-based TCP splicing is a Linux-specific feature which first appeared in kernel 2.6.25. It offers kernel-based acceleration to transfer data between sockets without copying these data to user-space, thus providing noticeable performance gains and CPU cycles savings. Since many early implementations are buggy, corrupt data and/or are inefficient, this feature is not enabled by default, and it should be used with extreme care. While it is not possible to detect the correctness of an implementation, 2.6.29 is the first version offering a properly working implementation. In case of doubt, splicing may be globally disabled using the global "nosplice" keyword.
option splice-auto
If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable automatic kernel acceleration on sockets for requests
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
When this option is enabled either on a frontend or on a backend, haproxy will use kernel tcp splicing whenever possible to forward data going from the client to the server. It might still use the recv/send scheme if there are no spare pipes left. This option requires splicing to be enabled at compile time, and may be globally disabled with the global option "nosplice". Since splice uses pipes, using it requires that there are enough spare pipes. Important note: see "option splice-auto" for usage limitations.
option splice-request
If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable automatic kernel acceleration on sockets for responses
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
When this option is enabled either on a frontend or on a backend, haproxy will use kernel tcp splicing whenever possible to forward data going from the server to the client. It might still use the recv/send scheme if there are no spare pipes left. This option requires splicing to be enabled at compile time, and may be globally disabled with the global option "nosplice". Since splice uses pipes, using it requires that there are enough spare pipes. Important note: see "option splice-auto" for usage limitations.
option splice-response
If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Use SPOP health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | no | yes |
It is possible to test that the server correctly talks SPOP protocol instead of just testing that it accepts the TCP connection. When this option is set, a HELLO handshake is performed between HAProxy and the server, and the response is analyzed to check no error is reported.
option spop-check
Enable or disable the sending of TCP keepalive packets on the server side
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When there is a firewall or any session-aware component between a client and a server, and when the protocol involves very long sessions with long idle periods (e.g. remote desktops), there is a risk that one of the intermediate components decides to expire a session which has remained idle for too long. Enabling socket-level TCP keep-alives makes the system regularly send packets to the other end of the connection, leaving it active. The delay between keep-alive probes is controlled by the system only and depends both on the operating system and its tuning parameters. It is important to understand that keep-alive packets are neither emitted nor received at the application level. It is only the network stacks which sees them. For this reason, even if one side of the proxy already uses keep-alives to maintain its connection alive, those keep-alive packets will not be forwarded to the other side of the proxy. Please note that this has nothing to do with HTTP keep-alive. Using option "srvtcpka" enables the emission of TCP keep-alive probes on the server side of a connection, which should help when session expirations are noticed between HAProxy and a server. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Use SSLv3 client hello health checks for server testing
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
When some SSL-based protocols are relayed in TCP mode through HAProxy, it is possible to test that the server correctly talks SSL instead of just testing that it accepts the TCP connection. When "option ssl-hello-chk" is set, pure SSLv3 client hello messages are sent once the connection is established to the server, and the response is analyzed to find an SSL server hello message. The server is considered valid only when the response contains this server hello message. All servers tested till there correctly reply to SSLv3 client hello messages, and most servers tested do not even log the requests containing only hello messages, which is appreciable. Note that this check works even when SSL support was not built into haproxy because it forges the SSL message. When SSL support is available, it is best to use native SSL health checks instead of this one.
Perform health checks using tcp-check send/expect sequences
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
This health check method is intended to be combined with "tcp-check" command lists in order to support send/expect types of health check sequences. TCP checks currently support 4 modes of operations : - no "tcp-check" directive : the health check only consists in a connection attempt, which remains the default mode. - "tcp-check send" or "tcp-check send-binary" only is mentioned : this is used to send a string along with a connection opening. With some protocols, it helps sending a "QUIT" message for example that prevents the server from logging a connection error for each health check. The check result will still be based on the ability to open the connection only. - "tcp-check expect" only is mentioned : this is used to test a banner. The connection is opened and haproxy waits for the server to present some contents which must validate some rules. The check result will be based on the matching between the contents and the rules. This is suited for POP, IMAP, SMTP, FTP, SSH, TELNET. - both "tcp-check send" and "tcp-check expect" are mentioned : this is used to test a hello-type protocol. HAProxy sends a message, the server responds and its response is analyzed. the check result will be based on the matching between the response contents and the rules. This is often suited for protocols which require a binding or a request/response model. LDAP, MySQL, Redis and SSL are example of such protocols, though they already all have their dedicated checks with a deeper understanding of the respective protocols. In this mode, many questions may be sent and many answers may be analyzed. A fifth mode can be used to insert comments in different steps of the script. For each tcp-check rule you create, you can add a "comment" directive, followed by a string. This string will be reported in the log and stderr in debug mode. It is useful to make user-friendly error reporting. The "comment" is of course optional.
# perform a POP check (analyze only server's banner)
option tcp-check
tcp-check expect string +OK\ POP3\ ready comment POP\ protocol
# perform an IMAP check (analyze only server's banner)
option tcp-check
tcp-check expect string *\ OK\ IMAP4\ ready comment IMAP\ protocol
# look for the redis master server after ensuring it speaks well
# redis protocol, then it exits properly.
# (send a command then analyze the response 3 times)
option tcp-check
tcp-check comment PING\ phase
tcp-check send PING\r\n
tcp-check expect string +PONG
tcp-check comment role\ check
tcp-check send info\ replication\r\n
tcp-check expect string role:master
tcp-check comment QUIT\ phase
tcp-check send QUIT\r\n
tcp-check expect string +OK
forge a HTTP request, then analyze the response
(send many headers before analyzing)
option tcp-check
tcp-check comment forge\ and\ send\ HTTP\ request
tcp-check send HEAD\ /\ HTTP/1.1\r\n
tcp-check send Host:\ www.mydomain.com\r\n
tcp-check send User-Agent:\ HAProxy\ tcpcheck\r\n
tcp-check send \r\n
tcp-check expect rstring HTTP/1\..\ (2..|3..) comment check\ HTTP\ response
Enable or disable the saving of one ACK packet during the accept sequence
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
When an HTTP connection request comes in, the system acknowledges it on behalf of HAProxy, then the client immediately sends its request, and the system acknowledges it too while it is notifying HAProxy about the new connection. HAProxy then reads the request and responds. This means that we have one TCP ACK sent by the system for nothing, because the request could very well be acknowledged by HAProxy when it sends its response. For this reason, in HTTP mode, HAProxy automatically asks the system to avoid sending this useless ACK on platforms which support it (currently at least Linux). It must not cause any problem, because the system will send it anyway after 40 ms if the response takes more time than expected to come. During complex network debugging sessions, it may be desirable to disable this optimization because delayed ACKs can make troubleshooting more complex when trying to identify where packets are delayed. It is then possible to fall back to normal behavior by specifying "no option tcp-smart-accept". It is also possible to force it for non-HTTP proxies by simply specifying "option tcp-smart-accept". For instance, it can make sense with some services such as SMTP where the server speaks first. It is recommended to avoid forcing this option in a defaults section. In case of doubt, consider setting it back to automatic values by prepending the "default" keyword before it, or disabling it using the "no" keyword.
Enable or disable the saving of one ACK packet during the connect sequence
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
On certain systems (at least Linux), HAProxy can ask the kernel not to immediately send an empty ACK upon a connection request, but to directly send the buffer request instead. This saves one packet on the network and thus boosts performance. It can also be useful for some servers, because they immediately get the request along with the incoming connection. This feature is enabled when "option tcp-smart-connect" is set in a backend. It is not enabled by default because it makes network troubleshooting more complex. It only makes sense to enable it with protocols where the client speaks first such as HTTP. In other situations, if there is no data to send in place of the ACK, a normal ACK is sent. If this option has been enabled in a "defaults" section, it can be disabled in a specific instance by prepending the "no" keyword before it.
Enable or disable the sending of TCP keepalive packets on both sides
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
When there is a firewall or any session-aware component between a client and a server, and when the protocol involves very long sessions with long idle periods (e.g. remote desktops), there is a risk that one of the intermediate components decides to expire a session which has remained idle for too long. Enabling socket-level TCP keep-alives makes the system regularly send packets to the other end of the connection, leaving it active. The delay between keep-alive probes is controlled by the system only and depends both on the operating system and its tuning parameters. It is important to understand that keep-alive packets are neither emitted nor received at the application level. It is only the network stacks which sees them. For this reason, even if one side of the proxy already uses keep-alives to maintain its connection alive, those keep-alive packets will not be forwarded to the other side of the proxy. Please note that this has nothing to do with HTTP keep-alive. Using option "tcpka" enables the emission of TCP keep-alive probes on both the client and server sides of a connection. Note that this is meaningful only in "defaults" or "listen" sections. If this option is used in a frontend, only the client side will get keep-alives, and if this option is used in a backend, only the server side will get keep-alives. For this reason, it is strongly recommended to explicitly use "option clitcpka" and "option srvtcpka" when the configuration is split between frontends and backends.
Enable advanced logging of TCP connections with session state and timers
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
By default, the log output format is very poor, as it only contains the source and destination addresses, and the instance name. By specifying "option tcplog", each log line turns into a much richer format including, but not limited to, the connection timers, the session status, the connections numbers, the frontend, backend and server name, and of course the source address and ports. This option is useful for pure TCP proxies in order to find which of the client or server disconnects or times out. For normal HTTP proxies, it's better to use "option httplog" which is even more complete. "option tcplog" overrides any previous "log-format" directive.
Enable client-side transparent proxying
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
This option was introduced in order to provide layer 7 persistence to layer 3 load balancers. The idea is to use the OS's ability to redirect an incoming connection for a remote address to a local process (here HAProxy), and let this process know what address was initially requested. When this option is used, sessions without cookies will be forwarded to the original destination IP address of the incoming request (which should match that of another equipment), while requests with cookies will still be forwarded to the appropriate server. Note that contrary to a common belief, this option does NOT make HAProxy present the client's IP to the server when establishing the connection.
Executable to run when performing an external-check
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<command> is the external command to run
The arguments passed to the to the command are: <proxy_address> <proxy_port> <server_address> <server_port> The <proxy_address> and <proxy_port> are derived from the first listener that is either IPv4, IPv6 or a UNIX socket. In the case of a UNIX socket listener the proxy_address will be the path of the socket and the <proxy_port> will be the string "NOT_USED". In a backend section, it's not possible to determine a listener, and both <proxy_address> and <proxy_port> will have the string value "NOT_USED". Some values are also provided through environment variables. Environment variables : HAPROXY_PROXY_ADDR The first bind address if available (or empty if not applicable, for example in a "backend" section). HAPROXY_PROXY_ID The backend id. HAPROXY_PROXY_NAME The backend name. HAPROXY_PROXY_PORT The first bind port if available (or empty if not applicable, for example in a "backend" section or for a UNIX socket). HAPROXY_SERVER_ADDR The server address. HAPROXY_SERVER_CURCONN The current number of connections on the server. HAPROXY_SERVER_ID The server id. HAPROXY_SERVER_MAXCONN The server max connections. HAPROXY_SERVER_NAME The server name. HAPROXY_SERVER_PORT The server port if available (or empty for a UNIX socket). PATH The PATH environment variable used when executing the command may be set using "external-check path". See also "2.3. Environment variables" for other variables. If the command executed and exits with a zero status then the check is considered to have passed, otherwise the check is considered to have failed.
external-check command /bin/true
The value of the PATH environment variable used when running an external-check
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<path> is the path used when executing external command to run
The default path is "".
external-check path "/usr/bin:/bin"
Enable RDP cookie-based persistence
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<name> is the optional name of the RDP cookie to check. If omitted, the default cookie name "msts" will be used. There currently is no valid reason to change this name.
This statement enables persistence based on an RDP cookie. The RDP cookie contains all information required to find the server in the list of known servers. So when this option is set in the backend, the request is analyzed and if an RDP cookie is found, it is decoded. If it matches a known server which is still UP (or if "option persist" is set), then the connection is forwarded to this server. Note that this only makes sense in a TCP backend, but for this to work, the frontend must have waited long enough to ensure that an RDP cookie is present in the request buffer. This is the same requirement as with the "rdp-cookie" load-balancing method. Thus it is highly recommended to put all statements in a single "listen" section. Also, it is important to understand that the terminal server will emit this RDP cookie only if it is configured for "token redirection mode", which means that the "IP address redirection" option is disabled.
listen tse-farm
bind :3389
# wait up to 5s for an RDP cookie in the request
tcp-request inspect-delay 5s
tcp-request content accept if RDP_COOKIE
# apply RDP cookie persistence
persist rdp-cookie
# if server is unknown, let's balance on the same cookie.
# alternatively, "balance leastconn" may be useful too.
balance rdp-cookie
server srv1 1.1.1.1:3389
server srv2 1.1.1.2:3389
Set a limit on the number of new sessions accepted per second on a frontend
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<rate> The <rate> parameter is an integer designating the maximum number of new sessions per second to accept on the frontend.
When the frontend reaches the specified number of new sessions per second, it
stops accepting new connections until the rate drops below the limit again.
During this time, the pending sessions will be kept in the socket's backlog
(in system buffers) and haproxy will not even be aware that sessions are
pending. When applying very low limit on a highly loaded service, it may make
sense to increase the socket's backlog using the "backlog" keyword.
This feature is particularly efficient at blocking connection-based attacks
or service abuse on fragile servers. Since the session rate is measured every
millisecond, it is extremely accurate. Also, the limit applies immediately,
no delay is needed at all to detect the threshold.
Limit the connection rate on SMTP to 10 per second maxlisten smtp mode tcp bind :25 rate-limit sessions 10 server smtp1 127.0.0.1:1025
Note : when the maximum rate is reached, the frontend's status is not changed but its sockets appear as "WAITING" in the statistics if the "socket-stats" option is enabled.
Return an HTTP redirection if/unless a condition is matched
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
If/unless the condition is matched, the HTTP request will lead to a redirect response. If no condition is specified, the redirect applies unconditionally.
<loc> With "redirect location", the exact value in <loc> is placed into the HTTP "Location" header. When used in an "http-request" rule, <loc> value follows the log-format rules and can include some dynamic values (see Custom Log Format in section 8.2.4). <pfx> With "redirect prefix", the "Location" header is built from the concatenation of <pfx> and the complete URI path, including the query string, unless the "drop-query" option is specified (see below). As a special case, if <pfx> equals exactly "/", then nothing is inserted before the original URI. It allows one to redirect to the same URL (for instance, to insert a cookie). When used in an "http-request" rule, <pfx> value follows the log-format rules and can include some dynamic values (see Custom Log Format in section 8.2.4). <sch> With "redirect scheme", then the "Location" header is built by concatenating <sch> with "://" then the first occurrence of the "Host" header, and then the URI path, including the query string unless the "drop-query" option is specified (see below). If no path is found or if the path is "*", then "/" is used instead. If no "Host" header is found, then an empty host component will be returned, which most recent browsers interpret as redirecting to the same host. This directive is mostly used to redirect HTTP to HTTPS. When used in an "http-request" rule, <sch> value follows the log-format rules and can include some dynamic values (see Custom Log Format in section 8.2.4). <code> The code is optional. It indicates which type of HTTP redirection is desired. Only codes 301, 302, 303, 307 and 308 are supported, with 302 used by default if no code is specified. 301 means "Moved permanently", and a browser may cache the Location. 302 means "Moved temporarily" and means that the browser should not cache the redirection. 303 is equivalent to 302 except that the browser will fetch the location with a GET method. 307 is just like 302 but makes it clear that the same method must be reused. Likewise, 308 replaces 301 if the same method must be used. <option> There are several options which can be specified to adjust the expected behavior of a redirection : - "drop-query" When this keyword is used in a prefix-based redirection, then the location will be set without any possible query-string, which is useful for directing users to a non-secure page for instance. It has no effect with a location-type redirect. - "append-slash" This keyword may be used in conjunction with "drop-query" to redirect users who use a URL not ending with a '/' to the same one with the '/'. It can be useful to ensure that search engines will only see one URL. For this, a return code 301 is preferred. - "set-cookie NAME[=value]" A "Set-Cookie" header will be added with NAME (and optionally "=value") to the response. This is sometimes used to indicate that a user has been seen, for instance to protect against some types of DoS. No other cookie option is added, so the cookie will be a session cookie. Note that for a browser, a sole cookie name without an equal sign is different from a cookie with an equal sign. - "clear-cookie NAME[=]" A "Set-Cookie" header will be added with NAME (and optionally "="), but with the "Max-Age" attribute set to zero. This will tell the browser to delete this cookie. It is useful for instance on logout pages. It is important to note that clearing the cookie "NAME" will not remove a cookie set with "NAME=value". You have to clear the cookie "NAME=" for that, because the browser makes the difference.
Move the login URL only to HTTPS.acl clear dst_port 80 acl secure dst_port 8080 acl login_page url_beg /login acl logout url_beg /logout acl uid_given url_reg /login?userid=[^&]+ acl cookie_set hdr_sub(cookie) SEEN=1 redirect prefix https://mysite.com set-cookie SEEN=1 if !cookie_set redirect prefix https://mysite.com if login_page !secure redirect prefix http://mysite.com drop-query if login_page !uid_given redirect location http://mysite.com/ if !login_page secure redirect location / clear-cookie USERID= if logout
Send redirects for request for articles without a '/'.acl missing_slash path_reg ^/article/[^/]*$ redirect code 301 prefix / drop-query append-slash if missing_slash
Redirect all HTTP traffic to HTTPS when SSL is handled by haproxy.redirect scheme https if !{ ssl_fc }
Append 'www.' prefix in front of all hosts not having ithttp-request redirect code 301 location \ http://www.%[hdr(host)]%[capture.req.uri] \ unless { hdr_beg(host) -i www }
See section 7 about ACL usage.
Set the number of retries to perform on a server after a connection failure
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<value> is the number of times a connection attempt should be retried on a server when a connection either is refused or times out. The default value is 3.
It is important to understand that this value applies to the number of connection attempts, not full requests. When a connection has effectively been established to a server, there will be no more retry. In order to avoid immediate reconnections to a server which is restarting, a turn-around timer of min("timeout connect", one second) is applied before a retry occurs. When "option redispatch" is set, the last retry may be performed on another server even if a cookie references a different server.
Specify when to attempt to automatically retry a failed request.
This setting is only valid when "mode" is set to http and is silently ignored
otherwise.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<keywords> is a list of keywords or HTTP status codes, each representing a type of failure event on which an attempt to retry the request is desired. Please read the notes at the bottom before changing this setting. The following keywords are supported : none never retry conn-failure retry when the connection or the SSL handshake failed and the request could not be sent. This is the default. empty-response retry when the server connection was closed after part of the request was sent, and nothing was received from the server. This type of failure may be caused by the request timeout on the server side, poor network condition, or a server crash or restart while processing the request. junk-response retry when the server returned something not looking like a complete HTTP response. This includes partial responses headers as well as non-HTTP contents. It usually is a bad idea to retry on such events, which may be caused a configuration issue (wrong server port) or by the request being harmful to the server (buffer overflow attack for example). response-timeout the server timeout stroke while waiting for the server to respond to the request. This may be caused by poor network condition, the reuse of an idle connection which has expired on the path, or by the request being extremely expensive to process. It generally is a bad idea to retry on such events on servers dealing with heavy database processing (full scans, etc) as it may amplify denial of service attacks. 0rtt-rejected retry requests which were sent over early data and were rejected by the server. These requests are generally considered to be safe to retry. <status> any HTTP status code among "404" (Not Found), "408" (Request Timeout), "425" (Too Early), "500" (Server Error), "501" (Not Implemented), "502" (Bad Gateway), "503" (Service Unavailable), "504" (Gateway Timeout). all-retryable-errors retry request for any error that are considered retryable. This currently activates "conn-failure", "empty-response", "junk-response", "response-timeout", "0rtt-rejected", "500", "502", "503", and "504".
Using this directive replaces any previous settings with the new ones; it is not cumulative. Please note that using anything other than "none" and "conn-failure" requires to allocate a buffer and copy the whole request into it, so it has memory and performance impacts. Requests not fitting in a single buffer will never be retried (see the global tune.bufsize setting). You have to make sure the application has a replay protection mechanism built in such as a unique transaction IDs passed in requests, or that replaying the same request has no consequence, or it is very dangerous to use any retry-on value beside "conn-failure" and "none". Static file servers and caches are generally considered safe against any type of retry. Using a status code can be useful to quickly leave a server showing an abnormal behavior (out of memory, file system issues, etc), but in this case it may be a good idea to immediately redispatch the connection to another server (please see "option redispatch" for this). Last, it is important to understand that most causes of failures are the requests themselves and that retrying a request causing a server to misbehave will often make the situation even worse for this server, or for the whole service in case of redispatch. Unless you know exactly how the application deals with replayed requests, you should not use this directive. The default is "conn-failure".
Declare a server in a backend
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<name> is the internal name assigned to this server. This name will appear in logs and alerts. If "http-send-name-header" is set, it will be added to the request header sent to the server. <address> is the IPv4 or IPv6 address of the server. Alternatively, a resolvable hostname is supported, but this name will be resolved during start-up. Address "0.0.0.0" or "*" has a special meaning. It indicates that the connection will be forwarded to the same IP address as the one from the client connection. This is useful in transparent proxy architectures where the client's connection is intercepted and haproxy must forward to the original destination address. This is more or less what the "transparent" keyword does except that with a server it's possible to limit concurrency and to report statistics. Optionally, an address family prefix may be used before the address to force the family regardless of the address format, which can be useful to specify a path to a unix socket with no slash ('/'). Currently supported prefixes are : - 'ipv4@' -> address is always IPv4 - 'ipv6@' -> address is always IPv6 - 'unix@' -> address is a path to a local unix socket - 'abns@' -> address is in abstract namespace (Linux only) - 'sockpair@' -> address is the FD of a connected unix socket or of a socketpair. During a connection, the backend creates a pair of connected sockets, and passes one of them over the FD. The bind part will use the received socket as the client FD. Should be used carefully. You may want to reference some environment variables in the address parameter, see section 2.3 about environment variables. The "init-addr" setting can be used to modify the way IP addresses should be resolved upon startup. <port> is an optional port specification. If set, all connections will be sent to this port. If unset, the same port the client connected to will be used. The port may also be prefixed by a "+" or a "-". In this case, the server's port will be determined by adding this value to the client's port. <param*> is a list of parameters for this server. The "server" keywords accepts an important number of options and has a complete section dedicated to it. Please refer to section 5 for more details.
server first 10.1.1.1:1080 cookie first check inter 1000
server second 10.1.1.2:1080 cookie second check inter 1000
server transp ipv4@
server backup "${SRV_BACKUP}:1080" backup
server www1_dc1 "${LAN_DC1}.101:80"
server www1_dc2 "${LAN_DC2}.101:80"
Note: regarding Linux's abstract namespace sockets, HAProxy uses the whole sun_path length is used for the address length. Some other programs such as socat use the string length only by default. Pass the option ",unix-tightsocklen=0" to any abstract socket definition in socat to make it compatible with HAProxy's.
Set the server state file to read, load and apply to servers available in this backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
It only applies when the directive "load-server-state-from-file" is set to "local". When <file> is not provided, if "use-backend-name" is used or if this directive is not set, then backend name is used. If <file> starts with a slash '/', then it is considered as an absolute path. Otherwise, <file> is concatenated to the global directive "server-state-base".
The minimal configuration below would make HAProxy look for the state server file '/etc/haproxy/states/bk':global server-state-file-base /etc/haproxy/states backend bk load-server-state-from-file
Set a template to initialize servers with shared parameters. The names of these servers are built from <prefix> and <num | range> parameters.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<prefix> A prefix for the server names to be built. <num | range> If <num> is provided, this template initializes <num> servers with 1 up to <num> as server name suffixes. A range of numbers <num_low>-<num_high> may also be used to use <num_low> up to <num_high> as server name suffixes. <fqdn> A FQDN for all the servers this template initializes. <port> Same meaning as "server" <port> argument (see "server" keyword). <params*> Remaining server parameters among all those supported by "server" keyword.
# Initializes 3 servers with srv1, srv2 and srv3 as names,
# google.com as FQDN, and health-check enabled.
server-template srv 1-3 google.com:80 check
# or
server-template srv 3 google.com:80 check
# would be equivalent to:
server srv1 google.com:80 check
server srv2 google.com:80 check
server srv3 google.com:80 check
Set the source address for outgoing connections
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<addr> is the IPv4 address HAProxy will bind to before connecting to a server. This address is also used as a source for health checks. The default value of 0.0.0.0 means that the system will select the most appropriate address to reach its destination. Optionally an address family prefix may be used before the address to force the family regardless of the address format, which can be useful to specify a path to a unix socket with no slash ('/'). Currently supported prefixes are : - 'ipv4@' -> address is always IPv4 - 'ipv6@' -> address is always IPv6 - 'unix@' -> address is a path to a local unix socket - 'abns@' -> address is in abstract namespace (Linux only) You may want to reference some environment variables in the address parameter, see section 2.3 about environment variables. <port> is an optional port. It is normally not needed but may be useful in some very specific contexts. The default value of zero means the system will select a free port. Note that port ranges are not supported in the backend. If you want to force port ranges, you have to specify them on each "server" line. <addr2> is the IP address to present to the server when connections are forwarded in full transparent proxy mode. This is currently only supported on some patched Linux kernels. When this address is specified, clients connecting to the server will be presented with this address, while health checks will still use the address <addr>. <port2> is the optional port to present to the server when connections are forwarded in full transparent proxy mode (see <addr2> above). The default value of zero means the system will select a free port. <hdr> is the name of a HTTP header in which to fetch the IP to bind to. This is the name of a comma-separated header list which can contain multiple IP addresses. By default, the last occurrence is used. This is designed to work with the X-Forwarded-For header and to automatically bind to the client's IP address as seen by previous proxy, typically Stunnel. In order to use another occurrence from the last one, please see the <occ> parameter below. When the header (or occurrence) is not found, no binding is performed so that the proxy's default IP address is used. Also keep in mind that the header name is case insensitive, as for any HTTP header. <occ> is the occurrence number of a value to be used in a multi-value header. This is to be used in conjunction with "hdr_ip(<hdr>)", in order to specify which occurrence to use for the source IP address. Positive values indicate a position from the first occurrence, 1 being the first one. Negative values indicate positions relative to the last one, -1 being the last one. This is helpful for situations where an X-Forwarded-For header is set at the entry point of an infrastructure and must be used several proxy layers away. When this value is not specified, -1 is assumed. Passing a zero here disables the feature. <name> is an optional interface name to which to bind to for outgoing traffic. On systems supporting this features (currently, only Linux), this allows one to bind all traffic to the server to this interface even if it is not the one the system would select based on routing tables. This should be used with extreme care. Note that using this option requires root privileges.
The "source" keyword is useful in complex environments where a specific address only is allowed to connect to the servers. It may be needed when a private address must be used through a public gateway for instance, and it is known that the system cannot determine the adequate source address by itself. An extension which is available on certain patched Linux kernels may be used through the "usesrc" optional keyword. It makes it possible to connect to the servers with an IP address which does not belong to the system itself. This is called "full transparent proxy mode". For this to work, the destination servers have to route their traffic back to this address through the machine running HAProxy, and IP forwarding must generally be enabled on this machine. In this "full transparent proxy" mode, it is possible to force a specific IP address to be presented to the servers. This is not much used in fact. A more common use is to tell HAProxy to present the client's IP address. For this, there are two methods : - present the client's IP and port addresses. This is the most transparent mode, but it can cause problems when IP connection tracking is enabled on the machine, because a same connection may be seen twice with different states. However, this solution presents the huge advantage of not limiting the system to the 64k outgoing address+port couples, because all of the client ranges may be used. - present only the client's IP address and select a spare port. This solution is still quite elegant but slightly less transparent (downstream firewalls logs will not match upstream's). It also presents the downside of limiting the number of concurrent connections to the usual 64k ports. However, since the upstream and downstream ports are different, local IP connection tracking on the machine will not be upset by the reuse of the same session. This option sets the default source for all servers in the backend. It may also be specified in a "defaults" section. Finer source address specification is possible at the server level using the "source" server option. Refer to section 5 for more information. In order to work, "usesrc" requires root privileges.
backend private
# Connect to the servers using our 192.168.1.200 source address
source 192.168.1.200
backend transparent_ssl1
# Connect to the SSL farm from the client's source address
source 192.168.1.200 usesrc clientip
backend transparent_ssl2
# Connect to the SSL farm from the client's source address and port
# not recommended if IP conntrack is present on the local machine.
source 192.168.1.200 usesrc client
backend transparent_ssl3
# Connect to the SSL farm from the client's source address. It
# is more conntrack-friendly.
source 192.168.1.200 usesrc clientip
backend transparent_smtp
# Connect to the SMTP farm from the client's source address/port
# with Tproxy version 4.
source 0.0.0.0 usesrc clientip
backend transparent_http
# Connect to the servers using the client's IP as seen by previous
# proxy.
source 0.0.0.0 usesrc hdr_ip(x-forwarded-for,-1)
Enable statistics admin level if/unless a condition is matched
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
This statement enables the statistics admin level if/unless a condition is matched. The admin level allows to enable/disable servers from the web interface. By default, statistics page is read-only for security reasons. Note : Consider not using this feature in multi-process mode (nbproc > 1) unless you know what you do : memory is not shared between the processes, which can result in random behaviors. Currently, the POST request is limited to the buffer size minus the reserved buffer space, which means that if the list of servers is too long, the request won't be processed. It is recommended to alter few servers at a time.
# statistics admin level only for localhost
backend stats_localhost
stats enable
stats admin if LOCALHOST
# statistics admin level always enabled because of the authentication
backend stats_auth
stats enable
stats auth admin:AdMiN123
stats admin if TRUE
# statistics admin level depends on the authenticated user
userlist stats-auth
group admin users admin
user admin insecure-password AdMiN123
group readonly users haproxy
user haproxy insecure-password haproxy
backend stats_auth
stats enable
acl AUTH http_auth(stats-auth)
acl AUTH_ADMIN http_auth_group(stats-auth) admin
stats http-request auth unless AUTH
stats admin if AUTH_ADMIN
Enable statistics with authentication and grant access to an account
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<user> is a user name to grant access to <passwd> is the cleartext password associated to this user
This statement enables statistics with default settings, and restricts access to declared users only. It may be repeated as many times as necessary to allow as many users as desired. When a user tries to access the statistics without a valid account, a "401 Forbidden" response will be returned so that the browser asks the user to provide a valid user and password. The real which will be returned to the browser is configurable using "stats realm". Since the authentication method is HTTP Basic Authentication, the passwords circulate in cleartext on the network. Thus, it was decided that the configuration file would also use cleartext passwords to remind the users that those ones should not be sensitive and not shared with any other account. It is also possible to reduce the scope of the proxies which appear in the report using "stats scope". Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Enable statistics reporting with default settings
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
This statement enables statistics reporting with default settings defined at build time. Unless stated otherwise, these settings are used : - stats uri : /haproxy?stats - stats realm : "HAProxy Statistics" - stats auth : no authentication - stats scope : no restriction Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Enable statistics and hide HAProxy version reporting
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
By default, the stats page reports some useful status information along with the statistics. Among them is HAProxy's version. However, it is generally considered dangerous to report precise version to anyone, as it can help them target known weaknesses with specific attacks. The "stats hide-version" statement removes the version from the statistics report. This is recommended for public sites or any site with a weak login/password. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Access control for statistics
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
As "http-request", these set of options allow to fine control access to
statistics. Each option may be followed by if/unless and acl.
First option with matched condition (or option without condition) is final.
For "deny" a 403 error will be returned, for "allow" normal processing is
performed, for "auth" a 401/407 error code is returned so the client
should be asked to enter a username and password.
There is no fixed limit to the number of http-request statements per
instance.
Enable statistics and set authentication realm
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<realm> is the name of the HTTP Basic Authentication realm reported to the browser. The browser uses it to display it in the pop-up inviting the user to enter a valid username and password.
The realm is read as a single word, so any spaces in it should be escaped using a backslash ('\'). This statement is useful only in conjunction with "stats auth" since it is only related to authentication. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Enable statistics with automatic refresh
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<delay> is the suggested refresh delay, specified in seconds, which will be returned to the browser consulting the report page. While the browser is free to apply any delay, it will generally respect it and refresh the page this every seconds. The refresh interval may be specified in any other non-default time unit, by suffixing the unit after the value, as explained at the top of this document.
This statement is useful on monitoring displays with a permanent page reporting the load balancer's activity. When set, the HTML report page will include a link "refresh"/"stop refresh" so that the user can select whether he wants automatic refresh of the page or not. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Enable statistics and limit access scope
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<name> is the name of a listen, frontend or backend section to be reported. The special name "." (a single dot) designates the section in which the statement appears.
When this statement is specified, only the sections enumerated with this statement will appear in the report. All other ones will be hidden. This statement may appear as many times as needed if multiple sections need to be reported. Please note that the name checking is performed as simple string comparisons, and that it is never checked that a give section name really exists. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Enable reporting of a description on the statistics page.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<desc> is an optional description to be reported. If unspecified, the description from global section is automatically used instead. This statement is useful for users that offer shared services to their customers, where node or description should be different for each customer. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters. By default description is not shown.
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats show-desc Master node for Europe, Asia, Africa
stats uri /admin?stats
stats refresh 5s
Enable reporting additional information on the statistics page
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
Enable reporting additional information on the statistics page : - cap: capabilities (proxy) - mode: one of tcp, http or health (proxy) - id: SNMP ID (proxy, socket, server) - IP (socket, server) - cookie (backend, server) Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters. Default behavior is not to show this information.
Enable reporting of a host name on the statistics page.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<name> is an optional name to be reported. If unspecified, the node name from global section is automatically used instead.
This statement is useful for users that offer shared services to their customers, where node or description might be different on a stats page provided for each customer. Default behavior is not to show host name. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats show-node Europe-1
stats uri /admin?stats
stats refresh 5s
Enable statistics and define the URI prefix to access them
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<prefix> is the prefix of any URI which will be redirected to stats. This prefix may contain a question mark ('?') to indicate part of a query string.
The statistics URI is intercepted on the relayed traffic, so it appears as a page within the normal application. It is strongly advised to ensure that the selected URI will never appear in the application, otherwise it will never be possible to reach it in the application. The default URI compiled in haproxy is "/haproxy?stats", but this may be changed at build time, so it's better to always explicitly specify it here. It is generally a good idea to include a question mark in the URI so that intermediate proxies refrain from caching the results. Also, since any string beginning with the prefix will be accepted as a stats request, the question mark helps ensuring that no valid URI will begin with the same words. It is sometimes very convenient to use "/" as the URI prefix, and put that statement in a "listen" instance of its own. That makes it easy to dedicate an address or a port to statistics only. Though this statement alone is enough to enable statistics reporting, it is recommended to set all other settings in order to avoid relying on default unobvious parameters.
# public access (limited to this backend only)
backend public_www
server srv1 192.168.0.1:80
stats enable
stats hide-version
stats scope .
stats uri /admin?stats
stats realm HAProxy\ Statistics
stats auth admin1:AdMiN123
stats auth admin2:AdMiN321
# internal monitoring access (unlimited)
backend private_monitoring
stats enable
stats uri /admin?stats
stats refresh 5s
Define a request pattern matching condition to stick a user to a server
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<pattern> is a sample expression rule as described in section 7.3. It describes what elements of the incoming request or connection will be analyzed in the hope to find a matching entry in a stickiness table. This rule is mandatory. <table> is an optional stickiness table name. If unspecified, the same backend's table is used. A stickiness table is declared using the "stick-table" statement. <cond> is an optional matching condition. It makes it possible to match on a certain criterion only when other conditions are met (or not met). For instance, it could be used to match on a source IP address except when a request passes through a known proxy, in which case we'd match on a header containing that IP address.
Some protocols or applications require complex stickiness rules and cannot always simply rely on cookies nor hashing. The "stick match" statement describes a rule to extract the stickiness criterion from an incoming request or connection. See section 7 for a complete list of possible patterns and transformation rules. The table has to be declared using the "stick-table" statement. It must be of a type compatible with the pattern. By default it is the one which is present in the same backend. It is possible to share a table with other backends by referencing it using the "table" keyword. If another table is referenced, the server's ID inside the backends are used. By default, all server IDs start at 1 in each backend, so the server ordering is enough. But in case of doubt, it is highly recommended to force server IDs using their "id" setting. It is possible to restrict the conditions where a "stick match" statement will apply, using "if" or "unless" followed by a condition. See section 7 for ACL based conditions. There is no limit on the number of "stick match" statements. The first that applies and matches will cause the request to be directed to the same server as was used for the request which created the entry. That way, multiple matches can be used as fallbacks. The stick rules are checked after the persistence cookies, so they will not affect stickiness if a cookie has already been used to select a server. That way, it becomes very easy to insert cookies and match on IP addresses in order to maintain stickiness between HTTP and HTTPS. Note : Consider not using this feature in multi-process mode (nbproc > 1) unless you know what you do : memory is not shared between the processes, which can result in random behaviors.
# forward SMTP users to the same server they just used for POP in the
# last 30 minutes
backend pop
mode tcp
balance roundrobin
stick store-request src
stick-table type ip size 200k expire 30m
server s1 192.168.1.1:110
server s2 192.168.1.1:110
backend smtp
mode tcp
balance roundrobin
stick match src table pop
server s1 192.168.1.1:25
server s2 192.168.1.1:25
Define a request pattern to associate a user to a server
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
Note : This form is exactly equivalent to "stick match" followed by "stick store-request", all with the same arguments. Please refer to both keywords for details. It is only provided as a convenience for writing more maintainable configurations. Note : Consider not using this feature in multi-process mode (nbproc > 1) unless you know what you do : memory is not shared between the processes, which can result in random behaviors.
# The following form ...
stick on src table pop if !localhost
# ...is strictly equivalent to this one :
stick match src table pop if !localhost
stick store-request src table pop if !localhost
# Use cookie persistence for HTTP, and stick on source address for HTTPS as
# well as HTTP without cookie. Share the same table between both accesses.
backend http
mode http
balance roundrobin
stick on src table https
cookie SRV insert indirect nocache
server s1 192.168.1.1:80 cookie s1
server s2 192.168.1.1:80 cookie s2
backend https
mode tcp
balance roundrobin
stick-table type ip size 200k expire 30m
stick on src
server s1 192.168.1.1:443
server s2 192.168.1.1:443
Define a request pattern used to create an entry in a stickiness table
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<pattern> is a sample expression rule as described in section 7.3. It describes what elements of the incoming request or connection will be analyzed, extracted and stored in the table once a server is selected. <table> is an optional stickiness table name. If unspecified, the same backend's table is used. A stickiness table is declared using the "stick-table" statement. <cond> is an optional storage condition. It makes it possible to store certain criteria only when some conditions are met (or not met). For instance, it could be used to store the source IP address except when the request passes through a known proxy, in which case we'd store a converted form of a header containing that IP address.
Some protocols or applications require complex stickiness rules and cannot always simply rely on cookies nor hashing. The "stick store-request" statement describes a rule to decide what to extract from the request and when to do it, in order to store it into a stickiness table for further requests to match it using the "stick match" statement. Obviously the extracted part must make sense and have a chance to be matched in a further request. Storing a client's IP address for instance often makes sense. Storing an ID found in a URL parameter also makes sense. Storing a source port will almost never make any sense because it will be randomly matched. See section 7 for a complete list of possible patterns and transformation rules. The table has to be declared using the "stick-table" statement. It must be of a type compatible with the pattern. By default it is the one which is present in the same backend. It is possible to share a table with other backends by referencing it using the "table" keyword. If another table is referenced, the server's ID inside the backends are used. By default, all server IDs start at 1 in each backend, so the server ordering is enough. But in case of doubt, it is highly recommended to force server IDs using their "id" setting. It is possible to restrict the conditions where a "stick store-request" statement will apply, using "if" or "unless" followed by a condition. This condition will be evaluated while parsing the request, so any criteria can be used. See section 7 for ACL based conditions. There is no limit on the number of "stick store-request" statements, but there is a limit of 8 simultaneous stores per request or response. This makes it possible to store up to 8 criteria, all extracted from either the request or the response, regardless of the number of rules. Only the 8 first ones which match will be kept. Using this, it is possible to feed multiple tables at once in the hope to increase the chance to recognize a user on another protocol or access method. Using multiple store-request rules with the same table is possible and may be used to find the best criterion to rely on, by arranging the rules by decreasing preference order. Only the first extracted criterion for a given table will be stored. All subsequent store- request rules referencing the same table will be skipped and their ACLs will not be evaluated. The "store-request" rules are evaluated once the server connection has been established, so that the table will contain the real server that processed the request. Note : Consider not using this feature in multi-process mode (nbproc > 1) unless you know what you do : memory is not shared between the processes, which can result in random behaviors.
# forward SMTP users to the same server they just used for POP in the
# last 30 minutes
backend pop
mode tcp
balance roundrobin
stick store-request src
stick-table type ip size 200k expire 30m
server s1 192.168.1.1:110
server s2 192.168.1.1:110
backend smtp
mode tcp
balance roundrobin
stick match src table pop
server s1 192.168.1.1:25
server s2 192.168.1.1:25
Configure the stickiness table for the current section
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
ip a table declared with "type ip" will only store IPv4 addresses. This form is very compact (about 50 bytes per entry) and allows very fast entry lookup and stores with almost no overhead. This is mainly used to store client source IP addresses. ipv6 a table declared with "type ipv6" will only store IPv6 addresses. This form is very compact (about 60 bytes per entry) and allows very fast entry lookup and stores with almost no overhead. This is mainly used to store client source IP addresses. integer a table declared with "type integer" will store 32bit integers which can represent a client identifier found in a request for instance. string a table declared with "type string" will store substrings of up to <len> characters. If the string provided by the pattern extractor is larger than <len>, it will be truncated before being stored. During matching, at most <len> characters will be compared between the string in the table and the extracted pattern. When not specified, the string is automatically limited to 32 characters. binary a table declared with "type binary" will store binary blocks of <len> bytes. If the block provided by the pattern extractor is larger than <len>, it will be truncated before being stored. If the block provided by the sample expression is shorter than <len>, it will be padded by 0. When not specified, the block is automatically limited to 32 bytes. <length> is the maximum number of characters that will be stored in a "string" type table (See type "string" above). Or the number of bytes of the block in "binary" type table. Be careful when changing this parameter as memory usage will proportionally increase. <size> is the maximum number of entries that can fit in the table. This value directly impacts memory usage. Count approximately 50 bytes per entry, plus the size of a string if any. The size supports suffixes "k", "m", "g" for 2^10, 2^20 and 2^30 factors. [nopurge] indicates that we refuse to purge older entries when the table is full. When not specified and the table is full when haproxy wants to store an entry in it, it will flush a few of the oldest entries in order to release some space for the new ones. This is most often the desired behavior. In some specific cases, it be desirable to refuse new entries instead of purging the older ones. That may be the case when the amount of data to store is far above the hardware limits and we prefer not to offer access to new clients than to reject the ones already connected. When using this parameter, be sure to properly set the "expire" parameter (see below). <peersect> is the name of the peers section to use for replication. Entries which associate keys to server IDs are kept synchronized with the remote peers declared in this section. All entries are also automatically learned from the local peer (old process) during a soft restart. NOTE : each peers section may be referenced only by tables belonging to the same unique process. <expire> defines the maximum duration of an entry in the table since it was last created, refreshed or matched. The expiration delay is defined using the standard time format, similarly as the various timeouts. The maximum duration is slightly above 24 days. See section 2.4 for more information. If this delay is not specified, the session won't automatically expire, but older entries will be removed once full. Be sure not to use the "nopurge" parameter if not expiration delay is specified. <data_type> is used to store additional information in the stick-table. This may be used by ACLs in order to control various criteria related to the activity of the client matching the stick-table. For each item specified here, the size of each entry will be inflated so that the additional data can fit. Several data types may be stored with an entry. Multiple data types may be specified after the "store" keyword, as a comma-separated list. Alternatively, it is possible to repeat the "store" keyword followed by one or several data types. Except for the "server_id" type which is automatically detected and enabled, all data types must be explicitly declared to be stored. If an ACL references a data type which is not stored, the ACL will simply not match. Some data types require an argument which must be passed just after the type between parenthesis. See below for the supported data types and their arguments.
The data types that can be stored with an entry are the following : - server_id : this is an integer which holds the numeric ID of the server a request was assigned to. It is used by the "stick match", "stick store", and "stick on" rules. It is automatically enabled when referenced. - gpc0 : first General Purpose Counter. It is a positive 32-bit integer integer which may be used for anything. Most of the time it will be used to put a special tag on some entries, for instance to note that a specific behavior was detected and must be known for future matches. - gpc0_rate(<period>) : increment rate of the first General Purpose Counter over a period. It is a positive 32-bit integer integer which may be used for anything. Just like <gpc0>, it counts events, but instead of keeping a cumulative number, it maintains the rate at which the counter is incremented. Most of the time it will be used to measure the frequency of occurrence of certain events (e.g. requests to a specific URL). - gpc1 : second General Purpose Counter. It is a positive 32-bit integer integer which may be used for anything. Most of the time it will be used to put a special tag on some entries, for instance to note that a specific behavior was detected and must be known for future matches. - gpc1_rate(<period>) : increment rate of the second General Purpose Counter over a period. It is a positive 32-bit integer integer which may be used for anything. Just like <gpc1>, it counts events, but instead of keeping a cumulative number, it maintains the rate at which the counter is incremented. Most of the time it will be used to measure the frequency of occurrence of certain events (e.g. requests to a specific URL). - conn_cnt : Connection Count. It is a positive 32-bit integer which counts the absolute number of connections received from clients which matched this entry. It does not mean the connections were accepted, just that they were received. - conn_cur : Current Connections. It is a positive 32-bit integer which stores the concurrent connection counts for the entry. It is incremented once an incoming connection matches the entry, and decremented once the connection leaves. That way it is possible to know at any time the exact number of concurrent connections for an entry. - conn_rate(<period>) : frequency counter (takes 12 bytes). It takes an integer parameter <period> which indicates in milliseconds the length of the period over which the average is measured. It reports the average incoming connection rate over that period, in connections per period. The result is an integer which can be matched using ACLs. - sess_cnt : Session Count. It is a positive 32-bit integer which counts the absolute number of sessions received from clients which matched this entry. A session is a connection that was accepted by the layer 4 rules. - sess_rate(<period>) : frequency counter (takes 12 bytes). It takes an integer parameter <period> which indicates in milliseconds the length of the period over which the average is measured. It reports the average incoming session rate over that period, in sessions per period. The result is an integer which can be matched using ACLs. - http_req_cnt : HTTP request Count. It is a positive 32-bit integer which counts the absolute number of HTTP requests received from clients which matched this entry. It does not matter whether they are valid requests or not. Note that this is different from sessions when keep-alive is used on the client side. - http_req_rate(<period>) : frequency counter (takes 12 bytes). It takes an integer parameter <period> which indicates in milliseconds the length of the period over which the average is measured. It reports the average HTTP request rate over that period, in requests per period. The result is an integer which can be matched using ACLs. It does not matter whether they are valid requests or not. Note that this is different from sessions when keep-alive is used on the client side. - http_err_cnt : HTTP Error Count. It is a positive 32-bit integer which counts the absolute number of HTTP requests errors induced by clients which matched this entry. Errors are counted on invalid and truncated requests, as well as on denied or tarpitted requests, and on failed authentications. If the server responds with 4xx, then the request is also counted as an error since it's an error triggered by the client (e.g. vulnerability scan). - http_err_rate(<period>) : frequency counter (takes 12 bytes). It takes an integer parameter <period> which indicates in milliseconds the length of the period over which the average is measured. It reports the average HTTP request error rate over that period, in requests per period (see http_err_cnt above for what is accounted as an error). The result is an integer which can be matched using ACLs. - bytes_in_cnt : client to server byte count. It is a positive 64-bit integer which counts the cumulative number of bytes received from clients which matched this entry. Headers are included in the count. This may be used to limit abuse of upload features on photo or video servers. - bytes_in_rate(<period>) : frequency counter (takes 12 bytes). It takes an integer parameter <period> which indicates in milliseconds the length of the period over which the average is measured. It reports the average incoming bytes rate over that period, in bytes per period. It may be used to detect users which upload too much and too fast. Warning: with large uploads, it is possible that the amount of uploaded data will be counted once upon termination, thus causing spikes in the average transfer speed instead of having a smooth one. This may partially be smoothed with "option contstats" though this is not perfect yet. Use of byte_in_cnt is recommended for better fairness. - bytes_out_cnt : server to client byte count. It is a positive 64-bit integer which counts the cumulative number of bytes sent to clients which matched this entry. Headers are included in the count. This may be used to limit abuse of bots sucking the whole site. - bytes_out_rate(<period>) : frequency counter (takes 12 bytes). It takes an integer parameter <period> which indicates in milliseconds the length of the period over which the average is measured. It reports the average outgoing bytes rate over that period, in bytes per period. It may be used to detect users which download too much and too fast. Warning: with large transfers, it is possible that the amount of transferred data will be counted once upon termination, thus causing spikes in the average transfer speed instead of having a smooth one. This may partially be smoothed with "option contstats" though this is not perfect yet. Use of byte_out_cnt is recommended for better fairness. There is only one stick-table per proxy. At the moment of writing this doc, it does not seem useful to have multiple tables per proxy. If this happens to be required, simply create a dummy backend with a stick-table in it and reference it. It is important to understand that stickiness based on learning information has some limitations, including the fact that all learned associations are lost upon restart unless peers are properly configured to transfer such information upon restart (recommended). In general it can be good as a complement but not always as an exclusive stickiness. Last, memory requirements may be important when storing many data types. Indeed, storing all indicators above at once in each entry requires 116 bytes per entry, or 116 MB for a 1-million entries table. This is definitely not something that can be ignored.
# Keep track of counters of up to 1 million IP addresses over 5 minutes
# and store a general purpose counter and the average connection rate
# computed over a sliding window of 30 seconds.
stick-table type ip size 1m expire 5m store gpc0,conn_rate(30s)
Define a response pattern used to create an entry in a stickiness table
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<pattern> is a sample expression rule as described in section 7.3. It describes what elements of the response or connection will be analyzed, extracted and stored in the table once a server is selected. <table> is an optional stickiness table name. If unspecified, the same backend's table is used. A stickiness table is declared using the "stick-table" statement. <cond> is an optional storage condition. It makes it possible to store certain criteria only when some conditions are met (or not met). For instance, it could be used to store the SSL session ID only when the response is a SSL server hello.
Some protocols or applications require complex stickiness rules and cannot always simply rely on cookies nor hashing. The "stick store-response" statement describes a rule to decide what to extract from the response and when to do it, in order to store it into a stickiness table for further requests to match it using the "stick match" statement. Obviously the extracted part must make sense and have a chance to be matched in a further request. Storing an ID found in a header of a response makes sense. See section 7 for a complete list of possible patterns and transformation rules. The table has to be declared using the "stick-table" statement. It must be of a type compatible with the pattern. By default it is the one which is present in the same backend. It is possible to share a table with other backends by referencing it using the "table" keyword. If another table is referenced, the server's ID inside the backends are used. By default, all server IDs start at 1 in each backend, so the server ordering is enough. But in case of doubt, it is highly recommended to force server IDs using their "id" setting. It is possible to restrict the conditions where a "stick store-response" statement will apply, using "if" or "unless" followed by a condition. This condition will be evaluated while parsing the response, so any criteria can be used. See section 7 for ACL based conditions. There is no limit on the number of "stick store-response" statements, but there is a limit of 8 simultaneous stores per request or response. This makes it possible to store up to 8 criteria, all extracted from either the request or the response, regardless of the number of rules. Only the 8 first ones which match will be kept. Using this, it is possible to feed multiple tables at once in the hope to increase the chance to recognize a user on another protocol or access method. Using multiple store-response rules with the same table is possible and may be used to find the best criterion to rely on, by arranging the rules by decreasing preference order. Only the first extracted criterion for a given table will be stored. All subsequent store- response rules referencing the same table will be skipped and their ACLs will not be evaluated. However, even if a store-request rule references a table, a store-response rule may also use the same table. This means that each table may learn exactly one element from the request and one element from the response at once. The table will contain the real server that processed the request.
# Learn SSL session ID from both request and response and create affinity.
backend https
mode tcp
balance roundrobin
# maximum SSL session ID length is 32 bytes.
stick-table type binary len 32 size 30k expire 30m
acl clienthello req_ssl_hello_type 1
acl serverhello rep_ssl_hello_type 2
# use tcp content accepts to detects ssl client and server hello.
tcp-request inspect-delay 5s
tcp-request content accept if clienthello
# no timeout on response inspect delay by default.
tcp-response content accept if serverhello
# SSL session ID (SSLID) may be present on a client or server hello.
# Its length is coded on 1 byte at offset 43 and its value starts
# at offset 44.
# Match and learn on request if client hello.
stick on payload_lv(43,1) if clienthello
# Learn on response if server hello.
stick store-response payload_lv(43,1) if serverhello
server s1 192.168.1.1:443
server s2 192.168.1.1:443
Opens a new connection
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
When an application lies on more than a single TCP port or when HAProxy load-balance many services in a single backend, it makes sense to probe all the services individually before considering a server as operational. When there are no TCP port configured on the server line neither server port directive, then the 'tcp-check connect port <port>' must be the first step of the sequence. In a tcp-check ruleset a 'connect' is required, it is also mandatory to start the ruleset with a 'connect' rule. Purpose is to ensure admin know what they do. Parameters : They are optional and can be used to describe how HAProxy should open and use the TCP connection. port if not set, check port or server port is used. It tells HAProxy where to open the connection to. <port> must be a valid TCP port source integer, from 1 to 65535. send-proxy send a PROXY protocol string ssl opens a ciphered connection
# check HTTP and HTTPs services on a server.
# first open port 80 thanks to server line port directive, then
# tcp-check opens port 443, ciphered and run a request on it:
option tcp-check
tcp-check connect
tcp-check send GET\ /\ HTTP/1.0\r\n
tcp-check send Host:\ haproxy.1wt.eu\r\n
tcp-check send \r\n
tcp-check expect rstring (2..|3..)
tcp-check connect port 443 ssl
tcp-check send GET\ /\ HTTP/1.0\r\n
tcp-check send Host:\ haproxy.1wt.eu\r\n
tcp-check send \r\n
tcp-check expect rstring (2..|3..)
server www 10.0.0.1 check port 80
# check both POP and IMAP from a single server:
option tcp-check
tcp-check connect port 110
tcp-check expect string +OK\ POP3\ ready
tcp-check connect port 143
tcp-check expect string *\ OK\ IMAP4\ ready
server mail 10.0.0.1 check
Specify data to be collected and analyzed during a generic health check
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<match> is a keyword indicating how to look for a specific pattern in the response. The keyword may be one of "string", "rstring" or binary. The keyword may be preceded by an exclamation mark ("!") to negate the match. Spaces are allowed between the exclamation mark and the keyword. See below for more details on the supported keywords. <pattern> is the pattern to look for. It may be a string or a regular expression. If the pattern contains spaces, they must be escaped with the usual backslash ('\'). If the match is set to binary, then the pattern must be passed as a series of hexadecimal digits in an even number. Each sequence of two digits will represent a byte. The hexadecimal digits may be used upper or lower case.
The available matches are intentionally similar to their http-check cousins : string <string> : test the exact string matches in the response buffer. A health check response will be considered valid if the response's buffer contains this exact string. If the "string" keyword is prefixed with "!", then the response will be considered invalid if the body contains this string. This can be used to look for a mandatory pattern in a protocol response, or to detect a failure when a specific error appears in a protocol banner. rstring <regex> : test a regular expression on the response buffer. A health check response will be considered valid if the response's buffer matches this expression. If the "rstring" keyword is prefixed with "!", then the response will be considered invalid if the body matches the expression. binary <hexstring> : test the exact string in its hexadecimal form matches in the response buffer. A health check response will be considered valid if the response's buffer contains this exact hexadecimal string. Purpose is to match data on binary protocols. It is important to note that the responses will be limited to a certain size defined by the global "tune.chksize" option, which defaults to 16384 bytes. Thus, too large responses may not contain the mandatory pattern when using "string", "rstring" or binary. If a large response is absolutely required, it is possible to change the default max size by setting the global variable. However, it is worth keeping in mind that parsing very large responses can waste some CPU cycles, especially when regular expressions are used, and that it is always better to focus the checks on smaller resources. Also, in its current state, the check will not find any string nor regex past a null character in the response. Similarly it is not possible to request matching the null character.
# perform a POP check
option tcp-check
tcp-check expect string +OK\ POP3\ ready
# perform an IMAP check
option tcp-check
tcp-check expect string *\ OK\ IMAP4\ ready
# look for the redis master server
option tcp-check
tcp-check send PING\r\n
tcp-check expect string +PONG
tcp-check send info\ replication\r\n
tcp-check expect string role:master
tcp-check send QUIT\r\n
tcp-check expect string +OK
Specify a string to be sent as a question during a generic health check
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<data> : the data to be sent as a question during a generic health check session. For now, <data> must be a string.
# look for the redis master server
option tcp-check
tcp-check send info\ replication\r\n
tcp-check expect string role:master
Specify a hex digits string to be sent as a binary question during a raw tcp health check
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<data> : the data to be sent as a question during a generic health check session. For now, <data> must be a string. <hexstring> : test the exact string in its hexadecimal form matches in the response buffer. A health check response will be considered valid if the response's buffer contains this exact hexadecimal string. Purpose is to send binary data to ask on binary protocols.
# redis check in binary
option tcp-check
tcp-check send-binary 50494e470d0a # PING\r\n
tcp-check expect binary 2b504F4e47 # +PONG
Perform an action on an incoming connection depending on a layer 4 condition
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<action> defines the action to perform if the condition applies. See below. <condition> is a standard layer4-only ACL-based condition (see section 7).
Immediately after acceptance of a new incoming connection, it is possible to evaluate some conditions to decide whether this connection must be accepted or dropped or have its counters tracked. Those conditions cannot make use of any data contents because the connection has not been read from yet, and the buffers are not yet allocated. This is used to selectively and very quickly accept or drop connections from various sources with a very low overhead. If some contents need to be inspected in order to take the decision, the "tcp-request content" statements must be used instead. The "tcp-request connection" rules are evaluated in their exact declaration order. If no rule matches or if there is no rule, the default action is to accept the incoming connection. There is no specific limit to the number of rules which may be inserted. Four types of actions are supported : - accept : accepts the connection if the condition is true (when used with "if") or false (when used with "unless"). The first such rule executed ends the rules evaluation. - reject : rejects the connection if the condition is true (when used with "if") or false (when used with "unless"). The first such rule executed ends the rules evaluation. Rejected connections do not even become a session, which is why they are accounted separately for in the stats, as "denied connections". They are not considered for the session rate-limit and are not logged either. The reason is that these rules should only be used to filter extremely high connection rates such as the ones encountered during a massive DDoS attack. Under these extreme conditions, the simple action of logging each event would make the system collapse and would considerably lower the filtering capacity. If logging is absolutely desired, then "tcp-request content" rules should be used instead, as "tcp-request session" rules will not log either. - expect-proxy layer4 : configures the client-facing connection to receive a PROXY protocol header before any byte is read from the socket. This is equivalent to having the "accept-proxy" keyword on the "bind" line, except that using the TCP rule allows the PROXY protocol to be accepted only for certain IP address ranges using an ACL. This is convenient when multiple layers of load balancers are passed through by traffic coming from public hosts. - expect-netscaler-cip layer4 : configures the client-facing connection to receive a NetScaler Client IP insertion protocol header before any byte is read from the socket. This is equivalent to having the "accept-netscaler-cip" keyword on the "bind" line, except that using the TCP rule allows the PROXY protocol to be accepted only for certain IP address ranges using an ACL. This is convenient when multiple layers of load balancers are passed through by traffic coming from public hosts. - capture <sample> len <length> : This only applies to "tcp-request content" rules. It captures sample expression <sample> from the request buffer, and converts it to a string of at most <len> characters. The resulting string is stored into the next request "capture" slot, so it will possibly appear next to some captured HTTP headers. It will then automatically appear in the logs, and it will be possible to extract it using sample fetch rules to feed it into headers or anything. The length should be limited given that this size will be allocated for each capture during the whole session life. Please check section 7.3 (Fetching samples) and "capture request header" for more information. - { track-sc0 | track-sc1 | track-sc2 } <key> [table <table>] : enables tracking of sticky counters from current connection. These rules do not stop evaluation and do not change default action. The number of counters that may be simultaneously tracked by the same connection is set in MAX_SESS_STKCTR at build time (reported in haproxy -vv) which defaults to 3, so the track-sc number is between 0 and (MAX_SESS_STCKTR-1). The first "track-sc0" rule executed enables tracking of the counters of the specified table as the first set. The first "track-sc1" rule executed enables tracking of the counters of the specified table as the second set. The first "track-sc2" rule executed enables tracking of the counters of the specified table as the third set. It is a recommended practice to use the first set of counters for the per-frontend counters and the second set for the per-backend ones. But this is just a guideline, all may be used everywhere. These actions take one or two arguments : <key> is mandatory, and is a sample expression rule as described in section 7.3. It describes what elements of the incoming request or connection will be analyzed, extracted, combined, and used to select which table entry to update the counters. Note that "tcp-request connection" cannot use content-based fetches. <table> is an optional table to be used instead of the default one, which is the stick-table declared in the current proxy. All the counters for the matches and updates for the key will then be performed in that table until the session ends. Once a "track-sc*" rule is executed, the key is looked up in the table and if it is not found, an entry is allocated for it. Then a pointer to that entry is kept during all the session's life, and this entry's counters are updated as often as possible, every time the session's counters are updated, and also systematically when the session ends. Counters are only updated for events that happen after the tracking has been started. For example, connection counters will not be updated when tracking layer 7 information, since the connection event happens before layer7 information is extracted. If the entry tracks concurrent connection counters, one connection is counted for as long as the entry is tracked, and the entry will not expire during that time. Tracking counters also provides a performance advantage over just checking the keys, because only one table lookup is performed for all ACL checks that make use of it. - sc-inc-gpc0(<sc-id>): The "sc-inc-gpc0" increments the GPC0 counter according to the sticky counter designated by <sc-id>. If an error occurs, this action silently fails and the actions evaluation continues. - sc-inc-gpc1(<sc-id>): The "sc-inc-gpc1" increments the GPC1 counter according to the sticky counter designated by <sc-id>. If an error occurs, this action silently fails and the actions evaluation continues. - sc-set-gpt0(<sc-id>) { <int> | <expr> }: This action sets the 32-bit unsigned GPT0 tag according to the sticky counter designated by <sc-id> and the value of <int>/<expr>. The expected result is a boolean. If an error occurs, this action silently fails and the actions evaluation continues. - set-src <expr> : Is used to set the source IP address to the value of specified expression. Useful if you want to mask source IP for privacy. If you want to provide an IP from a HTTP header use "http-request set-src".
<expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
tcp-request connection set-src src,ipmask(24)
When possible, set-src preserves the original source port as long as the address family allows it, otherwise the source port is set to 0. - set-src-port <expr> : Is used to set the source port address to the value of specified expression.
<expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
tcp-request connection set-src-port int(4000)
When possible, set-src-port preserves the original source address as long as the address family supports a port, otherwise it forces the source address to IPv4 "0.0.0.0" before rewriting the port. - set-dst <expr> : Is used to set the destination IP address to the value of specified expression. Useful if you want to mask IP for privacy in log. If you want to provide an IP from a HTTP header use "http-request set-dst". If you want to connect to the new address/port, use '0.0.0.0:0' as a server address in the backend. <expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
tcp-request connection set-dst dst,ipmask(24)
tcp-request connection set-dst ipv4(10.0.0.1)
When possible, set-dst preserves the original destination port as long as the address family allows it, otherwise the destination port is set to 0. - set-dst-port <expr> : Is used to set the destination port address to the value of specified expression. If you want to connect to the new address/port, use '0.0.0.0:0' as a server address in the backend. <expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
tcp-request connection set-dst-port int(4000)
When possible, set-dst-port preserves the original destination address as long as the address family supports a port, otherwise it forces the destination address to IPv4 "0.0.0.0" before rewriting the port. - "silent-drop" : This stops the evaluation of the rules and makes the client-facing connection suddenly disappear using a system-dependent way that tries to prevent the client from being notified. The effect it then that the client still sees an established connection while there's none on HAProxy. The purpose is to achieve a comparable effect to "tarpit" except that it doesn't use any local resource at all on the machine running HAProxy. It can resist much higher loads than "tarpit", and slow down stronger attackers. It is important to understand the impact of using this mechanism. All stateful equipment placed between the client and HAProxy (firewalls, proxies, load balancers) will also keep the established connection for a long time and may suffer from this action. On modern Linux systems running with enough privileges, the TCP_REPAIR socket option is used to block the emission of a TCP reset. On other systems, the socket's TTL is reduced to 1 so that the TCP reset doesn't pass the first router, though it's still delivered to local networks. Do not use it unless you fully understand how it works. Note that the "if/unless" condition is optional. If no condition is set on the action, it is simply performed unconditionally. That can be useful for "track-sc*" actions as well as for changing the default action to a reject.
Accept all connections from white-listed hosts, reject too fast connection without counting them, and track accepted connections. This results in connection rate being capped from abusive sources.tcp-request connection accept if { src -f /etc/haproxy/whitelist.lst } tcp-request connection reject if { src_conn_rate gt 10 } tcp-request connection track-sc0 src
Accept all connections from white-listed hosts, count all other connections and reject too fast ones. This results in abusive ones being blocked as long as they don't slow down.tcp-request connection accept if { src -f /etc/haproxy/whitelist.lst } tcp-request connection track-sc0 src tcp-request connection reject if { sc0_conn_rate gt 10 }
Enable the PROXY protocol for traffic coming from all known proxies.tcp-request connection expect-proxy layer4 if { src -f proxies.lst }
See section 7 about ACL usage.
Perform an action on a new session depending on a layer 4-7 condition
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
<action> defines the action to perform if the condition applies. See below. <condition> is a standard layer 4-7 ACL-based condition (see section 7).
A request's contents can be analyzed at an early stage of request processing called "TCP content inspection". During this stage, ACL-based rules are evaluated every time the request contents are updated, until either an "accept" or a "reject" rule matches, or the TCP request inspection delay expires with no matching rule. The first difference between these rules and "tcp-request connection" rules is that "tcp-request content" rules can make use of contents to take a decision. Most often, these decisions will consider a protocol recognition or validity. The second difference is that content-based rules can be used in both frontends and backends. In case of HTTP keep-alive with the client, all tcp-request content rules are evaluated again, so haproxy keeps a record of what sticky counters were assigned by a "tcp-request connection" versus a "tcp-request content" rule, and flushes all the content-related ones after processing an HTTP request, so that they may be evaluated again by the rules being evaluated again for the next request. This is of particular importance when the rule tracks some L7 information or when it is conditioned by an L7-based ACL, since tracking may change between requests. Content-based rules are evaluated in their exact declaration order. If no rule matches or if there is no rule, the default action is to accept the contents. There is no specific limit to the number of rules which may be inserted. Several types of actions are supported : - accept : the request is accepted - do-resolve: perform a DNS resolution - reject : the request is rejected and the connection is closed - capture : the specified sample expression is captured - set-priority-class <expr> | set-priority-offset <expr> - { track-sc0 | track-sc1 | track-sc2 } <key> [table <table>] - sc-inc-gpc0(<sc-id>) - sc-inc-gpc1(<sc-id>) - sc-set-gpt0(<sc-id>) { <int> | <expr> } - set-dst <expr> - set-dst-port <expr> - set-var(<var-name>) <expr> - unset-var(<var-name>) - silent-drop - send-spoe-group <engine-name> <group-name> - use-service <service-name> They have the same meaning as their counter-parts in "tcp-request connection" so please refer to that section for a complete description. For "do-resolve" action, please check the "http-request do-resolve" configuration section. While there is nothing mandatory about it, it is recommended to use the track-sc0 in "tcp-request connection" rules, track-sc1 for "tcp-request content" rules in the frontend, and track-sc2 for "tcp-request content" rules in the backend, because that makes the configuration more readable and easier to troubleshoot, but this is just a guideline and all counters may be used everywhere. Note that the "if/unless" condition is optional. If no condition is set on the action, it is simply performed unconditionally. That can be useful for "track-sc*" actions as well as for changing the default action to a reject. It is perfectly possible to match layer 7 contents with "tcp-request content" rules from a TCP proxy, since HTTP-specific ACL matches are able to preliminarily parse the contents of a buffer before extracting the required data. If the buffered contents do not parse as a valid HTTP message, then the ACL does not match. The parser which is involved there is exactly the same as for all other HTTP processing, so there is no risk of parsing something differently. In an HTTP frontend or an HTTP backend, it is guaranteed that HTTP contents will always be immediately present when the rule is evaluated first because the HTTP parsing is performed in the early stages of the connection processing, at the session level. But for such proxies, using "http-request" rules is much more natural and recommended. Tracking layer7 information is also possible provided that the information are present when the rule is processed. The rule processing engine is able to wait until the inspect delay expires when the data to be tracked is not yet available. The "set-dst" and "set-dst-port" are used to set respectively the destination IP and port. More information on how to use it at "http-request set-dst". The "set-var" is used to set the content of a variable. The variable is declared inline. For "tcp-request session" rules, only session-level variables can be used, without any layer7 contents. <var-name> The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'. <expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters. The "unset-var" is used to unset a variable. See above for details about <var-name>. The "set-priority-class" is used to set the queue priority class of the current request. The value must be a sample expression which converts to an integer in the range -2047..2047. Results outside this range will be truncated. The priority class determines the order in which queued requests are processed. Lower values have higher priority. The "set-priority-offset" is used to set the queue priority timestamp offset of the current request. The value must be a sample expression which converts to an integer in the range -524287..524287. Results outside this range will be truncated. When a request is queued, it is ordered first by the priority class, then by the current timestamp adjusted by the given offset in milliseconds. Lower values have higher priority. Note that the resulting timestamp is is only tracked with enough precision for 524,287ms (8m44s287ms). If the request is queued long enough to where the adjusted timestamp exceeds this value, it will be misidentified as highest priority. Thus it is important to set "timeout queue" to a value, where when combined with the offset, does not exceed this limit. The "send-spoe-group" is used to trigger sending of a group of SPOE messages. To do so, the SPOE engine used to send messages must be defined, as well as the SPOE group to send. Of course, the SPOE engine must refer to an existing SPOE filter. If not engine name is provided on the SPOE filter line, the SPOE agent name must be used. <engine-name> The SPOE engine name. <group-name> The SPOE group name as specified in the engine configuration. The "use-service" is used to executes a TCP service which will reply to the request and stop the evaluation of the rules. This service may choose to reply by sending any valid response or it may immediately close the connection without sending anything. Outside natives services, it is possible to write your own services in Lua. No further "tcp-request" rules are evaluated.
tcp-request content use-service lua.deny { src -f /etc/haproxy/blacklist.lst }
tcp-request content set-var(sess.my_var) src
tcp-request content unset-var(sess.my_var2)
# Accept HTTP requests containing a Host header saying "example.com"
# and reject everything else.
acl is_host_com hdr(Host) -i example.com
tcp-request inspect-delay 30s
tcp-request content accept if is_host_com
tcp-request content reject
# reject SMTP connection if client speaks first
tcp-request inspect-delay 30s
acl content_present req_len gt 0
tcp-request content reject if content_present
# Forward HTTPS connection only if client speaks
tcp-request inspect-delay 30s
acl content_present req_len gt 0
tcp-request content accept if content_present
tcp-request content reject
# Track the last IP(stick-table type string) from X-Forwarded-For
tcp-request inspect-delay 10s
tcp-request content track-sc0 hdr(x-forwarded-for,-1)
# Or track the last IP(stick-table type ip|ipv6) from X-Forwarded-For
tcp-request content track-sc0 req.hdr_ip(x-forwarded-for,-1)
# track request counts per "base" (concatenation of Host+URL)
tcp-request inspect-delay 10s
tcp-request content track-sc0 base table req-rate
Track per-frontend and per-backend counters, block abusers at the frontend when the backend detects abuse(and marks gpc0).frontend http # Use General Purpose Counter 0 in SC0 as a global abuse counter # protecting all our sites stick-table type ip size 1m expire 5m store gpc0 tcp-request connection track-sc0 src tcp-request connection reject if { sc0_get_gpc0 gt 0 } ... use_backend http_dynamic if { path_end .php } backend http_dynamic # if a source makes too fast requests to this dynamic site (tracked # by SC1), block it globally in the frontend. stick-table type ip size 1m expire 5m store http_req_rate(10s) acl click_too_fast sc1_http_req_rate gt 10 acl mark_as_abuser sc0_inc_gpc0(http) gt 0 tcp-request content track-sc1 src tcp-request content reject if click_too_fast mark_as_abuser
See section 7 about ACL usage.
Set the maximum allowed time to wait for data during content inspection
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
People using haproxy primarily as a TCP relay are often worried about the risk of passing any type of protocol to a server without any analysis. In order to be able to analyze the request contents, we must first withhold the data then analyze them. This statement simply enables withholding of data for at most the specified amount of time. TCP content inspection applies very early when a connection reaches a frontend, then very early when the connection is forwarded to a backend. This means that a connection may experience a first delay in the frontend and a second delay in the backend if both have tcp-request rules. Note that when performing content inspection, haproxy will evaluate the whole rules for every new chunk which gets in, taking into account the fact that those data are partial. If no rule matches before the aforementioned delay, a last check is performed upon expiration, this time considering that the contents are definitive. If no delay is set, haproxy will not wait at all and will immediately apply a verdict based on the available information. Obviously this is unlikely to be very useful and might even be racy, so such setups are not recommended. As soon as a rule matches, the request is released and continues as usual. If the timeout is reached and no rule matches, the default policy will be to let it pass through unaffected. For most protocols, it is enough to set it to a few seconds, as most clients send the full request immediately upon connection. Add 3 or more seconds to cover TCP retransmits but that's all. For some protocols, it may make sense to use large values, for instance to ensure that the client never talks before the server (e.g. SMTP), or to wait for a client to talk before passing data to the server (e.g. SSL). Note that the client timeout must cover at least the inspection delay, otherwise it will expire first. If the client closes the connection or if the buffer is full, the delay immediately expires since the contents will not be able to change anymore.
Perform an action on a session response depending on a layer 4-7 condition
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<action> defines the action to perform if the condition applies. See below. <condition> is a standard layer 4-7 ACL-based condition (see section 7).
Response contents can be analyzed at an early stage of response processing called "TCP content inspection". During this stage, ACL-based rules are evaluated every time the response contents are updated, until either an "accept", "close" or a "reject" rule matches, or a TCP response inspection delay is set and expires with no matching rule. Most often, these decisions will consider a protocol recognition or validity. Content-based rules are evaluated in their exact declaration order. If no rule matches or if there is no rule, the default action is to accept the contents. There is no specific limit to the number of rules which may be inserted. Several types of actions are supported : - accept : accepts the response if the condition is true (when used with "if") or false (when used with "unless"). The first such rule executed ends the rules evaluation. - close : immediately closes the connection with the server if the condition is true (when used with "if"), or false (when used with "unless"). The first such rule executed ends the rules evaluation. The main purpose of this action is to force a connection to be finished between a client and a server after an exchange when the application protocol expects some long time outs to elapse first. The goal is to eliminate idle connections which take significant resources on servers with certain protocols. - reject : rejects the response if the condition is true (when used with "if") or false (when used with "unless"). The first such rule executed ends the rules evaluation. Rejected session are immediately closed. - set-var(<var-name>) <expr> Sets a variable. - unset-var(<var-name>) Unsets a variable. - sc-inc-gpc0(<sc-id>): This action increments the GPC0 counter according to the sticky counter designated by <sc-id>. If an error occurs, this action fails silently and the actions evaluation continues. - sc-inc-gpc1(<sc-id>): This action increments the GPC1 counter according to the sticky counter designated by <sc-id>. If an error occurs, this action fails silently and the actions evaluation continues. - sc-set-gpt0(<sc-id>) { <int> | <expr> } This action sets the 32-bit unsigned GPT0 tag according to the sticky counter designated by <sc-id> and the value of <int>/<expr>. The expected result is a boolean. If an error occurs, this action silently fails and the actions evaluation continues. - "silent-drop" : This stops the evaluation of the rules and makes the client-facing connection suddenly disappear using a system-dependent way that tries to prevent the client from being notified. The effect it then that the client still sees an established connection while there's none on HAProxy. The purpose is to achieve a comparable effect to "tarpit" except that it doesn't use any local resource at all on the machine running HAProxy. It can resist much higher loads than "tarpit", and slow down stronger attackers. It is important to understand the impact of using this mechanism. All stateful equipment placed between the client and HAProxy (firewalls, proxies, load balancers) will also keep the established connection for a long time and may suffer from this action. On modern Linux systems running with enough privileges, the TCP_REPAIR socket option is used to block the emission of a TCP reset. On other systems, the socket's TTL is reduced to 1 so that the TCP reset doesn't pass the first router, though it's still delivered to local networks. Do not use it unless you fully understand how it works. - send-spoe-group <engine-name> <group-name> Send a group of SPOE messages. Note that the "if/unless" condition is optional. If no condition is set on the action, it is simply performed unconditionally. That can be useful for for changing the default action to a reject. It is perfectly possible to match layer 7 contents with "tcp-response content" rules, but then it is important to ensure that a full response has been buffered, otherwise no contents will match. In order to achieve this, the best solution involves detecting the HTTP protocol during the inspection period. The "set-var" is used to set the content of a variable. The variable is declared inline. <var-name> The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'. <expr> Is a standard HAProxy expression formed by a sample-fetch followed by some converters.
tcp-request content set-var(sess.my_var) src
The "unset-var" is used to unset a variable. See above for details about <var-name>.
tcp-request content unset-var(sess.my_var)
The "send-spoe-group" is used to trigger sending of a group of SPOE messages. To do so, the SPOE engine used to send messages must be defined, as well as the SPOE group to send. Of course, the SPOE engine must refer to an existing SPOE filter. If not engine name is provided on the SPOE filter line, the SPOE agent name must be used. <engine-name> The SPOE engine name. <group-name> The SPOE group name as specified in the engine configuration. See section 7 about ACL usage.
Perform an action on a validated session depending on a layer 5 condition
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<action> defines the action to perform if the condition applies. See below. <condition> is a standard layer5-only ACL-based condition (see section 7).
Once a session is validated, (i.e. after all handshakes have been completed), it is possible to evaluate some conditions to decide whether this session must be accepted or dropped or have its counters tracked. Those conditions cannot make use of any data contents because no buffers are allocated yet and the processing cannot wait at this stage. The main use case it to copy some early information into variables (since variables are accessible in the session), or to keep track of some information collected after the handshake, such as SSL-level elements (SNI, ciphers, client cert's CN) or information from the PROXY protocol header (e.g. track a source forwarded this way). The extracted information can thus be copied to a variable or tracked using "track-sc" rules. Of course it is also possible to decide to accept/reject as with other rulesets. Most operations performed here could also be performed in "tcp-request content" rules, except that in HTTP these rules are evaluated for each new request, and that might not always be acceptable. For example a rule might increment a counter on each evaluation. It would also be possible that a country is resolved by geolocation from the source IP address, assigned to a session-wide variable, then the source address rewritten from an HTTP header for all requests. If some contents need to be inspected in order to take the decision, the "tcp-request content" statements must be used instead. The "tcp-request session" rules are evaluated in their exact declaration order. If no rule matches or if there is no rule, the default action is to accept the incoming session. There is no specific limit to the number of rules which may be inserted. Several types of actions are supported : - accept : the request is accepted - reject : the request is rejected and the connection is closed - { track-sc0 | track-sc1 | track-sc2 } <key> [table <table>] - sc-inc-gpc0(<sc-id>) - sc-inc-gpc1(<sc-id>) - sc-set-gpt0(<sc-id>) { <int> | <expr> } - set-var(<var-name>) <expr> - unset-var(<var-name>) - silent-drop These actions have the same meaning as their respective counter-parts in "tcp-request connection" and "tcp-request content", so please refer to these sections for a complete description. Note that the "if/unless" condition is optional. If no condition is set on the action, it is simply performed unconditionally. That can be useful for "track-sc*" actions as well as for changing the default action to a reject.
Track the original source address by default, or the one advertised in the PROXY protocol header for connection coming from the local proxies. The first connection-level rule enables receipt of the PROXY protocol for these ones, the second rule tracks whatever address we decide to keep after optional decoding.tcp-request connection expect-proxy layer4 if { src -f proxies.lst } tcp-request session track-sc0 src
Accept all sessions from white-listed hosts, reject too fast sessions without counting them, and track accepted sessions. This results in session rate being capped from abusive sources.tcp-request session accept if { src -f /etc/haproxy/whitelist.lst } tcp-request session reject if { src_sess_rate gt 10 } tcp-request session track-sc0 src
Accept all sessions from white-listed hosts, count all other sessions and reject too fast ones. This results in abusive ones being blocked as long as they don't slow down.tcp-request session accept if { src -f /etc/haproxy/whitelist.lst } tcp-request session track-sc0 src tcp-request session reject if { sc0_sess_rate gt 10 }
See section 7 about ACL usage.
Set the maximum allowed time to wait for a response during content inspection
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
Set additional check timeout, but only after a connection has been already established.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
If set, haproxy uses min("timeout connect", "inter") as a connect timeout for check and "timeout check" as an additional read timeout. The "min" is used so that people running with *very* long "timeout connect" (e.g. those who needed this due to the queue or tarpit) do not slow down their checks. (Please also note that there is no valid reason to have such long connect timeouts, because "timeout queue" and "timeout tarpit" can always be used to avoid that). If "timeout check" is not set haproxy uses "inter" for complete check timeout (connect + read) exactly like all <1.3.15 version. In most cases check request is much simpler and faster to handle than normal requests and people may want to kick out laggy servers so this timeout should be smaller than "timeout server". This parameter is specific to backends, but can be specified once for all in "defaults" sections. This is in fact one of the easiest solutions not to forget about it.
Set the maximum inactivity time on the client side.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
The inactivity timeout applies when the client is expected to acknowledge or send data. In HTTP mode, this timeout is particularly important to consider during the first phase, when the client sends the request, and during the response while it is reading data sent by the server. That said, for the first phase, it is preferable to set the "timeout http-request" to better protect HAProxy from Slowloris like attacks. The value is specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as specified at the top of this document. In TCP mode (and to a lesser extent, in HTTP mode), it is highly recommended that the client timeout remains equal to the server timeout in order to avoid complex situations to debug. It is a good practice to cover one or several TCP packet losses by specifying timeouts that are slightly above multiples of 3 seconds (e.g. 4 or 5 seconds). If some long-lived sessions are mixed with short-lived sessions (e.g. WebSocket and HTTP), it's worth considering "timeout tunnel", which overrides "timeout client" and "timeout server" for tunnels, as well as "timeout client-fin" for half-closed connections. This parameter is specific to frontends, but can be specified once for all in "defaults" sections. This is in fact one of the easiest solutions not to forget about it. An unspecified timeout results in an infinite timeout, which is not recommended. Such a usage is accepted and works but reports a warning during startup because it may result in accumulation of expired sessions in the system if the system's timeouts are not configured either. This also applies to HTTP/2 connections, which will be closed with GOAWAY.
Set the inactivity timeout on the client side for half-closed connections.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
The inactivity timeout applies when the client is expected to acknowledge or send data while one direction is already shut down. This timeout is different from "timeout client" in that it only applies to connections which are closed in one direction. This is particularly useful to avoid keeping connections in FIN_WAIT state for too long when clients do not disconnect cleanly. This problem is particularly common long connections such as RDP or WebSocket. Note that this timeout can override "timeout tunnel" when a connection shuts down in one direction. It is applied to idle HTTP/2 connections once a GOAWAY frame was sent, often indicating an expectation that the connection quickly ends. This parameter is specific to frontends, but can be specified once for all in "defaults" sections. By default it is not set, so half-closed connections will use the other timeouts (timeout.client or timeout.tunnel).
Set the maximum time to wait for a connection attempt to a server to succeed.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
If the server is located on the same LAN as haproxy, the connection should be immediate (less than a few milliseconds). Anyway, it is a good practice to cover one or several TCP packet losses by specifying timeouts that are slightly above multiples of 3 seconds (e.g. 4 or 5 seconds). By default, the connect timeout also presets both queue and tarpit timeouts to the same value if these have not been specified. This parameter is specific to backends, but can be specified once for all in "defaults" sections. This is in fact one of the easiest solutions not to forget about it. An unspecified timeout results in an infinite timeout, which is not recommended. Such a usage is accepted and works but reports a warning during startup because it may result in accumulation of failed sessions in the system if the system's timeouts are not configured either.
Set the maximum allowed time to wait for a new HTTP request to appear
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
By default, the time to wait for a new request in case of keep-alive is set by "timeout http-request". However this is not always convenient because some people want very short keep-alive timeouts in order to release connections faster, and others prefer to have larger ones but still have short timeouts once the request has started to present itself. The "http-keep-alive" timeout covers these needs. It will define how long to wait for a new HTTP request to start coming after a response was sent. Once the first byte of request has been seen, the "http-request" timeout is used to wait for the complete request to come. Note that empty lines prior to a new request do not refresh the timeout and are not counted as a new request. There is also another difference between the two timeouts : when a connection expires during timeout http-keep-alive, no error is returned, the connection just closes. If the connection expires in "http-request" while waiting for a connection to complete, a HTTP 408 error is returned. In general it is optimal to set this value to a few tens to hundreds of milliseconds, to allow users to fetch all objects of a page at once but without waiting for further clicks. Also, if set to a very small value (e.g. 1 millisecond) it will probably only accept pipelined requests but not the non-pipelined ones. It may be a nice trade-off for very large sites running with tens to hundreds of thousands of clients. If this parameter is not set, the "http-request" timeout applies, and if both are not set, "timeout client" still applies at the lower level. It should be set in the frontend to take effect, unless the frontend is in TCP mode, in which case the HTTP backend's timeout will be used. When using HTTP/2 "timeout client" is applied instead. This is so we can keep using short keep-alive timeouts in HTTP/1.1 while using longer ones in HTTP/2 (where we only have one connection per client and a connection setup).
Set the maximum allowed time to wait for a complete HTTP request
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
In order to offer DoS protection, it may be required to lower the maximum accepted time to receive a complete HTTP request without affecting the client timeout. This helps protecting against established connections on which nothing is sent. The client timeout cannot offer a good protection against this abuse because it is an inactivity timeout, which means that if the attacker sends one character every now and then, the timeout will not trigger. With the HTTP request timeout, no matter what speed the client types, the request will be aborted if it does not complete in time. When the timeout expires, an HTTP 408 response is sent to the client to inform it about the problem, and the connection is closed. The logs will report termination codes "cR". Some recent browsers are having problems with this standard, well-documented behavior, so it might be needed to hide the 408 code using "option http-ignore-probes" or "errorfile 408 /dev/null". See more details in the explanations of the "cR" termination code in section 8.5. By default, this timeout only applies to the header part of the request, and not to any data. As soon as the empty line is received, this timeout is not used anymore. When combined with "option http-buffer-request", this timeout also applies to the body of the request.. It is used again on keep-alive connections to wait for a second request if "timeout http-keep-alive" is not set. Generally it is enough to set it to a few seconds, as most clients send the full request immediately upon connection. Add 3 or more seconds to cover TCP retransmits but that's all. Setting it to very low values (e.g. 50 ms) will generally work on local networks as long as there are no packet losses. This will prevent people from sending bare HTTP requests using telnet. If this parameter is not set, the client timeout still applies between each chunk of the incoming request. It should be set in the frontend to take effect, unless the frontend is in TCP mode, in which case the HTTP backend's timeout will be used.
Set the maximum time to wait in the queue for a connection slot to be free
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
When a server's maxconn is reached, connections are left pending in a queue which may be server-specific or global to the backend. In order not to wait indefinitely, a timeout is applied to requests pending in the queue. If the timeout is reached, it is considered that the request will almost never be served, so it is dropped and a 503 error is returned to the client. The "timeout queue" statement allows to fix the maximum time for a request to be left pending in a queue. If unspecified, the same value as the backend's connection timeout ("timeout connect") is used, for backwards compatibility with older versions with no "timeout queue" parameter.
Set the maximum inactivity time on the server side.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
The inactivity timeout applies when the server is expected to acknowledge or send data. In HTTP mode, this timeout is particularly important to consider during the first phase of the server's response, when it has to send the headers, as it directly represents the server's processing time for the request. To find out what value to put there, it's often good to start with what would be considered as unacceptable response times, then check the logs to observe the response time distribution, and adjust the value accordingly. The value is specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as specified at the top of this document. In TCP mode (and to a lesser extent, in HTTP mode), it is highly recommended that the client timeout remains equal to the server timeout in order to avoid complex situations to debug. Whatever the expected server response times, it is a good practice to cover at least one or several TCP packet losses by specifying timeouts that are slightly above multiples of 3 seconds (e.g. 4 or 5 seconds minimum). If some long-lived sessions are mixed with short-lived sessions (e.g. WebSocket and HTTP), it's worth considering "timeout tunnel", which overrides "timeout client" and "timeout server" for tunnels. This parameter is specific to backends, but can be specified once for all in "defaults" sections. This is in fact one of the easiest solutions not to forget about it. An unspecified timeout results in an infinite timeout, which is not recommended. Such a usage is accepted and works but reports a warning during startup because it may result in accumulation of expired sessions in the system if the system's timeouts are not configured either.
Set the inactivity timeout on the server side for half-closed connections.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
The inactivity timeout applies when the server is expected to acknowledge or send data while one direction is already shut down. This timeout is different from "timeout server" in that it only applies to connections which are closed in one direction. This is particularly useful to avoid keeping connections in FIN_WAIT state for too long when a remote server does not disconnect cleanly. This problem is particularly common long connections such as RDP or WebSocket. Note that this timeout can override "timeout tunnel" when a connection shuts down in one direction. This setting was provided for completeness, but in most situations, it should not be needed. This parameter is specific to backends, but can be specified once for all in "defaults" sections. By default it is not set, so half-closed connections will use the other timeouts (timeout.server or timeout.tunnel).
Set the duration for which tarpitted connections will be maintained
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | yes |
<timeout> is the tarpit duration specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
When a connection is tarpitted using "http-request tarpit", it is maintained open with no activity for a certain amount of time, then closed. "timeout tarpit" defines how long it will be maintained open. The value is specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as specified at the top of this document. If unspecified, the same value as the backend's connection timeout ("timeout connect") is used, for backwards compatibility with older versions with no "timeout tarpit" parameter.
Set the maximum inactivity time on the client and server side for tunnels.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
<timeout> is the timeout value specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as explained at the top of this document.
The tunnel timeout applies when a bidirectional connection is established between a client and a server, and the connection remains inactive in both directions. This timeout supersedes both the client and server timeouts once the connection becomes a tunnel. In TCP, this timeout is used as soon as no analyzer remains attached to either connection (e.g. tcp content rules are accepted). In HTTP, this timeout is used when a connection is upgraded (e.g. when switching to the WebSocket protocol, or forwarding a CONNECT request to a proxy), or after the first response when no keepalive/close option is specified. Since this timeout is usually used in conjunction with long-lived connections, it usually is a good idea to also set "timeout client-fin" to handle the situation where a client suddenly disappears from the net and does not acknowledge a close, or sends a shutdown and does not acknowledge pending data anymore. This can happen in lossy networks where firewalls are present, and is detected by the presence of large amounts of sessions in a FIN_WAIT state. The value is specified in milliseconds by default, but can be in any other unit if the number is suffixed by the unit, as specified at the top of this document. Whatever the expected normal idle time, it is a good practice to cover at least one or several TCP packet losses by specifying timeouts that are slightly above multiples of 3 seconds (e.g. 4 or 5 seconds minimum). This parameter is specific to backends, but can be specified once for all in "defaults" sections. This is in fact one of the easiest solutions not to forget about it.
defaults http
option http-server-close
timeout connect 5s
timeout client 30s
timeout client-fin 30s
timeout server 30s
timeout tunnel 1h # timeout to use with WebSocket and CONNECT
Enable client-side transparent proxying
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | no | yes | yes |
This keyword was introduced in order to provide layer 7 persistence to layer 3 load balancers. The idea is to use the OS's ability to redirect an incoming connection for a remote address to a local process (here HAProxy), and let this process know what address was initially requested. When this option is used, sessions without cookies will be forwarded to the original destination IP address of the incoming request (which should match that of another equipment), while requests with cookies will still be forwarded to the appropriate server. The "transparent" keyword is deprecated, use "option transparent" instead. Note that contrary to a common belief, this option does NOT make HAProxy present the client's IP to the server when establishing the connection.
Generate a unique ID for each request.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<string> is a log-format string.
This keyword creates a ID for each request using the custom log format. A unique ID is useful to trace a request passing through many components of a complex infrastructure. The newly created ID may also be logged using the %ID tag the log-format string. The format should be composed from elements that are guaranteed to be unique when combined together. For instance, if multiple haproxy instances are involved, it might be important to include the node name. It is often needed to log the incoming connection's source and destination addresses and ports. Note that since multiple requests may be performed over the same connection, including a request counter may help differentiate them. Similarly, a timestamp may protect against a rollover of the counter. Logging the process ID will avoid collisions after a service restart. It is recommended to use hexadecimal notation for many fields since it makes them more compact and saves space in logs.
unique-id-format %{+X}o\ %ci:%cp_%fi:%fp_%Ts_%rt:%pid
will generate:
7F000001:8296_7F00001E:1F90_4F7B0A69_0003:790A
Add a unique ID header in the HTTP request.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
yes | yes | yes | no |
<name> is the name of the header.
Add a unique-id header in the HTTP request sent to the server, using the unique-id-format. It can't work if the unique-id-format doesn't exist.
unique-id-format %{+X}o\ %ci:%cp_%fi:%fp_%Ts_%rt:%pid
unique-id-header X-Unique-ID
will generate:
X-Unique-ID: 7F000001:8296_7F00001E:1F90_4F7B0A69_0003:790A
See also: "unique-id-format"
Switch to a specific backend if/unless an ACL-based condition is matched.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | yes | yes | no |
<backend> is the name of a valid backend or "listen" section, or a "log-format" string resolving to a backend name. <condition> is a condition composed of ACLs, as described in section 7. If it is omitted, the rule is unconditionally applied.
When doing content-switching, connections arrive on a frontend and are then dispatched to various backends depending on a number of conditions. The relation between the conditions and the backends is described with the "use_backend" keyword. While it is normally used with HTTP processing, it can also be used in pure TCP, either without content using stateless ACLs (e.g. source address validation) or combined with a "tcp-request" rule to wait for some payload. There may be as many "use_backend" rules as desired. All of these rules are evaluated in their declaration order, and the first one which matches will assign the backend. In the first form, the backend will be used if the condition is met. In the second form, the backend will be used if the condition is not met. If no condition is valid, the backend defined with "default_backend" will be used. If no default backend is defined, either the servers in the same section are used (in case of a "listen" section) or, in case of a frontend, no server is used and a 503 service unavailable response is returned. Note that it is possible to switch from a TCP frontend to an HTTP backend. In this case, either the frontend has already checked that the protocol is HTTP, and backend processing will immediately follow, or the backend will wait for a complete HTTP request to get in. This feature is useful when a frontend must decode several protocols on a unique port, one of them being HTTP. When <backend> is a simple name, it is resolved at configuration time, and an error is reported if the specified backend does not exist. If <backend> is a log-format string instead, no check may be done at configuration time, so the backend name is resolved dynamically at run time. If the resulting backend name does not correspond to any valid backend, no other rule is evaluated, and the default_backend directive is applied instead. Note that when using dynamic backend names, it is highly recommended to use a prefix that no other backend uses in order to ensure that an unauthorized backend cannot be forced from the request. It is worth mentioning that "use_backend" rules with an explicit name are used to detect the association between frontends and backends to compute the backend's "fullconn" setting. This cannot be done for dynamic names.
Defines the FastCGI application to use for the backend.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<name> is the name of the FastCGI application to use.
See section 10.1 about FastCGI application setup for details.
Only use a specific server if/unless an ACL-based condition is matched.
May be used in sections :
defaults | frontend | listen | backend |
---|---|---|---|
no | no | yes | yes |
<server> is the name of a valid server in the same backend section. <condition> is a condition composed of ACLs, as described in section 7.
By default, connections which arrive to a backend are load-balanced across the available servers according to the configured algorithm, unless a persistence mechanism such as a cookie is used and found in the request. Sometimes it is desirable to forward a particular request to a specific server without having to declare a dedicated backend for this server. This can be achieved using the "use-server" rules. These rules are evaluated after the "redirect" rules and before evaluating cookies, and they have precedence on them. There may be as many "use-server" rules as desired. All of these rules are evaluated in their declaration order, and the first one which matches will assign the server. If a rule designates a server which is down, and "option persist" is not used and no force-persist rule was validated, it is ignored and evaluation goes on with the next rules until one matches. In the first form, the server will be used if the condition is met. In the second form, the server will be used if the condition is not met. If no condition is valid, the processing continues and the server will be assigned according to other persistence mechanisms. Note that even if a rule is matched, cookie processing is still performed but does not assign the server. This allows prefixed cookies to have their prefix stripped. The "use-server" statement works both in HTTP and TCP mode. This makes it suitable for use with content-based inspection. For instance, a server could be selected in a farm according to the TLS SNI field. And if these servers have their weight set to zero, they will not be used for other traffic.
# intercept incoming TLS requests based on the SNI field
use-server www if { req_ssl_sni -i www.example.com }
server www 192.168.0.1:443 weight 0
use-server mail if { req_ssl_sni -i mail.example.com }
server mail 192.168.0.1:587 weight 0
use-server imap if { req_ssl_sni -i imap.example.com }
server imap 192.168.0.1:993 weight 0
# all the rest is forwarded to this server
server default 192.168.0.2:443 check
The "bind", "server" and "default-server" keywords support a number of settings depending on some build options and on the system HAProxy was built on. These settings generally each consist in one word sometimes followed by a value, written on the same line as the "bind" or "server" line. All these options are described in this section.
The "bind" keyword supports a certain number of settings which are all passed
as arguments on the same line. The order in which those arguments appear makes
no importance, provided that they appear after the bind address. All of these
parameters are optional. Some of them consist in a single words (booleans),
while other ones expect a value after them. In this case, the value must be
provided immediately after the setting name.
The currently supported settings are the following ones.
Enforces the use of the NetScaler Client IP insertion protocol over any connection accepted by any of the TCP sockets declared on the same line. The NetScaler Client IP insertion protocol dictates the layer 3/4 addresses of the incoming connection to be used everywhere an address is used, with the only exception of "tcp-request connection" rules which will only see the real connection address. Logs will reflect the addresses indicated in the protocol, unless it is violated, in which case the real address will still be used. This keyword combined with support from external components can be used as an efficient and reliable alternative to the X-Forwarded-For mechanism which is not always reliable and not even always usable. See also "tcp-request connection expect-netscaler-cip" for a finer-grained setting of which client is allowed to use the protocol.
Enforces the use of the PROXY protocol over any connection accepted by any of the sockets declared on the same line. Versions 1 and 2 of the PROXY protocol are supported and correctly detected. The PROXY protocol dictates the layer 3/4 addresses of the incoming connection to be used everywhere an address is used, with the only exception of "tcp-request connection" rules which will only see the real connection address. Logs will reflect the addresses indicated in the protocol, unless it is violated, in which case the real address will still be used. This keyword combined with support from external components can be used as an efficient and reliable alternative to the X-Forwarded-For mechanism which is not always reliable and not even always usable. See also "tcp-request connection expect-proxy" for a finer-grained setting of which client is allowed to use the protocol.
Allow receiving early data when using TLSv1.3. This is disabled by default, due to security considerations. Because it is vulnerable to replay attacks, you should only allow if for requests that are safe to replay, i.e. requests that are idempotent. You can use the "wait-for-handshake" action for any request that wouldn't be safe with early data.
This enables the TLS ALPN extension and advertises the specified protocol list as supported on top of ALPN. The protocol list consists in a comma- delimited list of protocol names, for instance: "http/1.1,http/1.0" (without quotes). This requires that the SSL library is built with support for TLS extensions enabled (check with haproxy -vv). The ALPN extension replaces the initial NPN extension. ALPN is required to enable HTTP/2 on an HTTP frontend. Versions of OpenSSL prior to 1.0.2 didn't support ALPN and only supposed the now obsolete NPN extension. At the time of writing this, most browsers still support both ALPN and NPN for HTTP/2 so a fallback to NPN may still work for a while. But ALPN must be used whenever possible. If both HTTP/2 and HTTP/1.1 are expected to be supported, both versions can be advertised, in order of preference, like below : bind :443 ssl crt pub.pem alpn h2,http/1.1
Sets the socket's backlog to this value. If unspecified or 0, the frontend's backlog is used instead, which generally defaults to the maxconn value.
This setting is only available when support for OpenSSL was built in. It sets the string describing the list of elliptic curves algorithms ("curve suite") that are negotiated during the SSL/TLS handshake with ECDHE. The format of the string is a colon-delimited list of curve name.
This setting is only available when support for OpenSSL was built in. It sets the named curve (RFC 4492) used to generate ECDH ephemeral keys. By default, used named curve is prime256v1.
This setting is only available when support for OpenSSL was built in. It designates a PEM file from which to load CA certificates used to verify client's certificate.
This setting is only available when support for OpenSSL was built in. Sets a comma separated list of errorIDs to ignore during verify at depth > 0. If set to 'all', all errors are ignored. SSL handshake is not aborted if an error is ignored.
This setting is only available when support for OpenSSL was built in. It designates a PEM file containing both the CA certificate and the CA private key used to create and sign server's certificates. This is a mandatory setting when the dynamic generation of certificates is enabled. See 'generate-certificates' for details.
This setting is only available when support for OpenSSL was built in. It is the CA private key passphrase. This setting is optional and used only when the dynamic generation of certificates is enabled. See 'generate-certificates' for details.
This setting is only available when support for OpenSSL was built in. It sets
the string describing the list of cipher algorithms ("cipher suite") that are
negotiated during the SSL/TLS handshake up to TLSv1.2. The format of the
string is defined in "man 1 ciphers" from OpenSSL man pages. For background
information and recommendations see e.g.
(https://wiki.mozilla.org/Security/Server_Side_TLS) and
(https://mozilla.github.io/server-side-tls/ssl-config-generator/). For TLSv1.3
cipher configuration, please check the "ciphersuites" keyword.
This setting is only available when support for OpenSSL was built in and OpenSSL 1.1.1 or later was used to build HAProxy. It sets the string describing the list of cipher algorithms ("cipher suite") that are negotiated during the TLSv1.3 handshake. The format of the string is defined in "man 1 ciphers" from OpenSSL man pages under the "ciphersuites" section. For cipher configuration for TLSv1.2 and earlier, please check the "ciphers" keyword.
This setting is only available when support for OpenSSL was built in. It designates a PEM file from which to load certificate revocation list used to verify client's certificate.
This setting is only available when support for OpenSSL was built in. It designates a PEM file containing both the required certificates and any associated private keys. This file can be built by concatenating multiple PEM files into one (e.g. cat cert.pem key.pem > combined.pem). If your CA requires an intermediate certificate, this can also be concatenated into this file. If the OpenSSL used supports Diffie-Hellman, parameters present in this file are loaded. If a directory name is used instead of a PEM file, then all files found in that directory will be loaded in alphabetic order unless their name ends with '.issuer', '.ocsp' or '.sctl' (reserved extensions). This directive may be specified multiple times in order to load certificates from multiple files or directories. The certificates will be presented to clients who provide a valid TLS Server Name Indication field matching one of their CN or alt subjects. Wildcards are supported, where a wildcard character '*' is used instead of the first hostname component (e.g. *.example.org matches www.example.org but not www.sub.example.org). If no SNI is provided by the client or if the SSL library does not support TLS extensions, or if the client provides an SNI hostname which does not match any certificate, then the first loaded certificate will be presented. This means that when loading certificates from a directory, it is highly recommended to load the default one first as a file or to ensure that it will always be the first one in the directory. Note that the same cert may be loaded multiple times without side effects. Some CAs (such as GoDaddy) offer a drop down list of server types that do not include HAProxy when obtaining a certificate. If this happens be sure to choose a web server that the CA believes requires an intermediate CA (for GoDaddy, selection Apache Tomcat will get the correct bundle, but many others, e.g. nginx, result in a wrong bundle that will not work for some clients). For each PEM file, haproxy checks for the presence of file at the same path suffixed by ".ocsp". If such file is found, support for the TLS Certificate Status Request extension (also known as "OCSP stapling") is automatically enabled. The content of this file is optional. If not empty, it must contain a valid OCSP Response in DER format. In order to be valid an OCSP Response must comply with the following rules: it has to indicate a good status, it has to be a single response for the certificate of the PEM file, and it has to be valid at the moment of addition. If these rules are not respected the OCSP Response is ignored and a warning is emitted. In order to identify which certificate an OCSP Response applies to, the issuer's certificate is necessary. If the issuer's certificate is not found in the PEM file, it will be loaded from a file at the same path as the PEM file suffixed by ".issuer" if it exists otherwise it will fail with an error. For each PEM file, haproxy also checks for the presence of file at the same path suffixed by ".sctl". If such file is found, support for Certificate Transparency (RFC6962) TLS extension is enabled. The file must contain a valid Signed Certificate Timestamp List, as described in RFC. File is parsed to check basic syntax, but no signatures are verified. There are cases where it is desirable to support multiple key types, e.g. RSA and ECDSA in the cipher suites offered to the clients. This allows clients that support EC certificates to be able to use EC ciphers, while simultaneously supporting older, RSA only clients. In order to provide this functionality, multiple PEM files, each with a different key type, are required. To associate these PEM files into a "cert bundle" that is recognized by haproxy, they must be named in the following way: All PEM files that are to be bundled must have the same base name, with a suffix indicating the key type. Currently, three suffixes are supported: rsa, dsa and ecdsa. For example, if www.example.com has two PEM files, an RSA file and an ECDSA file, they must be named: "example.pem.rsa" and "example.pem.ecdsa". The first part of the filename is arbitrary; only the suffix matters. To load this bundle into haproxy, specify the base name only:
bind :8443 ssl crt example.pem
Note that the suffix is not given to haproxy; this tells haproxy to look for a cert bundle. HAProxy will load all PEM files in the bundle at the same time to try to support multiple key types. PEM files are combined based on Common Name (CN) and Subject Alternative Name (SAN) to support SNI lookups. This means that even if you give haproxy a cert bundle, if there are no shared CN/SAN entries in the certificates in that bundle, haproxy will not be able to provide multi-cert support. Assuming bundle in the example above contained the following:
Filename | CN | SAN |
---|---|---|
example.pem.rsa | www.example.com | rsa.example.com |
example.pem.ecdsa | www.example.com | ecdsa.example.com |
Users connecting with an SNI of "www.example.com" will be able to use both RSA and ECDSA cipher suites. Users connecting with an SNI of "rsa.example.com" will only be able to use RSA cipher suites, and users connecting with "ecdsa.example.com" will only be able to use ECDSA cipher suites. With BoringSSL and Openssl >= 1.1.1 multi-cert is natively supported, no need to bundle certificates. ECDSA certificate will be preferred if client support it. If a directory name is given as the <cert> argument, haproxy will automatically search and load bundled files in that directory. OSCP files (.ocsp) and issuer files (.issuer) are supported with multi-cert bundling. Each certificate can have its own .ocsp and .issuer file. At this time, sctl is not supported in multi-certificate bundling.
This setting is only available when support for OpenSSL was built in. Sets a comma separated list of errorIDs to ignore during verify at depth == 0. If set to 'all', all errors are ignored. SSL handshake is not aborted if an error is ignored.
This setting is only available when support for OpenSSL was built in. It designates a list of PEM file with an optional ssl configuration and a SNI filter per certificate, with the following format for each line : <crtfile> [\[<sslbindconf> ...\]] [[!]<snifilter> ...] sslbindconf supports "allow-0rtt", "alpn", "ca-file", "ciphers", "ciphersuites", "crl-file", "curves", "ecdhe", "no-ca-names", "npn", "verify" configuration. With BoringSSL and Openssl >= 1.1.1 "ssl-min-ver" and "ssl-max-ver" are also supported. It overrides the configuration set in bind line for the certificate. Wildcards are supported in the SNI filter. Negative filter are also supported, only useful in combination with a wildcard filter to exclude a particular SNI. The certificates will be presented to clients who provide a valid TLS Server Name Indication field matching one of the SNI filters. If no SNI filter is specified, the CN and alt subjects are used. This directive may be specified multiple times. See the "crt" option for more information. The default certificate is still needed to meet OpenSSL expectations. If it is not used, the 'strict-sni' option may be used. Multi-cert bundling (see "crt") is supported with crt-list, as long as only the base name is given in the crt-list. SNI filter will do the same work on all bundled certificates. With BoringSSL and Openssl >= 1.1.1 multi-cert is natively supported, avoid multi-cert bundling. RSA and ECDSA certificates can be declared in a row, and set different ssl and filter parameter. crt-list file example: cert1.pem cert2.pem [alpn h2,http/1.1] certW.pem *.domain.tld !secure.domain.tld certS.pem [curves X25519:P-256 ciphers ECDHE-ECDSA-AES256-GCM-SHA384] secure.domain.tld
Is an optional keyword which is supported only on certain Linux kernels. It states that a connection will only be accepted once some data arrive on it, or at worst after the first retransmit. This should be used only on protocols for which the client talks first (e.g. HTTP). It can slightly improve performance by ensuring that most of the request is already available when the connection is accepted. On the other hand, it will not be able to detect connections which don't talk. It is important to note that this option is broken in all kernels up to 2.6.31, as the connection is never accepted until the client talks. This can cause issues with front firewalls which would see an established connection while the proxy will only see it in SYN_RECV. This option is only supported on TCPv4/TCPv6 sockets and ignored by other ones.
This option is only usable with the stats socket. It gives your stats socket the capability to pass listeners FD to another HAProxy process. During a reload with the master-worker mode, the process is automatically reexecuted adding -x and one of the stats socket with this option. See also "-x" in the management guide.
This option enforces use of SSLv3 only on SSL connections instantiated from this listener. SSLv3 is generally less expensive than the TLS counterparts for high connection rates. This option is also available on global statement "ssl-default-bind-options". See also "ssl-min-ver" and "ssl-max-ver".
This option enforces use of TLSv1.0 only on SSL connections instantiated from this listener. This option is also available on global statement "ssl-default-bind-options". See also "ssl-min-ver" and "ssl-max-ver".
This option enforces use of TLSv1.1 only on SSL connections instantiated from this listener. This option is also available on global statement "ssl-default-bind-options". See also "ssl-min-ver" and "ssl-max-ver".
This option enforces use of TLSv1.2 only on SSL connections instantiated from this listener. This option is also available on global statement "ssl-default-bind-options". See also "ssl-min-ver" and "ssl-max-ver".
This option enforces use of TLSv1.3 only on SSL connections instantiated from this listener. This option is also available on global statement "ssl-default-bind-options". See also "ssl-min-ver" and "ssl-max-ver".
This setting is only available when support for OpenSSL was built in. It enables the dynamic SSL certificates generation. A CA certificate and its private key are necessary (see 'ca-sign-file'). When HAProxy is configured as a transparent forward proxy, SSL requests generate errors because of a common name mismatch on the certificate presented to the client. With this option enabled, HAProxy will try to forge a certificate using the SNI hostname indicated by the client. This is done only if no certificate matches the SNI hostname (see 'crt-list'). If an error occurs, the default certificate is used, else the 'strict-sni' option is set. It can also be used when HAProxy is configured as a reverse proxy to ease the deployment of an architecture with many backends. Creating a SSL certificate is an expensive operation, so a LRU cache is used to store forged certificates (see 'tune.ssl.ssl-ctx-cache-size'). It increases the HAProxy's memory footprint to reduce latency when the same certificate is used many times.
Sets the group of the UNIX sockets to the designated system gid. It can also be set by default in the global section's "unix-bind" statement. Note that some platforms simply ignore this. This setting is equivalent to the "group" setting except that the group ID is used instead of its name. This setting is ignored by non UNIX sockets.
Sets the group of the UNIX sockets to the designated system group. It can also be set by default in the global section's "unix-bind" statement. Note that some platforms simply ignore this. This setting is equivalent to the "gid" setting except that the group name is used instead of its gid. This setting is ignored by non UNIX sockets.
Fixes the socket ID. By default, socket IDs are automatically assigned, but sometimes it is more convenient to fix them to ease monitoring. This value must be strictly positive and unique within the listener/frontend. This option can only be used when defining only a single socket.
Restricts the socket to a specific interface. When specified, only packets received from that particular interface are processed by the socket. This is currently only supported on Linux. The interface must be a primary system interface, not an aliased interface. It is also possible to bind multiple frontends to the same address if they are bound to different interfaces. Note that binding to a network interface requires root privileges. This parameter is only compatible with TCPv4/TCPv6 sockets. When specified, return traffic uses the same interface as inbound traffic, and its associated routing table, even if there are explicit routes through different interfaces configured. This can prove useful to address asymmetric routing issues when the same client IP addresses need to be able to reach frontends hosted on different interfaces.
This setting is used with the stats sockets only to restrict the nature of
the commands that can be issued on the socket. It is ignored by other
sockets. <level> can be one of :
- "user" is the least privileged level; only non-sensitive stats can be
read, and no change is allowed. It would make sense on systems where it
is not easy to restrict access to the socket.
- "operator" is the default level and fits most common uses. All data can
be read, and only non-sensitive changes are permitted (e.g. clear max
counters).
- "admin" should be used with care, as everything is permitted (e.g. clear
all counters).
This setting is used with the stats sockets only to configure severity level output prepended to informational feedback messages. Severity level of messages can range between 0 and 7, conforming to syslog rfc5424. Valid and successful socket commands requesting data (i.e. "show map", "get acl foo" etc.) will never have a severity level prepended. It is ignored by other sockets. <format> can be one of : - "none" (default) no severity level is prepended to feedback messages. - "number" severity level is prepended as a number. - "string" severity level is prepended as a string following the rfc5424 convention.
Limits the sockets to this number of concurrent connections. Extraneous connections will remain in the system's backlog until a connection is released. If unspecified, the limit will be the same as the frontend's maxconn. Note that in case of port ranges or multiple addresses, the same value will be applied to each socket. This setting enables different limitations on expensive sockets, for instance SSL entries which may easily eat all memory.
Sets the octal mode used to define access permissions on the UNIX socket. It can also be set by default in the global section's "unix-bind" statement. Note that some platforms simply ignore this. This setting is ignored by non UNIX sockets.
Sets the TCP Maximum Segment Size (MSS) value to be advertised on incoming connections. This can be used to force a lower MSS for certain specific ports, for instance for connections passing through a VPN. Note that this relies on a kernel feature which is theoretically supported under Linux but was buggy in all versions prior to 2.6.28. It may or may not work on other operating systems. It may also not change the advertised value but change the effective size of outgoing segments. The commonly advertised value for TCPv4 over Ethernet networks is 1460 = 1500(MTU) - 40(IP+TCP). If this value is positive, it will be used as the advertised MSS. If it is negative, it will indicate by how much to reduce the incoming connection's advertised MSS for outgoing segments. This parameter is only compatible with TCP v4/v6 sockets.
Sets an optional name for these sockets, which will be reported on the stats page.
On Linux, it is possible to specify which network namespace a socket will belong to. This directive makes it possible to explicitly bind a listener to a namespace different from the default one. Please refer to your operating system's documentation to find more details about network namespaces.
Sets the 'niceness' of connections initiated from the socket. Value must be in the range -1024..1024 inclusive, and defaults to zero. Positive values means that such connections are more friendly to others and easily offer their place in the scheduler. On the opposite, negative values mean that connections want to run with a higher priority than others. The difference only happens under high loads when the system is close to saturation. Negative values are appropriate for low-latency or administration services, and high values are generally recommended for CPU intensive tasks such as SSL processing or bulk transfers which are less sensible to latency. For example, it may make sense to use a positive value for an SMTP socket and a negative one for an RDP socket.
This setting is only available when support for OpenSSL was built in. It prevents from send CA names in server hello message when ca-file is used.
This setting is only available when support for OpenSSL was built in. It disables support for SSLv3 on any sockets instantiated from the listener when SSL is supported. Note that SSLv2 is forced disabled in the code and cannot be enabled using any configuration option. This option is also available on global statement "ssl-default-bind-options". Use "ssl-min-ver" and "ssl-max-ver" instead.
This setting is only available when support for OpenSSL was built in. It disables the stateless session resumption (RFC 5077 TLS Ticket extension) and force to use stateful session resumption. Stateless session resumption is more expensive in CPU usage. This option is also available on global statement "ssl-default-bind-options". The TLS ticket mechanism is only used up to TLS 1.2. Forward Secrecy is compromised with TLS tickets, unless ticket keys are periodically rotated (via reload or by using "tls-ticket-keys").
This setting is only available when support for OpenSSL was built in. It disables support for TLSv1.0 on any sockets instantiated from the listener when SSL is supported. Note that SSLv2 is forced disabled in the code and cannot be enabled using any configuration option. This option is also available on global statement "ssl-default-bind-options". Use "ssl-min-ver" and "ssl-max-ver" instead.
This setting is only available when support for OpenSSL was built in. It disables support for TLSv1.1 on any sockets instantiated from the listener when SSL is supported. Note that SSLv2 is forced disabled in the code and cannot be enabled using any configuration option. This option is also available on global statement "ssl-default-bind-options". Use "ssl-min-ver" and "ssl-max-ver" instead.
This setting is only available when support for OpenSSL was built in. It disables support for TLSv1.2 on any sockets instantiated from the listener when SSL is supported. Note that SSLv2 is forced disabled in the code and cannot be enabled using any configuration option. This option is also available on global statement "ssl-default-bind-options". Use "ssl-min-ver" and "ssl-max-ver" instead.
This setting is only available when support for OpenSSL was built in. It disables support for TLSv1.3 on any sockets instantiated from the listener when SSL is supported. Note that SSLv2 is forced disabled in the code and cannot be enabled using any configuration option. This option is also available on global statement "ssl-default-bind-options". Use "ssl-min-ver" and "ssl-max-ver" instead.
This enables the NPN TLS extension and advertises the specified protocol list
as supported on top of NPN. The protocol list consists in a comma-delimited
list of protocol names, for instance: "http/1.1,http/1.0" (without quotes).
This requires that the SSL library is built with support for TLS extensions
enabled (check with haproxy -vv). Note that the NPN extension has been
replaced with the ALPN extension (see the "alpn" keyword), though this one is
only available starting with OpenSSL 1.0.2. If HTTP/2 is desired on an older
version of OpenSSL, NPN might still be used as most clients still support it
at the time of writing this. It is possible to enable both NPN and ALPN
though it probably doesn't make any sense out of testing.
Use the client's preference when selecting the cipher suite, by default the server's preference is enforced. This option is also available on global statement "ssl-default-bind-options". Note that with OpenSSL >= 1.1.1 ChaCha20-Poly1305 is reprioritized anyway (without setting this option), if a ChaCha20-Poly1305 cipher is at the top of the client cipher list.
This restricts the list of processes or threads on which this listener is allowed to run. It does not enforce any process but eliminates those which do not match. If the frontend uses a "bind-process" setting, the intersection between the two is applied. If in the end the listener is not allowed to run on any remaining process, a warning is emitted, and the listener will either run on the first process of the listener if a single process was specified, or on all of its processes if multiple processes were specified. If a thread set is specified, it limits the threads allowed to process incoming connections for this listener, for the the process set. If multiple processes and threads are configured, a warning is emitted, as it either results from a configuration error or a misunderstanding of these models. For the unlikely case where several ranges are needed, this directive may be repeated. <process-set> and <thread-set> must use the format all | odd | even | number[-[number]] Ranges can be partially defined. The higher bound can be omitted. In such case, it is replaced by the corresponding maximum value. The main purpose of this directive is to be used with the stats sockets and have one different socket per process. The second purpose is to have multiple bind lines sharing the same IP:port but not the same process in a listener, so that the system can distribute the incoming connections into multiple queues and allow a smoother inter-process load balancing. Currently Linux 3.9 and above is known for supporting this. See also "bind-process" and "nbproc".
Forces the multiplexer's protocol to use for the incoming connections. It must be compatible with the mode of the frontend (TCP or HTTP). It must also be usable on the frontend side. The list of available protocols is reported in haproxy -vv. Idea behind this optipon is to bypass the selection of the best multiplexer's protocol for all connections instantiated from this listening socket. For instance, it is possible to force the http/2 on clear TCP by specifying "proto h2" on the bind line.
This setting is only available when support for OpenSSL was built in. It
enables SSL deciphering on connections instantiated from this listener. A
certificate is necessary (see "crt" above). All contents in the buffers will
appear in clear text, so that ACLs and HTTP processing will only have access
to deciphered contents. SSLv3 is disabled per default, use "ssl-min-ver SSLv3"
to enable it.
This option enforces use of <version> or lower on SSL connections instantiated from this listener. This option is also available on global statement "ssl-default-bind-options". See also "ssl-min-ver".
This option enforces use of <version> or upper on SSL connections instantiated from this listener. This option is also available on global statement "ssl-default-bind-options". See also "ssl-max-ver".
This setting is only available when support for OpenSSL was built in. The
SSL/TLS negotiation is allow only if the client provided an SNI which match
a certificate. The default certificate is not used.
See the "crt" option for more information.
Sets the TCP User Timeout for all incoming connections instantiated from this listening socket. This option is available on Linux since version 2.6.37. It allows haproxy to configure a timeout for sockets which contain data not receiving an acknowledgment for the configured delay. This is especially useful on long-lived connections experiencing long idle periods such as remote terminals or database connection pools, where the client and server timeouts must remain high to allow a long period of idle, but where it is important to detect that the client has disappeared in order to release all resources associated with its connection (and the server's session). The argument is a delay expressed in milliseconds by default. This only works for regular TCP connections, and is ignored for other protocols.
Is an optional keyword which is supported only on Linux kernels >= 3.7. It enables TCP Fast Open on the listening socket, which means that clients which support this feature will be able to send a request and receive a response during the 3-way handshake starting from second connection, thus saving one round-trip after the first connection. This only makes sense with protocols that use high connection rates and where each round trip matters. This can possibly cause issues with many firewalls which do not accept data on SYN packets, so this option should only be enabled once well tested. This option is only supported on TCPv4/TCPv6 sockets and ignored by other ones. You may need to build HAProxy with USE_TFO=1 if your libc doesn't define TCP_FASTOPEN.
Sets the TLS ticket keys file to load the keys from. The keys need to be 48 or 80 bytes long, depending if aes128 or aes256 is used, encoded with base64 with one line per key (ex. openssl rand 80 | openssl base64 -A | xargs echo). The first key determines the key length used for next keys: you can't mix aes128 and aes256 keys. Number of keys is specified by the TLS_TICKETS_NO build option (default 3) and at least as many keys need to be present in the file. Last TLS_TICKETS_NO keys will be used for decryption and the penultimate one for encryption. This enables easy key rotation by just appending new key to the file and reloading the process. Keys must be periodically rotated (ex. every 12h) or Perfect Forward Secrecy is compromised. It is also a good idea to keep the keys off any permanent storage such as hard drives (hint: use tmpfs and don't swap those files). Lifetime hint can be changed using tune.ssl.timeout.
Is an optional keyword which is supported only on certain Linux kernels. It indicates that the addresses will be bound even if they do not belong to the local machine, and that packets targeting any of these addresses will be intercepted just as if the addresses were locally configured. This normally requires that IP forwarding is enabled. Caution! do not use this with the default address '*', as it would redirect any traffic for the specified port. This keyword is available only when HAProxy is built with USE_LINUX_TPROXY=1. This parameter is only compatible with TCPv4 and TCPv6 sockets, depending on kernel version. Some distribution kernels include backports of the feature, so check for support with your vendor.
Is an optional keyword which is supported only on most recent systems including Linux kernels >= 2.4.21. It is used to bind a socket to both IPv4 and IPv6 when it uses the default address. Doing so is sometimes necessary on systems which bind to IPv6 only by default. It has no effect on non-IPv6 sockets, and is overridden by the "v6only" option.
Is an optional keyword which is supported only on most recent systems including Linux kernels >= 2.4.21. It is used to bind a socket to IPv6 only when it uses the default address. Doing so is sometimes preferred to doing it system-wide as it is per-listener. It has no effect on non-IPv6 sockets and has precedence over the "v4v6" option.
Sets the owner of the UNIX sockets to the designated system uid. It can also be set by default in the global section's "unix-bind" statement. Note that some platforms simply ignore this. This setting is equivalent to the "user" setting except that the user numeric ID is used instead of its name. This setting is ignored by non UNIX sockets.
Sets the owner of the UNIX sockets to the designated system user. It can also be set by default in the global section's "unix-bind" statement. Note that some platforms simply ignore this. This setting is equivalent to the "uid" setting except that the user name is used instead of its uid. This setting is ignored by non UNIX sockets.
This setting is only available when support for OpenSSL was built in. If set to 'none', client certificate is not requested. This is the default. In other cases, a client certificate is requested. If the client does not provide a certificate after the request and if 'verify' is set to 'required', then the handshake is aborted, while it would have succeeded if set to 'optional'. The certificate provided by the client is always verified using CAs from 'ca-file' and optional CRLs from 'crl-file'. On verify failure the handshake is aborted, regardless of the 'verify' option, unless the error code exactly matches one of those listed with 'ca-ignore-err' or 'crt-ignore-err'.
The "server" and "default-server" keywords support a certain number of settings which are all passed as arguments on the server line. The order in which those arguments appear does not count, and they are all optional. Some of those settings are single words (booleans) while others expect one or several values after them. In this case, the values must immediately follow the setting name. Except default-server, all those settings must be specified after the server's address if they are used: server <name> <address>[:port] [settings ...] default-server [settings ...] Note that all these settings are supported both by "server" and "default-server" keywords, except "id" which is only supported by "server". The currently supported settings are the following ones.
Using the "addr" parameter, it becomes possible to use a different IP address to send health-checks or to probe the agent-check. On some servers, it may be desirable to dedicate an IP address to specific component able to perform complex tests which are more suitable to health-checks than the application. This parameter is ignored if the "check" parameter is not set. See also the "port" parameter.
Enable an auxiliary agent check which is run independently of a regular health check. An agent health check is performed by making a TCP connection to the port set by the "agent-port" parameter and reading an ASCII string terminated by the first '\r' or '\n' met. The string is made of a series of words delimited by spaces, tabs or commas in any order, each consisting of : - An ASCII representation of a positive integer percentage, e.g. "75%". Values in this format will set the weight proportional to the initial weight of a server as configured when haproxy starts. Note that a zero weight is reported on the stats page as "DRAIN" since it has the same effect on the server (it's removed from the LB farm). - The string "maxconn:" followed by an integer (no space between). Values in this format will set the maxconn of a server. The maximum number of connections advertised needs to be multiplied by the number of load balancers and different backends that use this health check to get the total number of connections the server might receive. Example: maxconn:30 - The word "ready". This will turn the server's administrative state to the READY mode, thus canceling any DRAIN or MAINT state - The word "drain". This will turn the server's administrative state to the DRAIN mode, thus it will not accept any new connections other than those that are accepted via persistence. - The word "maint". This will turn the server's administrative state to the MAINT mode, thus it will not accept any new connections at all, and health checks will be stopped. - The words "down", "fail", or "stopped", optionally followed by a description string after a sharp ('#'). All of these mark the server's operating state as DOWN, but since the word itself is reported on the stats page, the difference allows an administrator to know if the situation was expected or not : the service may intentionally be stopped, may appear up but fail some validity tests, or may be seen as down (e.g. missing process, or port not responding). - The word "up" sets back the server's operating state as UP if health checks also report that the service is accessible. Parameters which are not advertised by the agent are not changed. For example, an agent might be designed to monitor CPU usage and only report a relative weight and never interact with the operating status. Similarly, an agent could be designed as an end-user interface with 3 radio buttons allowing an administrator to change only the administrative state. However, it is important to consider that only the agent may revert its own actions, so if a server is set to DRAIN mode or to DOWN state using the agent, the agent must implement the other equivalent actions to bring the service into operations again. Failure to connect to the agent is not considered an error as connectivity is tested by the regular health check which is enabled by the "check" parameter. Warning though, it is not a good idea to stop an agent after it reports "down", since only an agent reporting "up" will be able to turn the server up again. Note that the CLI on the Unix stats socket is also able to force an agent's result in order to work around a bogus agent if needed. Requires the "agent-port" parameter to be set. See also the "agent-inter" and "no-agent-check" parameters.
If this option is specified, haproxy will send the given string (verbatim) to the agent server upon connection. You could, for example, encode the backend name into this string, which would enable your agent to send different responses based on the backend. Make sure to include a '\n' if you want to terminate your request with a newline.
The "agent-inter" parameter sets the interval between two agent checks to <delay> milliseconds. If left unspecified, the delay defaults to 2000 ms. Just as with every other time-based parameter, it may be entered in any other explicit unit among { us, ms, s, m, h, d }. The "agent-inter" parameter also serves as a timeout for agent checks "timeout check" is not set. In order to reduce "resonance" effects when multiple servers are hosted on the same hardware, the agent and health checks of all servers are started with a small time offset between them. It is also possible to add some random noise in the agent and health checks interval using the global "spread-checks" keyword. This makes sense for instance when a lot of backends use the same servers. See also the "agent-check" and "agent-port" parameters.
The "agent-addr" parameter sets address for agent check. You can offload agent-check to another target, so you can make single place managing status and weights of servers defined in haproxy in case you can't make self-aware and self-managing services. You can specify both IP or hostname, it will be resolved.
The "agent-port" parameter sets the TCP port used for agent checks. See also the "agent-check" and "agent-inter" parameters.
Allow sending early data to the server when using TLS 1.3. Note that early data will be sent only if the client used early data, or if the backend uses "retry-on" with the "0rtt-rejected" keyword.
This enables the TLS ALPN extension and advertises the specified protocol list as supported on top of ALPN. The protocol list consists in a comma- delimited list of protocol names, for instance: "http/1.1,http/1.0" (without quotes). This requires that the SSL library is built with support for TLS extensions enabled (check with haproxy -vv). The ALPN extension replaces the initial NPN extension. ALPN is required to connect to HTTP/2 servers. Versions of OpenSSL prior to 1.0.2 didn't support ALPN and only supposed the now obsolete NPN extension. If both HTTP/2 and HTTP/1.1 are expected to be supported, both versions can be advertised, in order of preference, like below : server 127.0.0.1:443 ssl crt pub.pem alpn h2,http/1.1
When "backup" is present on a server line, the server is only used in load balancing when all other non-backup servers are unavailable. Requests coming with a persistence cookie referencing the server will always be served though. By default, only the first operational backup server is used, unless the "allbackups" option is set in the backend. See also the "no-backup" and "allbackups" options.
This setting is only available when support for OpenSSL was built in. It designates a PEM file from which to load CA certificates used to verify server's certificate.
This option enables health checks on the server. By default, a server is always considered available. If "check" is set, the server is available when accepting periodic TCP connections, to ensure that it is really able to serve requests. The default address and port to send the tests to are those of the server, and the default source is the same as the one defined in the backend. It is possible to change the address using the "addr" parameter, the port using the "port" parameter, the source address using the "source" address, and the interval and timers using the "inter", "rise" and "fall" parameters. The request method is define in the backend using the "httpchk", "smtpchk", "mysql-check", "pgsql-check" and "ssl-hello-chk" options. Please refer to those options and parameters for more information. See also "no-check" option.
This option forces emission of a PROXY protocol line with outgoing health checks, regardless of whether the server uses send-proxy or not for the normal traffic. By default, the PROXY protocol is enabled for health checks if it is already enabled for normal traffic and if no "port" nor "addr" directive is present. However, if such a directive is present, the "check-send-proxy" option needs to be used to force the use of the protocol. See also the "send-proxy" option for more information.
Defines which protocols to advertise with ALPN. The protocol list consists in a comma-delimited list of protocol names, for instance: "http/1.1,http/1.0" (without quotes). If it is not set, the server ALPN is used.
This option allows you to specify the SNI to be used when doing health checks over SSL. It is only possible to use a string to set <sni>. If you want to set a SNI for proxied traffic, see "sni".
This option forces encryption of all health checks over SSL, regardless of whether the server uses SSL or not for the normal traffic. This is generally used when an explicit "port" or "addr" directive is specified and SSL health checks are not inherited. It is important to understand that this option inserts an SSL transport layer below the checks, so that a simple TCP connect check becomes an SSL connect, which replaces the old ssl-hello-chk. The most common use is to send HTTPS checks by combining "httpchk" with SSL checks. All SSL settings are common to health checks and traffic (e.g. ciphers). See the "ssl" option for more information and "no-check-ssl" to disable this option.
This option enables outgoing health checks using upstream socks4 proxy. By default, the health checks won't go through socks tunnel even it was enabled for normal traffic.
This setting is only available when support for OpenSSL was built in. This
option sets the string describing the list of cipher algorithms that is
negotiated during the SSL/TLS handshake with the server. The format of the
string is defined in "man 1 ciphers" from OpenSSL man pages. For background
information and recommendations see e.g.
(https://wiki.mozilla.org/Security/Server_Side_TLS) and
(https://mozilla.github.io/server-side-tls/ssl-config-generator/). For TLSv1.3
cipher configuration, please check the "ciphersuites" keyword.
This setting is only available when support for OpenSSL was built in and OpenSSL 1.1.1 or later was used to build HAProxy. This option sets the string describing the list of cipher algorithms that is negotiated during the TLS 1.3 handshake with the server. The format of the string is defined in "man 1 ciphers" from OpenSSL man pages under the "ciphersuites" section. For cipher configuration for TLSv1.2 and earlier, please check the "ciphers" keyword.
The "cookie" parameter sets the cookie value assigned to the server to <value>. This value will be checked in incoming requests, and the first operational server possessing the same value will be selected. In return, in cookie insertion or rewrite modes, this value will be assigned to the cookie sent to the client. There is nothing wrong in having several servers sharing the same cookie value, and it is in fact somewhat common between normal and backup servers. See also the "cookie" keyword in backend section.
This setting is only available when support for OpenSSL was built in. It designates a PEM file from which to load certificate revocation list used to verify server's certificate.
This setting is only available when support for OpenSSL was built in. It designates a PEM file from which to load both a certificate and the associated private key. This file can be built by concatenating both PEM files into one. This certificate will be sent if the server send a client certificate request.
The "disabled" keyword starts the server in the "disabled" state. That means that it is marked down in maintenance mode, and no connection other than the ones allowed by persist mode will reach it. It is very well suited to setup new servers, because normal traffic will never reach them, while it is still possible to test the service by making use of the force-persist mechanism. See also "enabled" setting.
This option may be used as 'server' setting to reset any 'disabled' setting which would have been inherited from 'default-server' directive as default value. It may also be used as 'default-server' setting to reset any previous 'default-server' 'disabled' setting.
If health observing is enabled, the "error-limit" parameter specifies the number of consecutive errors that triggers event selected by the "on-error" option. By default it is set to 10 consecutive errors. See also the "check", "error-limit" and "on-error".
The "fall" parameter states that a server will be considered as dead after <count> consecutive unsuccessful health checks. This value defaults to 3 if unspecified. See also the "check", "inter" and "rise" parameters.
This option enforces use of SSLv3 only when SSL is used to communicate with the server. SSLv3 is generally less expensive than the TLS counterparts for high connection rates. This option is also available on global statement "ssl-default-server-options". See also "ssl-min-ver" and ssl-max-ver".
This option enforces use of TLSv1.0 only when SSL is used to communicate with the server. This option is also available on global statement "ssl-default-server-options". See also "ssl-min-ver" and ssl-max-ver".
This option enforces use of TLSv1.1 only when SSL is used to communicate with the server. This option is also available on global statement "ssl-default-server-options". See also "ssl-min-ver" and ssl-max-ver".
This option enforces use of TLSv1.2 only when SSL is used to communicate with the server. This option is also available on global statement "ssl-default-server-options". See also "ssl-min-ver" and ssl-max-ver".
This option enforces use of TLSv1.3 only when SSL is used to communicate with the server. This option is also available on global statement "ssl-default-server-options". See also "ssl-min-ver" and ssl-max-ver".
Set a persistent ID for the server. This ID must be positive and unique for the proxy. An unused ID will automatically be assigned if unset. The first assigned value will be 1. This ID is currently only returned in statistics.
Indicate in what order the server's address should be resolved upon startup if it uses an FQDN. Attempts are made to resolve the address by applying in turn each of the methods mentioned in the comma-delimited list. The first method which succeeds is used. If the end of the list is reached without finding a working method, an error is thrown. Method "last" suggests to pick the address which appears in the state file (see "server-state-file"). Method "libc" uses the libc's internal resolver (gethostbyname() or getaddrinfo() depending on the operating system and build options). Method "none" specifically indicates that the server should start without any valid IP address in a down state. It can be useful to ignore some DNS issues upon startup, waiting for the situation to get fixed later. Finally, an IP address (IPv4 or IPv6) may be provided. It can be the currently known address of the server (e.g. filled by a configuration generator), or the address of a dummy server used to catch old sessions and present them with a decent error message for example. When the "first" load balancing algorithm is used, this IP address could point to a fake server used to trigger the creation of new instances on the fly. This option defaults to "last,libc" indicating that the previous address found in the state file (if any) is used first, otherwise the libc's resolver is used. This ensures continued compatibility with the historic behavior.
defaults
# never fail on address resolution
default-server init-addr last,libc,none
The "inter" parameter sets the interval between two consecutive health checks to <delay> milliseconds. If left unspecified, the delay defaults to 2000 ms. It is also possible to use "fastinter" and "downinter" to optimize delays between checks depending on the server state :
Server state | Interval used |
---|---|
UP 100% (non-transitional) | "inter" |
Transitionally UP (going down "fall"), Transitionally DOWN (going up "rise"), or yet unchecked. | "fastinter" if set, "inter" otherwise. |
DOWN 100% (non-transitional) | "downinter" if set, "inter" otherwise. |
Just as with every other time-based parameter, they can be entered in any other explicit unit among { us, ms, s, m, h, d }. The "inter" parameter also serves as a timeout for health checks sent to servers if "timeout check" is not set. In order to reduce "resonance" effects when multiple servers are hosted on the same hardware, the agent and health checks of all servers are started with a small time offset between them. It is also possible to add some random noise in the agent and health checks interval using the global "spread-checks" keyword. This makes sense for instance when a lot of backends use the same servers.
The "maxconn" parameter specifies the maximal number of concurrent connections that will be sent to this server. If the number of incoming concurrent connections goes higher than this value, they will be queued, waiting for a slot to be released. This parameter is very important as it can save fragile servers from going down under extreme loads. If a "minconn" parameter is specified, the limit becomes dynamic. The default value is "0" which means unlimited. See also the "minconn" and "maxqueue" parameters, and the backend's "fullconn" keyword. In HTTP mode this parameter limits the number of concurrent requests instead of the number of connections. Multiple requests might be multiplexed over a single TCP connection to the server. As an example if you specify a maxconn of 50 you might see between 1 and 50 actual server connections, but no more than 50 concurrent requests.
The "maxqueue" parameter specifies the maximal number of connections which will wait in the queue for this server. If this limit is reached, next requests will be redispatched to other servers instead of indefinitely waiting to be served. This will break persistence but may allow people to quickly re-log in when the server they try to connect to is dying. The default value is "0" which means the queue is unlimited. See also the "maxconn" and "minconn" parameters.
The "max-reuse" argument indicates the HTTP connection processors that they should not reuse a server connection more than this number of times to send new requests. Permitted values are -1 (the default), which disables this limit, or any positive value. Value zero will effectively disable keep-alive. This is only used to work around certain server bugs which cause them to leak resources over time. The argument is not necessarily respected by the lower layers as there might be technical limitations making it impossible to enforce. At least HTTP/2 connections to servers will respect it.
When the "minconn" parameter is set, the maxconn limit becomes a dynamic limit following the backend's load. The server will always accept at least <minconn> connections, never more than <maxconn>, and the limit will be on the ramp between both values when the backend has less than <fullconn> concurrent connections. This makes it possible to limit the load on the server during normal loads, but push it further for important loads without overloading the server during exceptional loads. See also the "maxconn" and "maxqueue" parameters, as well as the "fullconn" backend keyword.
On Linux, it is possible to specify which network namespace a socket will belong to. This directive makes it possible to explicitly bind a server to a namespace different from the default one. Please refer to your operating system's documentation to find more details about network namespaces.
This option may be used as "server" setting to reset any "agent-check" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "agent-check" setting.
This option may be used as "server" setting to reset any "backup" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "backup" setting.
This option may be used as "server" setting to reset any "check" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "check" setting.
This option may be used as "server" setting to reset any "check-ssl" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "check-ssl" setting.
This option may be used as "server" setting to reset any "send-proxy" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "send-proxy" setting.
This option may be used as "server" setting to reset any "send-proxy-v2" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "send-proxy-v2" setting.
This option may be used as "server" setting to reset any "send-proxy-v2-ssl" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "send-proxy-v2-ssl" setting.
This option may be used as "server" setting to reset any "send-proxy-v2-ssl-cn" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "send-proxy-v2-ssl-cn" setting.
This option may be used as "server" setting to reset any "ssl" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "ssl" setting.
This option disables SSL session reuse when SSL is used to communicate with the server. It will force the server to perform a full handshake for every new connection. It's probably only useful for benchmarking, troubleshooting, and for paranoid users.
This option disables support for SSLv3 when SSL is used to communicate with the server. Note that SSLv2 is disabled in the code and cannot be enabled using any configuration option. Use "ssl-min-ver" and "ssl-max-ver" instead. Supported in default-server: No
This setting is only available when support for OpenSSL was built in. It disables the stateless session resumption (RFC 5077 TLS Ticket extension) and force to use stateful session resumption. Stateless session resumption is more expensive in CPU usage for servers. This option is also available on global statement "ssl-default-server-options". The TLS ticket mechanism is only used up to TLS 1.2. Forward Secrecy is compromised with TLS tickets, unless ticket keys are periodically rotated (via reload or by using "tls-ticket-keys"). See also "tls-tickets".
This option disables support for TLSv1.0 when SSL is used to communicate with the server. Note that SSLv2 is disabled in the code and cannot be enabled using any configuration option. TLSv1 is more expensive than SSLv3 so it often makes sense to disable it when communicating with local servers. This option is also available on global statement "ssl-default-server-options". Use "ssl-min-ver" and "ssl-max-ver" instead. Supported in default-server: No
This option disables support for TLSv1.1 when SSL is used to communicate with the server. Note that SSLv2 is disabled in the code and cannot be enabled using any configuration option. TLSv1 is more expensive than SSLv3 so it often makes sense to disable it when communicating with local servers. This option is also available on global statement "ssl-default-server-options". Use "ssl-min-ver" and "ssl-max-ver" instead. Supported in default-server: No
This option disables support for TLSv1.2 when SSL is used to communicate with the server. Note that SSLv2 is disabled in the code and cannot be enabled using any configuration option. TLSv1 is more expensive than SSLv3 so it often makes sense to disable it when communicating with local servers. This option is also available on global statement "ssl-default-server-options". Use "ssl-min-ver" and "ssl-max-ver" instead. Supported in default-server: No
This option disables support for TLSv1.3 when SSL is used to communicate with the server. Note that SSLv2 is disabled in the code and cannot be enabled using any configuration option. TLSv1 is more expensive than SSLv3 so it often makes sense to disable it when communicating with local servers. This option is also available on global statement "ssl-default-server-options". Use "ssl-min-ver" and "ssl-max-ver" instead. Supported in default-server: No
This option may be used as "server" setting to reset any "verifyhost" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "verifyhost" setting.
This option may be used as "server" setting to reset any "tfo" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "tfo" setting.
Never add connections allocated to this sever to a stick-table. This may be used in conjunction with backup to ensure that stick-table persistence is disabled for backup servers.
This enables the NPN TLS extension and advertises the specified protocol list
as supported on top of NPN. The protocol list consists in a comma-delimited
list of protocol names, for instance: "http/1.1,http/1.0" (without quotes).
This requires that the SSL library is built with support for TLS extensions
enabled (check with haproxy -vv). Note that the NPN extension has been
replaced with the ALPN extension (see the "alpn" keyword), though this one is
only available starting with OpenSSL 1.0.2.
This option enables health adjusting based on observing communication with the server. By default this functionality is disabled and enabling it also requires to enable health checks. There are two supported modes: "layer4" and "layer7". In layer4 mode, only successful/unsuccessful tcp connections are significant. In layer7, which is only allowed for http proxies, responses received from server are verified, like valid/wrong http code, unparsable headers, a timeout, etc. Valid status codes include 100 to 499, 501 and 505. See also the "check", "on-error" and "error-limit".
Select what should happen when enough consecutive errors are detected. Currently, four modes are available: - fastinter: force fastinter - fail-check: simulate a failed check, also forces fastinter (default) - sudden-death: simulate a pre-fatal failed health check, one more failed check will mark a server down, forces fastinter - mark-down: mark the server immediately down and force fastinter See also the "check", "observe" and "error-limit".
Modify what occurs when a server is marked down. Currently one action is available: - shutdown-sessions: Shutdown peer sessions. When this setting is enabled, all connections to the server are immediately terminated when the server goes down. It might be used if the health check detects more complex cases than a simple connection status, and long timeouts would cause the service to remain unresponsive for too long a time. For instance, a health check might detect that a database is stuck and that there's no chance to reuse existing connections anymore. Connections killed this way are logged with a 'D' termination code (for "Down"). Actions are disabled by default
Modify what occurs when a server is marked up. Currently one action is available: - shutdown-backup-sessions: Shutdown sessions on all backup servers. This is done only if the server is not in backup state and if it is not disabled (it must have an effective weight > 0). This can be used sometimes to force an active server to take all the traffic back after recovery when dealing with long sessions (e.g. LDAP, SQL, ...). Doing this can cause more trouble than it tries to solve (e.g. incomplete transactions), so use this feature with extreme care. Sessions killed because a server comes up are logged with an 'U' termination code (for "Up"). Actions are disabled by default
Set the maximum number of idling connections for a server. -1 means unlimited connections, 0 means no idle connections. The default is -1. When idle connections are enabled, orphaned idle connections which do not belong to any client session anymore are moved to a dedicated pool so that they remain usable by future clients. This only applies to connections that can be shared according to the same principles as those applying to "http-reuse".
Sets the delay to start purging idle connections. Each <delay> interval, half of the idle connections are closed. 0 means we don't keep any idle connection. The default is 5s.
Using the "port" parameter, it becomes possible to use a different port to send health-checks. On some servers, it may be desirable to dedicate a port to a specific component able to perform complex tests which are more suitable to health-checks than the application. It is common to run a simple script in inetd for instance. This parameter is ignored if the "check" parameter is not set. See also the "addr" parameter.
Forces the multiplexer's protocol to use for the outgoing connections to this server. It must be compatible with the mode of the backend (TCP or HTTP). It must also be usable on the backend side. The list of available protocols is reported in haproxy -vv. Idea behind this optipon is to bypass the selection of the best multiplexer's protocol for all connections established to this server.
The "redir" parameter enables the redirection mode for all GET and HEAD requests addressing this server. This means that instead of having HAProxy forward the request to the server, it will send an "HTTP 302" response with the "Location" header composed of this prefix immediately followed by the requested URI beginning at the leading '/' of the path component. That means that no trailing slash should be used after <prefix>. All invalid requests will be rejected, and all non-GET or HEAD requests will be normally served by the server. Note that since the response is completely forged, no header mangling nor cookie insertion is possible in the response. However, cookies in requests are still analyzed, making this solution completely usable to direct users to a remote location in case of local disaster. Main use consists in increasing bandwidth for static servers by having the clients directly connect to them. Note: never use a relative location here, it would cause a loop between the client and HAProxy!
server srv1 192.168.1.1:80 redir http://image1.mydomain.com check
The "rise" parameter states that a server will be considered as operational after <count> consecutive successful health checks. This value defaults to 2 if unspecified. See also the "check", "inter" and "fall" parameters.
Comma separated list of options to apply to DNS resolution linked to this server. Available options: * allow-dup-ip By default, HAProxy prevents IP address duplication in a backend when DNS resolution at runtime is in operation. That said, for some cases, it makes sense that two servers (in the same backend, being resolved by the same FQDN) have the same IP address. For such case, simply enable this option. This is the opposite of prevent-dup-ip. * ignore-weight Ignore any weight that is set within an SRV record. This is useful when you would like to control the weights using an alternate method, such as using an "agent-check" or through the runtime api. * prevent-dup-ip Ensure HAProxy's default behavior is enforced on a server: prevent re-using an IP address already set to a server in the same backend and sharing the same fqdn. This is the opposite of allow-dup-ip.
backend b_myapp
default-server init-addr none resolvers dns
server s1 myapp.example.com:80 check resolve-opts allow-dup-ip
server s2 myapp.example.com:81 check resolve-opts allow-dup-ip
With the option allow-dup-ip set: * if the nameserver returns a single IP address, then both servers will use it * If the nameserver returns 2 IP addresses, then each server will pick up a different address Default value: not set
When DNS resolution is enabled for a server and multiple IP addresses from different families are returned, HAProxy will prefer using an IP address from the family mentioned in the "resolve-prefer" parameter. Available families: "ipv4" and "ipv6" Default value: ipv6
server s1 app1.domain.com:80 resolvers mydns resolve-prefer ipv6
This option prioritizes the choice of an ip address matching a network. This is useful with clouds to prefer a local ip. In some cases, a cloud high availability service can be announced with many ip addresses on many different datacenters. The latency between datacenter is not negligible, so this patch permits to prefer a local datacenter. If no address matches the configured network, another address is selected.
server s1 app1.domain.com:80 resolvers mydns resolve-net 10.0.0.0/8
Points to an existing "resolvers" section to resolve current server's
hostname.
server s1 app1.domain.com:80 check resolvers mydns
See also section 5.3
The "send-proxy" parameter enforces use of the PROXY protocol over any connection established to this server. The PROXY protocol informs the other end about the layer 3/4 addresses of the incoming connection, so that it can know the client's address or the public address it accessed to, whatever the upper layer protocol. For connections accepted by an "accept-proxy" or "accept-netscaler-cip" listener, the advertised address will be used. Only TCPv4 and TCPv6 address families are supported. Other families such as Unix sockets, will report an UNKNOWN family. Servers using this option can fully be chained to another instance of haproxy listening with an "accept-proxy" setting. This setting must not be used if the server isn't aware of the protocol. When health checks are sent to the server, the PROXY protocol is automatically used when this option is set, unless there is an explicit "port" or "addr" directive, in which case an explicit "check-send-proxy" directive would also be needed to use the PROXY protocol. See also the "no-send-proxy" option of this section and "accept-proxy" and "accept-netscaler-cip" option of the "bind" keyword.
The "send-proxy-v2" parameter enforces use of the PROXY protocol version 2 over any connection established to this server. The PROXY protocol informs the other end about the layer 3/4 addresses of the incoming connection, so that it can know the client's address or the public address it accessed to, whatever the upper layer protocol. It also send ALPN information if an alpn have been negotiated. This setting must not be used if the server isn't aware of this version of the protocol. See also the "no-send-proxy-v2" option of this section and send-proxy" option of the "bind" keyword.
The "proxy-v2-options" parameter add option to send in PROXY protocol version 2 when "send-proxy-v2" is used. Options available are "ssl" (see also send-proxy-v2-ssl), "cert-cn" (see also "send-proxy-v2-ssl-cn"), "ssl-cipher": name of the used cipher, "cert-sig": signature algorithm of the used certificate, "cert-key": key algorithm of the used certificate), "authority": host name value passed by the client (only sni from a tls connection is supported), "crc32c": checksum of the proxy protocol v2 header.
The "send-proxy-v2-ssl" parameter enforces use of the PROXY protocol version 2 over any connection established to this server. The PROXY protocol informs the other end about the layer 3/4 addresses of the incoming connection, so that it can know the client's address or the public address it accessed to, whatever the upper layer protocol. In addition, the SSL information extension of the PROXY protocol is added to the PROXY protocol header. This setting must not be used if the server isn't aware of this version of the protocol. See also the "no-send-proxy-v2-ssl" option of this section and the "send-proxy-v2" option of the "bind" keyword.
The "send-proxy-v2-ssl" parameter enforces use of the PROXY protocol version 2 over any connection established to this server. The PROXY protocol informs the other end about the layer 3/4 addresses of the incoming connection, so that it can know the client's address or the public address it accessed to, whatever the upper layer protocol. In addition, the SSL information extension of the PROXY protocol, along along with the Common Name from the subject of the client certificate (if any), is added to the PROXY protocol header. This setting must not be used if the server isn't aware of this version of the protocol. See also the "no-send-proxy-v2-ssl-cn" option of this section and the "send-proxy-v2" option of the "bind" keyword.
The "slowstart" parameter for a server accepts a value in milliseconds which indicates after how long a server which has just come back up will run at full speed. Just as with every other time-based parameter, it can be entered in any other explicit unit among { us, ms, s, m, h, d }. The speed grows linearly from 0 to 100% during this time. The limitation applies to two parameters : - maxconn: the number of connections accepted by the server will grow from 1 to 100% of the usual dynamic limit defined by (minconn,maxconn,fullconn). - weight: when the backend uses a dynamic weighted algorithm, the weight grows linearly from 1 to 100%. In this case, the weight is updated at every health-check. For this reason, it is important that the "inter" parameter is smaller than the "slowstart", in order to maximize the number of steps. The slowstart never applies when haproxy starts, otherwise it would cause trouble to running servers. It only applies when a server has been previously seen as failed.
The "sni" parameter evaluates the sample fetch expression, converts it to a string and uses the result as the host name sent in the SNI TLS extension to the server. A typical use case is to send the SNI received from the client in a bridged HTTPS scenario, using the "ssl_fc_sni" sample fetch for the expression, though alternatives such as req.hdr(host) can also make sense. If "verify required" is set (which is the recommended setting), the resulting name will also be matched against the server certificate's names. See the "verify" directive for more details. If you want to set a SNI for health checks, see the "check-sni" directive for more details.
The "source" parameter sets the source address which will be used when connecting to the server. It follows the exact same parameters and principle as the backend "source" keyword, except that it only applies to the server referencing it. Please consult the "source" keyword for details. Additionally, the "source" statement on a server line allows one to specify a source port range by indicating the lower and higher bounds delimited by a dash ('-'). Some operating systems might require a valid IP address when a source port range is specified. It is permitted to have the same IP/range for several servers. Doing so makes it possible to bypass the maximum of 64k total concurrent connections. The limit will then reach 64k connections per server. Since Linux 4.2/libc 2.23 IP_BIND_ADDRESS_NO_PORT is set for connections specifying the source address without port(s).
This option enables SSL ciphering on outgoing connections to the server. It is critical to verify server certificates using "verify" when using SSL to connect to servers, otherwise the communication is prone to trivial man in the-middle attacks rendering SSL useless. When this option is used, health checks are automatically sent in SSL too unless there is a "port" or an "addr" directive indicating the check should be sent to a different location. See the "no-ssl" to disable "ssl" option and "check-ssl" option to force SSL health checks.
This option enforces use of <version> or lower when SSL is used to communicate with the server. This option is also available on global statement "ssl-default-server-options". See also "ssl-min-ver".
This option enforces use of <version> or upper when SSL is used to communicate with the server. This option is also available on global statement "ssl-default-server-options". See also "ssl-max-ver".
This option may be used as "server" setting to reset any "no-ssl-reuse" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "no-ssl-reuse" setting.
This option may be used as "server" setting to reset any "non-stick" setting which would have been inherited from "default-server" directive as default value. It may also be used as "default-server" setting to reset any previous "default-server" "non-stick" setting.
This option enables upstream socks4 tunnel for outgoing connections to the server. Using this option won't force the health check to go via socks4 by default. You will have to use the keyword "check-via-socks4" to enable it.
Sets the TCP User Timeout for all outgoing connections to this server. This option is available on Linux since version 2.6.37. It allows haproxy to configure a timeout for sockets which contain data not receiving an acknowledgment for the configured delay. This is especially useful on long-lived connections experiencing long idle periods such as remote terminals or database connection pools, where the client and server timeouts must remain high to allow a long period of idle, but where it is important to detect that the server has disappeared in order to release all resources associated with its connection (and the client's session). One typical use case is also to force dead server connections to die when health checks are too slow or during a soft reload since health checks are then disabled. The argument is a delay expressed in milliseconds by default. This only works for regular TCP connections, and is ignored for other protocols.
This option enables using TCP fast open when connecting to servers, on systems that support it (currently only the Linux kernel >= 4.11). See the "tfo" bind option for more information about TCP fast open. Please note that when using tfo, you should also use the "conn-failure", "empty-response" and "response-timeout" keywords for "retry-on", or haproxy won't be able to retry the connection on failure. See also "no-tfo".
This option enables ability to set the current state of the server by tracking another one. It is possible to track a server which itself tracks another server, provided that at the end of the chain, a server has health checks enabled. If <proxy> is omitted the current one is used. If disable-on-404 is used, it has to be enabled on both proxies.
This option may be used as "server" setting to reset any "no-tls-tickets" setting which would have been inherited from "default-server" directive as default value. The TLS ticket mechanism is only used up to TLS 1.2. Forward Secrecy is compromised with TLS tickets, unless ticket keys are periodically rotated (via reload or by using "tls-ticket-keys"). It may also be used as "default-server" setting to reset any previous "default-server" "no-tls-tickets" setting.
This setting is only available when support for OpenSSL was built in. If set to 'none', server certificate is not verified. In the other case, The certificate provided by the server is verified using CAs from 'ca-file' and optional CRLs from 'crl-file' after having checked that the names provided in the certificate's subject and subjectAlternateNames attributes match either the name passed using the "sni" directive, or if not provided, the static host name passed using the "verifyhost" directive. When no name is found, the certificate's names are ignored. For this reason, without SNI it's important to use "verifyhost". On verification failure the handshake is aborted. It is critically important to verify server certificates when using SSL to connect to servers, otherwise the communication is prone to trivial man-in-the-middle attacks rendering SSL totally useless. Unless "ssl_server_verify" appears in the global section, "verify" is set to "required" by default.
This setting is only available when support for OpenSSL was built in, and only takes effect if 'verify required' is also specified. This directive sets a default static hostname to check the server's certificate against when no SNI was used to connect to the server. If SNI is not used, this is the only way to enable hostname verification. This static hostname, when set, will also be used for health checks (which cannot provide an SNI value). If none of the hostnames in the certificate match the specified hostname, the handshake is aborted. The hostnames in the server-provided certificate may include wildcards. See also "verify", "sni" and "no-verifyhost" options.
The "weight" parameter is used to adjust the server's weight relative to other servers. All servers will receive a load proportional to their weight relative to the sum of all weights, so the higher the weight, the higher the load. The default weight is 1, and the maximal value is 256. A value of 0 means the server will not participate in load-balancing but will still accept persistent connections. If this parameter is used to distribute the load according to server's capacity, it is recommended to start with values which can both grow and shrink, for instance between 10 and 100 to leave enough room above and below for later adjustments.
HAProxy allows using a host name on the server line to retrieve its IP address using name servers. By default, HAProxy resolves the name when parsing the configuration file, at startup and cache the result for the process's life. This is not sufficient in some cases, such as in Amazon where a server's IP can change after a reboot or an ELB Virtual IP can change based on current workload. This chapter describes how HAProxy can be configured to process server's name resolution at run time. Whether run time server name resolution has been enable or not, HAProxy will carry on doing the first resolution when parsing the configuration.
As we've seen in introduction, name resolution in HAProxy occurs at two different steps of the process life: 1. when starting up, HAProxy parses the server line definition and matches a host name. It uses libc functions to get the host name resolved. This resolution relies on /etc/resolv.conf file. 2. at run time, HAProxy performs periodically name resolutions for servers requiring DNS resolutions. A few other events can trigger a name resolution at run time: - when a server's health check ends up in a connection timeout: this may be because the server has a new IP address. So we need to trigger a name resolution to know this new IP. When using resolvers, the server name can either be a hostname, or a SRV label. HAProxy considers anything that starts with an underscore as a SRV label. If a SRV label is specified, then the corresponding SRV records will be retrieved from the DNS server, and the provided hostnames will be used. The SRV label will be checked periodically, and if any server are added or removed, haproxy will automatically do the same. A few things important to notice: - all the name servers are queried in the meantime. HAProxy will process the first valid response. - a resolution is considered as invalid (NX, timeout, refused), when all the servers return an error.
This section is dedicated to host information related to name resolution in HAProxy. There can be as many as resolvers section as needed. Each section can contain many name servers. When multiple name servers are configured in a resolvers section, then HAProxy uses the first valid response. In case of invalid responses, only the last one is treated. Purpose is to give the chance to a slow server to deliver a valid answer after a fast faulty or outdated server. When each server returns a different error type, then only the last error is used by HAProxy. The following processing is applied on this error: 1. HAProxy retries the same DNS query with a new query type. The A queries are switch to AAAA or the opposite. SRV queries are not concerned here. Timeout errors are also excluded. 2. When the fallback on the query type was done (or not applicable), HAProxy retries the original DNS query, with the preferred query type. 3. HAProxy retries previous steps <resolve_retires> times. If no valid response is received after that, it stops the DNS resolution and reports the error. For example, with 2 name servers configured in a resolvers section, the following scenarios are possible: - First response is valid and is applied directly, second response is ignored - First response is invalid and second one is valid, then second response is applied - First response is a NX domain and second one a truncated response, then HAProxy retries the query with a new type - First response is a NX domain and second one is a timeout, then HAProxy retries the query with a new type - Query timed out for both name servers, then HAProxy retries it with the same query type As a DNS server may not answer all the IPs in one DNS request, haproxy keeps a cache of previous answers, an answer will be considered obsolete after <hold obsolete> seconds without the IP returned.
Creates a new name server list labeled <resolvers id> A resolvers section accept the following parameters:
Defines the maximum payload size accepted by HAProxy and announced to all the name servers configured in this resolvers section. <nb> is in bytes. If not set, HAProxy announces 512. (minimal value defined by RFC 6891) Note: the maximum allowed value is 8192.
DNS server description: <id> : label of the server, should be unique <ip> : IP address of the server <port> : port where the DNS service actually runs
Adds all nameservers found in /etc/resolv.conf to this resolvers nameservers list. Ordered as if each nameserver in /etc/resolv.conf was individually placed in the resolvers section in place of this directive.
Defines <period> during which the last name resolution should be kept based
on last resolution <status>
<status> : last name resolution status. Acceptable values are "nx",
"other", "refused", "timeout", "valid", "obsolete".
<period> : interval between two successive name resolution when the last
answer was in <status>. It follows the HAProxy time format.
<period> is in milliseconds by default.
Default value is 10s for "valid", 0s for "obsolete" and 30s for others.
Defines the number <nb> of queries to send to resolve a server name before giving up. Default value: 3 A retry occurs on name server timeout or when the full sequence of DNS query type failover is over and we need to start up from the default ANY query type.
Defines timeouts related to name resolution <event> : the event on which the <time> timeout period applies to. events available are: - resolve : default time to trigger name resolutions when no other time applied. Default value: 1s - retry : time between two DNS queries, when no valid response have been received. Default value: 1s <time> : time related to the event. It follows the HAProxy time format. <time> is expressed in milliseconds.
resolvers mydns
nameserver dns1 10.0.0.1:53
nameserver dns2 10.0.0.2:53
parse-resolv-conf
resolve_retries 3
timeout resolve 1s
timeout retry 1s
hold other 30s
hold refused 30s
hold nx 30s
hold timeout 30s
hold valid 10s
hold obsolete 30s
HAProxy provides a cache, which was designed to perform cache on small objects (favicon, css...). This is a minimalist low-maintenance cache which runs in RAM. The cache is based on a memory which is shared between processes and threads, this memory is split in blocks of 1k. If an object is not used anymore, it can be deleted to store a new object independently of its expiration date. The oldest objects are deleted first when we try to allocate a new one. The cache uses a hash of the host header and the URI as the key. It's possible to view the status of a cache using the Unix socket command "show cache" consult section 9.3 "Unix Socket commands" of Management Guide for more details. When an object is delivered from the cache, the server name in the log is replaced by "<CACHE>".
The cache won't store and won't deliver objects in these cases: - If the response is not a 200 - If the response contains a Vary header - If the Content-Length + the headers size is greater than "max-object-size" - If the response is not cacheable - If the request is not a GET - If the HTTP version of the request is smaller than 1.1 - If the request contains an Authorization header
To setup a cache, you must define a cache section and use it in a proxy with the corresponding http-request and response actions.
Declare a cache section, allocate a shared cache memory named <name>, the size of cache is mandatory.
Define the size in RAM of the cache in megabytes. This size is split in blocks of 1kB which are used by the cache entries. Its maximum value is 4095.
Define the maximum size of the objects to be cached. Must not be greater than an half of "total-max-size". If not set, it equals to a 256th of the cache size. All objects with sizes larger than "max-object-size" will not be cached.
Define the maximum expiration duration. The expiration is set has the lowest value between the s-maxage or max-age (in this order) directive in the Cache-Control response header and this value. The default value is 60 seconds, which means that you can't cache an object more than 60 seconds by default.
Try to deliver a cached object from the cache <name>. This directive is also mandatory to store the cache as it calculates the cache hash. If you want to use a condition for both storage and delivering that's a good idea to put it after this one.
Store an http-response within the cache. The storage of the response headers is done at this step, which means you can use others http-response actions to modify headers before or after the storage of the response. This action is responsible for the setup of the cache storage filter.
backend bck1
mode http
http-request cache-use foobar
http-response cache-store foobar
server srv1 127.0.0.1:80
cache foobar
total-max-size 4
max-age 240
HAProxy is capable of extracting data from request or response streams, from client or server information, from tables, environmental information etc... The action of extracting such data is called fetching a sample. Once retrieved, these samples may be used for various purposes such as a key to a stick-table, but most common usages consist in matching them against predefined constant data called patterns.
The use of Access Control Lists (ACL) provides a flexible solution to perform content switching and generally to take decisions based on content extracted from the request, the response or any environmental status. The principle is simple : - extract a data sample from a stream, table or the environment - optionally apply some format conversion to the extracted sample - apply one or multiple pattern matching methods on this sample - perform actions only when a pattern matches the sample The actions generally consist in blocking a request, selecting a backend, or adding a header. In order to define a test, the "acl" keyword is used. The syntax is : acl <aclname> <criterion> [flags] [operator] [<value>] ... This creates a new ACL <aclname> or completes an existing one with new tests. Those tests apply to the portion of request/response specified in <criterion> and may be adjusted with optional flags [flags]. Some criteria also support an operator which may be specified before the set of values. Optionally some conversion operators may be applied to the sample, and they will be specified as a comma-delimited list of keywords just after the first keyword. The values are of the type supported by the criterion, and are separated by spaces. ACL names must be formed from upper and lower case letters, digits, '-' (dash), '_' (underscore) , '.' (dot) and ':' (colon). ACL names are case-sensitive, which means that "my_acl" and "My_Acl" are two different ACLs. There is no enforced limit to the number of ACLs. The unused ones do not affect performance, they just consume a small amount of memory. The criterion generally is the name of a sample fetch method, or one of its ACL specific declinations. The default test method is implied by the output type of this sample fetch method. The ACL declinations can describe alternate matching methods of a same sample fetch method. The sample fetch methods are the only ones supporting a conversion. Sample fetch methods return data which can be of the following types : - boolean - integer (signed or unsigned) - IPv4 or IPv6 address - string - data block Converters transform any of these data into any of these. For example, some converters might convert a string to a lower-case string while other ones would turn a string to an IPv4 address, or apply a netmask to an IP address. The resulting sample is of the type of the last converter applied to the list, which defaults to the type of the sample fetch method. Each sample or converter returns data of a specific type, specified with its keyword in this documentation. When an ACL is declared using a standard sample fetch method, certain types automatically involved a default matching method which are summarized in the table below : +---------------------+-----------------+ | Sample or converter | Default | | output type | matching method | +---------------------+-----------------+ | boolean | bool | +---------------------+-----------------+ | integer | int | +---------------------+-----------------+ | ip | ip | +---------------------+-----------------+ | string | str | +---------------------+-----------------+ | binary | none, use "-m" | +---------------------+-----------------+ Note that in order to match a binary samples, it is mandatory to specify a matching method, see below. The ACL engine can match these types against patterns of the following types : - boolean - integer or integer range - IP address / network - string (exact, substring, suffix, prefix, subdir, domain) - regular expression - hex block The following ACL flags are currently supported : -i : ignore case during matching of all subsequent patterns. -f : load patterns from a file. -m : use a specific pattern matching method -n : forbid the DNS resolutions -M : load the file pointed by -f like a map file. -u : force the unique id of the ACL -- : force end of flags. Useful when a string looks like one of the flags. The "-f" flag is followed by the name of a file from which all lines will be read as individual values. It is even possible to pass multiple "-f" arguments if the patterns are to be loaded from multiple files. Empty lines as well as lines beginning with a sharp ('#') will be ignored. All leading spaces and tabs will be stripped. If it is absolutely necessary to insert a valid pattern beginning with a sharp, just prefix it with a space so that it is not taken for a comment. Depending on the data type and match method, haproxy may load the lines into a binary tree, allowing very fast lookups. This is true for IPv4 and exact string matching. In this case, duplicates will automatically be removed. The "-M" flag allows an ACL to use a map file. If this flag is set, the file is parsed as two column file. The first column contains the patterns used by the ACL, and the second column contain the samples. The sample can be used later by a map. This can be useful in some rare cases where an ACL would just be used to check for the existence of a pattern in a map before a mapping is applied. The "-u" flag forces the unique id of the ACL. This unique id is used with the socket interface to identify ACL and dynamically change its values. Note that a file is always identified by its name even if an id is set. Also, note that the "-i" flag applies to subsequent entries and not to entries loaded from files preceding it. For instance : acl valid-ua hdr(user-agent) -f exact-ua.lst -i -f generic-ua.lst test In this example, each line of "exact-ua.lst" will be exactly matched against the "user-agent" header of the request. Then each line of "generic-ua" will be case-insensitively matched. Then the word "test" will be insensitively matched as well. The "-m" flag is used to select a specific pattern matching method on the input sample. All ACL-specific criteria imply a pattern matching method and generally do not need this flag. However, this flag is useful with generic sample fetch methods to describe how they're going to be matched against the patterns. This is required for sample fetches which return data type for which there is no obvious matching method (e.g. string or binary). When "-m" is specified and followed by a pattern matching method name, this method is used instead of the default one for the criterion. This makes it possible to match contents in ways that were not initially planned, or with sample fetch methods which return a string. The matching method also affects the way the patterns are parsed. The "-n" flag forbids the dns resolutions. It is used with the load of ip files. By default, if the parser cannot parse ip address it considers that the parsed string is maybe a domain name and try dns resolution. The flag "-n" disable this resolution. It is useful for detecting malformed ip lists. Note that if the DNS server is not reachable, the haproxy configuration parsing may last many minutes waiting for the timeout. During this time no error messages are displayed. The flag "-n" disable this behavior. Note also that during the runtime, this function is disabled for the dynamic acl modifications. There are some restrictions however. Not all methods can be used with all sample fetch methods. Also, if "-m" is used in conjunction with "-f", it must be placed first. The pattern matching method must be one of the following : - "found" : only check if the requested sample could be found in the stream, but do not compare it against any pattern. It is recommended not to pass any pattern to avoid confusion. This matching method is particularly useful to detect presence of certain contents such as headers, cookies, etc... even if they are empty and without comparing them to anything nor counting them. - "bool" : check the value as a boolean. It can only be applied to fetches which return a boolean or integer value, and takes no pattern. Value zero or false does not match, all other values do match. - "int" : match the value as an integer. It can be used with integer and boolean samples. Boolean false is integer 0, true is integer 1. - "ip" : match the value as an IPv4 or IPv6 address. It is compatible with IP address samples only, so it is implied and never needed. - "bin" : match the contents against a hexadecimal string representing a binary sequence. This may be used with binary or string samples. - "len" : match the sample's length as an integer. This may be used with binary or string samples. - "str" : exact match : match the contents against a string. This may be used with binary or string samples. - "sub" : substring match : check that the contents contain at least one of the provided string patterns. This may be used with binary or string samples. - "reg" : regex match : match the contents against a list of regular expressions. This may be used with binary or string samples. - "beg" : prefix match : check that the contents begin like the provided string patterns. This may be used with binary or string samples. - "end" : suffix match : check that the contents end like the provided string patterns. This may be used with binary or string samples. - "dir" : subdir match : check that a slash-delimited portion of the contents exactly matches one of the provided string patterns. This may be used with binary or string samples. - "dom" : domain match : check that a dot-delimited portion of the contents exactly match one of the provided string patterns. This may be used with binary or string samples. For example, to quickly detect the presence of cookie "JSESSIONID" in an HTTP request, it is possible to do : acl jsess_present cook(JSESSIONID) -m found In order to apply a regular expression on the 500 first bytes of data in the buffer, one would use the following acl : acl script_tag payload(0,500) -m reg -i <script> On systems where the regex library is much slower when using "-i", it is possible to convert the sample to lowercase before matching, like this : acl script_tag payload(0,500),lower -m reg <script> All ACL-specific criteria imply a default matching method. Most often, these criteria are composed by concatenating the name of the original sample fetch method and the matching method. For example, "hdr_beg" applies the "beg" match to samples retrieved using the "hdr" fetch method. Since all ACL-specific criteria rely on a sample fetch method, it is always possible instead to use the original sample fetch method and the explicit matching method using "-m". If an alternate match is specified using "-m" on an ACL-specific criterion, the matching method is simply applied to the underlying sample fetch method. For example, all ACLs below are exact equivalent : acl short_form hdr_beg(host) www. acl alternate1 hdr_beg(host) -m beg www. acl alternate2 hdr_dom(host) -m beg www. acl alternate3 hdr(host) -m beg www. The table below summarizes the compatibility matrix between sample or converter types and the pattern types to fetch against. It indicates for each compatible combination the name of the matching method to be used, surrounded with angle brackets ">" and "<" when the method is the default one and will work by default without "-m". +-------------------------------------------------+ | Input sample type | +----------------------+---------+---------+---------+---------+---------+ | pattern type | boolean | integer | ip | string | binary | +----------------------+---------+---------+---------+---------+---------+ | none (presence only) | found | found | found | found | found | +----------------------+---------+---------+---------+---------+---------+ | none (boolean value) |> bool <| bool | | bool | | +----------------------+---------+---------+---------+---------+---------+ | integer (value) | int |> int <| int | int | | +----------------------+---------+---------+---------+---------+---------+ | integer (length) | len | len | len | len | len | +----------------------+---------+---------+---------+---------+---------+ | IP address | | |> ip <| ip | ip | +----------------------+---------+---------+---------+---------+---------+ | exact string | str | str | str |> str <| str | +----------------------+---------+---------+---------+---------+---------+ | prefix | beg | beg | beg | beg | beg | +----------------------+---------+---------+---------+---------+---------+ | suffix | end | end | end | end | end | +----------------------+---------+---------+---------+---------+---------+ | substring | sub | sub | sub | sub | sub | +----------------------+---------+---------+---------+---------+---------+ | subdir | dir | dir | dir | dir | dir | +----------------------+---------+---------+---------+---------+---------+ | domain | dom | dom | dom | dom | dom | +----------------------+---------+---------+---------+---------+---------+ | regex | reg | reg | reg | reg | reg | +----------------------+---------+---------+---------+---------+---------+ | hex block | | | | bin | bin | +----------------------+---------+---------+---------+---------+---------+
In order to match a boolean, no value is needed and all values are ignored. Boolean matching is used by default for all fetch methods of type "boolean". When boolean matching is used, the fetched value is returned as-is, which means that a boolean "true" will always match and a boolean "false" will never match. Boolean matching may also be enforced using "-m bool" on fetch methods which return an integer value. Then, integer value 0 is converted to the boolean "false" and all other values are converted to "true".
Integer matching applies by default to integer fetch methods. It can also be enforced on boolean fetches using "-m int". In this case, "false" is converted to the integer 0, and "true" is converted to the integer 1. Integer matching also supports integer ranges and operators. Note that integer matching only applies to positive values. A range is a value expressed with a lower and an upper bound separated with a colon, both of which may be omitted. For instance, "1024:65535" is a valid range to represent a range of unprivileged ports, and "1024:" would also work. "0:1023" is a valid representation of privileged ports, and ":1023" would also work. As a special case, some ACL functions support decimal numbers which are in fact two integers separated by a dot. This is used with some version checks for instance. All integer properties apply to those decimal numbers, including ranges and operators. For an easier usage, comparison operators are also supported. Note that using operators with ranges does not make much sense and is strongly discouraged. Similarly, it does not make much sense to perform order comparisons with a set of values. Available operators for integer matching are : eq : true if the tested value equals at least one value ge : true if the tested value is greater than or equal to at least one value gt : true if the tested value is greater than at least one value le : true if the tested value is less than or equal to at least one value lt : true if the tested value is less than at least one value For instance, the following ACL matches any negative Content-Length header : acl negative-length hdr_val(content-length) lt 0 This one matches SSL versions between 3.0 and 3.1 (inclusive) : acl sslv3 req_ssl_ver 3:3.1
String matching applies to string or binary fetch methods, and exists in 6 different forms : - exact match (-m str) : the extracted string must exactly match the patterns; - substring match (-m sub) : the patterns are looked up inside the extracted string, and the ACL matches if any of them is found inside; - prefix match (-m beg) : the patterns are compared with the beginning of the extracted string, and the ACL matches if any of them matches. - suffix match (-m end) : the patterns are compared with the end of the extracted string, and the ACL matches if any of them matches. - subdir match (-m dir) : the patterns are looked up inside the extracted string, delimited with slashes ("/"), and the ACL matches if any of them matches. - domain match (-m dom) : the patterns are looked up inside the extracted string, delimited with dots ("."), and the ACL matches if any of them matches. String matching applies to verbatim strings as they are passed, with the exception of the backslash ("\") which makes it possible to escape some characters such as the space. If the "-i" flag is passed before the first string, then the matching will be performed ignoring the case. In order to match the string "-i", either set it second, or pass the "--" flag before the first string. Same applies of course to match the string "--". Do not use string matches for binary fetches which might contain null bytes (0x00), as the comparison stops at the occurrence of the first null byte. Instead, convert the binary fetch to a hex string with the hex converter first.
# matches if the string <tag> is present in the binary sample
acl tag_found req.payload(0,0),hex -m sub 3C7461673E
Just like with string matching, regex matching applies to verbatim strings as they are passed, with the exception of the backslash ("\") which makes it possible to escape some characters such as the space. If the "-i" flag is passed before the first regex, then the matching will be performed ignoring the case. In order to match the string "-i", either set it second, or pass the "--" flag before the first string. Same principle applies of course to match the string "--".
It is possible to match some extracted samples against a binary block which may not safely be represented as a string. For this, the patterns must be passed as a series of hexadecimal digits in an even number, when the match method is set to binary. Each sequence of two digits will represent a byte. The hexadecimal digits may be used upper or lower case.
# match "Hello\n" in the input stream (\x48 \x65 \x6c \x6c \x6f \x0a)
acl hello payload(0,6) -m bin 48656c6c6f0a
IPv4 addresses values can be specified either as plain addresses or with a netmask appended, in which case the IPv4 address matches whenever it is within the network. Plain addresses may also be replaced with a resolvable host name, but this practice is generally discouraged as it makes it more difficult to read and debug configurations. If hostnames are used, you should at least ensure that they are present in /etc/hosts so that the configuration does not depend on any random DNS match at the moment the configuration is parsed. The dotted IPv4 address notation is supported in both regular as well as the abbreviated form with all-0-octets omitted: +------------------+------------------+------------------+ | Example 1 | Example 2 | Example 3 | +------------------+------------------+------------------+ | 192.168.0.1 | 10.0.0.12 | 127.0.0.1 | | 192.168.1 | 10.12 | 127.1 | | 192.168.0.1/22 | 10.0.0.12/8 | 127.0.0.1/8 | | 192.168.1/22 | 10.12/8 | 127.1/8 | +------------------+------------------+------------------+ Notice that this is different from RFC 4632 CIDR address notation in which 192.168.42/24 would be equivalent to 192.168.42.0/24. IPv6 may be entered in their usual form, with or without a netmask appended. Only bit counts are accepted for IPv6 netmasks. In order to avoid any risk of trouble with randomly resolved IP addresses, host names are never allowed in IPv6 patterns. HAProxy is also able to match IPv4 addresses with IPv6 addresses in the following situations : - tested address is IPv4, pattern address is IPv4, the match applies in IPv4 using the supplied mask if any. - tested address is IPv6, pattern address is IPv6, the match applies in IPv6 using the supplied mask if any. - tested address is IPv6, pattern address is IPv4, the match applies in IPv4 using the pattern's mask if the IPv6 address matches with 2002:IPV4::, ::IPV4 or ::ffff:IPV4, otherwise it fails. - tested address is IPv4, pattern address is IPv6, the IPv4 address is first converted to IPv6 by prefixing ::ffff: in front of it, then the match is applied in IPv6 using the supplied IPv6 mask.
Some actions are only performed upon a valid condition. A condition is a combination of ACLs with operators. 3 operators are supported : - AND (implicit) - OR (explicit with the "or" keyword or the "||" operator) - Negation with the exclamation mark ("!") A condition is formed as a disjunctive form: [!]acl1 [!]acl2 ... [!]acln { or [!]acl1 [!]acl2 ... [!]acln } ... Such conditions are generally used after an "if" or "unless" statement, indicating when the condition will trigger the action. For instance, to block HTTP requests to the "*" URL with methods other than "OPTIONS", as well as POST requests without content-length, and GET or HEAD requests with a content-length greater than 0, and finally every request which is not either GET/HEAD/POST/OPTIONS ! acl missing_cl hdr_cnt(Content-length) eq 0 http-request deny if HTTP_URL_STAR !METH_OPTIONS || METH_POST missing_cl http-request deny if METH_GET HTTP_CONTENT http-request deny unless METH_GET or METH_POST or METH_OPTIONS To select a different backend for requests to static contents on the "www" site and to every request on the "img", "video", "download" and "ftp" hosts : acl url_static path_beg /static /images /img /css acl url_static path_end .gif .png .jpg .css .js acl host_www hdr_beg(host) -i www acl host_static hdr_beg(host) -i img. video. download. ftp. # now use backend "static" for all static-only hosts, and for static URLs # of host "www". Use backend "www" for the rest. use_backend static if host_static or host_www url_static use_backend www if host_www It is also possible to form rules using "anonymous ACLs". Those are unnamed ACL expressions that are built on the fly without needing to be declared. They must be enclosed between braces, with a space before and after each brace (because the braces must be seen as independent words). Example : The following rule : acl missing_cl hdr_cnt(Content-length) eq 0 http-request deny if METH_POST missing_cl Can also be written that way : http-request deny if METH_POST { hdr_cnt(Content-length) eq 0 } It is generally not recommended to use this construct because it's a lot easier to leave errors in the configuration when written that way. However, for very simple rules matching only one source IP address for instance, it can make more sense to use them than to declare ACLs with random names. Another example of good use is the following : With named ACLs : acl site_dead nbsrv(dynamic) lt 2 acl site_dead nbsrv(static) lt 2 monitor fail if site_dead With anonymous ACLs : monitor fail if { nbsrv(dynamic) lt 2 } || { nbsrv(static) lt 2 } See section 4.2 for detailed help on the "http-request deny" and "use_backend" keywords.
Historically, sample fetch methods were only used to retrieve data to match against patterns using ACLs. With the arrival of stick-tables, a new class of sample fetch methods was created, most often sharing the same syntax as their ACL counterpart. These sample fetch methods are also known as "fetches". As of now, ACLs and fetches have converged. All ACL fetch methods have been made available as fetch methods, and ACLs may use any sample fetch method as well. This section details all available sample fetch methods and their output type. Some sample fetch methods have deprecated aliases that are used to maintain compatibility with existing configurations. They are then explicitly marked as deprecated and should not be used in new setups. The ACL derivatives are also indicated when available, with their respective matching methods. These ones all have a well defined default pattern matching method, so it is never necessary (though allowed) to pass the "-m" option to indicate how the sample will be matched using ACLs. As indicated in the sample type versus matching compatibility matrix above, when using a generic sample fetch method in an ACL, the "-m" option is mandatory unless the sample type is one of boolean, integer, IPv4 or IPv6. When the same keyword exists as an ACL keyword and as a standard fetch method, the ACL engine will automatically pick the ACL-only one by default. Some of these keywords support one or multiple mandatory arguments, and one or multiple optional arguments. These arguments are strongly typed and are checked when the configuration is parsed so that there is no risk of running with an incorrect argument (e.g. an unresolved backend name). Fetch function arguments are passed between parenthesis and are delimited by commas. When an argument is optional, it will be indicated below between square brackets ('[ ]'). When all arguments are optional, the parenthesis may be omitted. Thus, the syntax of a standard sample fetch method is one of the following : - name - name(arg1) - name(arg1,arg2)
Sample fetch methods may be combined with transformations to be applied on top of the fetched sample (also called "converters"). These combinations form what is called "sample expressions" and the result is a "sample". Initially this was only supported by "stick on" and "stick store-request" directives but this has now be extended to all places where samples may be used (ACLs, log-format, unique-id-format, add-header, ...). These transformations are enumerated as a series of specific keywords after the sample fetch method. These keywords may equally be appended immediately after the fetch keyword's argument, delimited by a comma. These keywords can also support some arguments (e.g. a netmask) which must be passed in parenthesis. A certain category of converters are bitwise and arithmetic operators which support performing basic operations on integers. Some bitwise operations are supported (and, or, xor, cpl) and some arithmetic operations are supported (add, sub, mul, div, mod, neg). Some comparators are provided (odd, even, not, bool) which make it possible to report a match without having to write an ACL. The currently available list of transformation keywords include :
Returns values for the properties requested as a string, where values are separated by the delimiter specified with "51degrees-property-separator". The device is identified using the User-Agent header passed to the converter. The function can be passed up to five property names, and if a property name can't be found, the value "NoData" is returned.
# Here the header "X-51D-DeviceTypeMobileTablet" is added to the request,
# containing values for the three properties requested by using the
# User-Agent passed to the converter.
frontend http-in
bind *:8081
default_backend servers
http-request set-header X-51D-DeviceTypeMobileTablet \
%[req.fhdr(User-Agent),51d.single(DeviceType,IsMobile,IsTablet)]
Adds <value> to the input value of type signed integer, and returns the result as a signed integer. <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Decrypts the raw byte input using the AES128-GCM, AES192-GCM or AES256-GCM algorithm, depending on the <bits> parameter. All other parameters need to be base64 encoded and the returned result is in raw byte format. If the <aead_tag> validation fails, the converter doesn't return any data. The <nonce>, <key> and <aead_tag> can either be strings or variables. This converter requires at least OpenSSL 1.0.1.
http-response set-header X-Decrypted-Text %[var(txn.enc),\
aes_gcm_dec(128,txn.nonce,Zm9vb2Zvb29mb29wZm9vbw==,txn.aead_tag)]
Performs a bitwise "AND" between <value> and the input value of type signed integer, and returns the result as an signed integer. <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Converts (decodes) a base64 encoded input string to its binary representation. It performs the inverse operation of base64().
Converts a binary input sample to a base64 string. It is used to log or transfer binary content in a way that can be reliably transferred (e.g. an SSL ID can be copied in a header).
Returns a boolean TRUE if the input value of type signed integer is non-null, otherwise returns FALSE. Used in conjunction with and(), it can be used to report true/false for bit testing on input values (e.g. verify the presence of a flag).
Extracts some bytes from an input binary sample. The result is a binary sample starting at an offset (in bytes) of the original sample and optionally truncated at the given length.
Concatenates up to 3 fields after the current sample which is then turned to a string. The first one, <start>, is a constant string, that will be appended immediately after the existing sample. It may be omitted if not used. The second one, <var>, is a variable name. The variable will be looked up, its contents converted to a string, and it will be appended immediately after the <first> part. If the variable is not found, nothing is appended. It may be omitted as well. The third field, <end> is a constant string that will be appended after the variable. It may also be omitted. Together, these elements allow to concatenate variables with delimiters to an existing set of variables. This can be used to build new variables made of a succession of other variables, such as colon-delimited values. Note that due to the config parser, it is not possible to use a comma nor a closing parenthesis as delimiters.
tcp-request session set-var(sess.src) src
tcp-request session set-var(sess.dn) ssl_c_s_dn
tcp-request session set-var(txn.sig) str(),concat(<ip=,sess.ip,>),concat(<dn=,sess.dn,>)
http-request set-header x-hap-sig %[var(txn.sig)]
Takes the input value of type signed integer, applies a ones-complement (flips all bits) and returns the result as an signed integer.
Hashes a binary input sample into an unsigned 32-bit quantity using the CRC32 hash function. Optionally, it is possible to apply a full avalanche hash function to the output if the optional <avalanche> argument equals 1. This converter uses the same functions as used by the various hash-based load balancing algorithms, so it will provide exactly the same results. It is provided for compatibility with other software which want a CRC32 to be computed on some input keys, so it follows the most common implementation as found in Ethernet, Gzip, PNG, etc... It is slower than the other algorithms but may provide a better or at least less predictable distribution. It must not be used for security purposes as a 32-bit hash is trivial to break. See also "djb2", "sdbm", "wt6", "crc32c" and the "hash-type" directive.
Hashes a binary input sample into an unsigned 32-bit quantity using the CRC32C hash function. Optionally, it is possible to apply a full avalanche hash function to the output if the optional <avalanche> argument equals 1. This converter uses the same functions as described in RFC4960, Appendix B [8]. It is provided for compatibility with other software which want a CRC32C to be computed on some input keys. It is slower than the other algorithms and it must not be used for security purposes as a 32-bit hash is trivial to break. See also "djb2", "sdbm", "wt6", "crc32" and the "hash-type" directive.
Asks the DeviceAtlas converter to identify the User Agent string passed on input, and to emit a string made of the concatenation of the properties enumerated in argument, delimited by the separator defined by the global keyword "deviceatlas-property-separator", or by default the pipe character ('|'). There's a limit of 12 different properties imposed by the haproxy configuration language.
frontend www
bind *:8881
default_backend servers
http-request set-header X-DeviceAtlas-Data %[req.fhdr(User-Agent),da-csv(primaryHardwareType,osName,osVersion,browserName,browserVersion,browserRenderingEngine)]
This converter is used as debug tool. It takes a capture of the input sample and sends it to event sink <destination>, which may designate a ring buffer such as "buf0", as well as "stdout", or "stderr". Available sinks may be checked at run time by issuing "show events" on the CLI. When not specified, the output will be "buf0", which may be consulted via the CLI's "show events" command. An optional prefix <prefix> may be passed to help distinguish outputs from multiple expressions. It will then appear before the colon in the output message. The input sample is passed as-is on the output, so that it is safe to insert the debug converter anywhere in a chain, even with non- printable sample types.
tcp-request connection track-sc0 src,debug(track-sc)
Divides the input value of type signed integer by <value>, and returns the result as an signed integer. If <value> is null, the largest unsigned integer is returned (typically 2^63-1). <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Hashes a binary input sample into an unsigned 32-bit quantity using the DJB2 hash function. Optionally, it is possible to apply a full avalanche hash function to the output if the optional <avalanche> argument equals 1. This converter uses the same functions as used by the various hash-based load balancing algorithms, so it will provide exactly the same results. It is mostly intended for debugging, but can be used as a stick-table entry to collect rough statistics. It must not be used for security purposes as a 32-bit hash is trivial to break. See also "crc32", "sdbm", "wt6", "crc32c", and the "hash-type" directive.
Returns a boolean TRUE if the input value of type signed integer is even otherwise returns FALSE. It is functionally equivalent to "not,and(1),bool".
Extracts the substring at the given index counting from the beginning (positive index) or from the end (negative index) considering given delimiters from an input string. Indexes start at 1 or -1 and delimiters are a string formatted list of chars. Optionally you can specify <count> of fields to extract (default: 1). Value of 0 indicates extraction of all remaining fields.
str(f1_f2_f3__f5),field(5,_) # f5
str(f1_f2_f3__f5),field(2,_,0) # f2_f3__f5
str(f1_f2_f3__f5),field(2,_,2) # f2_f3
str(f1_f2_f3__f5),field(-2,_,3) # f2_f3_
str(f1_f2_f3__f5),field(-3,_,0) # f1_f2_f3
Converts a binary input sample to a hex string containing two hex digits per input byte. It is used to log or transfer hex dumps of some binary input data in a way that can be reliably transferred (e.g. an SSL ID can be copied in a header).
Converts a hex string containing two hex digits per input byte to an integer. If the input value cannot be converted, then zero is returned.
Converts an integer supposed to contain a date since epoch to a string representing this date in a format suitable for use in HTTP header fields. If an offset value is specified, then it is added to the date before the conversion is operated. This is particularly useful to emit Date header fields, Expires values in responses when combined with a positive offset, or Last-Modified values when the offset is negative. If a unit value is specified, then consider the timestamp as either "s" for seconds (default behavior), "ms" for milliseconds, or "us" for microseconds since epoch. Offset is assumed to have the same unit as input timestamp.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, a boolean false is returned. Otherwise a boolean true is returned. This can be used to verify the presence of a certain key in a table tracking some elements (e.g. whether or not a source IP address or an Authorization header was already seen). ipmask(<mask4>, [<mask6>]) Apply a mask to an IP address, and use the result for lookups and storage. This can be used to make all hosts within a certain mask to share the same table entries and as such use the same server. The mask4 can be passed in dotted form (e.g. 255.255.255.0) or in CIDR form (e.g. 24). The mask6 can be passed in quadruplet form (e.g. ffff:ffff::) or in CIDR form (e.g. 64). If no mask6 is given IPv6 addresses will fail to convert for backwards compatibility reasons.
Escapes the input string and produces an ASCII output string ready to use as a JSON string. The converter tries to decode the input string according to the <input-code> parameter. It can be "ascii", "utf8", "utf8s", "utf8p" or "utf8ps". The "ascii" decoder never fails. The "utf8" decoder detects 3 types of errors: - bad UTF-8 sequence (lone continuation byte, bad number of continuation bytes, ...) - invalid range (the decoded value is within a UTF-8 prohibited range), - code overlong (the value is encoded with more bytes than necessary). The UTF-8 JSON encoding can produce a "too long value" error when the UTF-8 character is greater than 0xffff because the JSON string escape specification only authorizes 4 hex digits for the value encoding. The UTF-8 decoder exists in 4 variants designated by a combination of two suffix letters : "p" for "permissive" and "s" for "silently ignore". The behaviors of the decoders are : - "ascii" : never fails; - "utf8" : fails on any detected errors; - "utf8s" : never fails, but removes characters corresponding to errors; - "utf8p" : accepts and fixes the overlong errors, but fails on any other error; - "utf8ps" : never fails, accepts and fixes the overlong errors, but removes characters corresponding to the other errors. This converter is particularly useful for building properly escaped JSON for logging to servers which consume JSON-formatted traffic logs.
capture request header Host len 15
capture request header user-agent len 150
log-format '{"ip":"%[src]","user-agent":"%[capture.req.hdr(1),json(utf8s)]"}'
Input request from client 127.0.0.1: GET / HTTP/1.0 User-Agent: Very "Ugly" UA 1/2 Output log: {"ip":"127.0.0.1","user-agent":"Very \"Ugly\" UA 1\/2"}
Returns the value with the highest q-factor from a list as extracted from the "accept-language" header using "req.fhdr". Values with no q-factor have a q-factor of 1. Values with a q-factor of 0 are dropped. Only values which belong to the list of semi-colon delimited <values> will be considered. The argument <value> syntax is "lang[;lang[;lang[;...]]]". If no value matches the given list and a default value is provided, it is returned. Note that language names may have a variant after a dash ('-'). If this variant is present in the list, it will be matched, but if it is not, only the base language is checked. The match is case-sensitive, and the output string is always one of those provided in arguments. The ordering of arguments is meaningless, only the ordering of the values in the request counts, as the first value among multiple sharing the same q-factor is used.
# this configuration switches to the backend matching a
# given language based on the request :
acl es req.fhdr(accept-language),language(es;fr;en) -m str es
acl fr req.fhdr(accept-language),language(es;fr;en) -m str fr
acl en req.fhdr(accept-language),language(es;fr;en) -m str en
use_backend spanish if es
use_backend french if fr
use_backend english if en
default_backend choose_your_language
Get the length of the string. This can only be placed after a string sample fetch function or after a transformation keyword returning a string type. The result is of type integer.
Convert a string sample to lower case. This can only be placed after a string sample fetch function or after a transformation keyword returning a string type. The result is of type string.
Converts an integer supposed to contain a date since epoch to a string representing this date in local time using a format defined by the <format> string using strftime(3). The purpose is to allow any date format to be used in logs. An optional <offset> in seconds may be applied to the input date (positive or negative). See the strftime() man page for the format supported by your operating system. See also the utime converter.
# Emit two colons, one with the local time and another with ip:port
# e.g. 20140710162350 127.0.0.1:57325
log-format %[date,ltime(%Y%m%d%H%M%S)]\ %ci:%cp
map_<match_type>(<map_file>[,<default_value>]) map_<match_type>_<output_type>(<map_file>[,<default_value>]) Search the input value from <map_file> using the <match_type> matching method, and return the associated value converted to the type <output_type>. If the input value cannot be found in the <map_file>, the converter returns the <default_value>. If the <default_value> is not set, the converter fails and acts as if no input value could be fetched. If the <match_type> is not set, it defaults to "str". Likewise, if the <output_type> is not set, it defaults to "str". For convenience, the "map" keyword is an alias for "map_str" and maps a string to another string. It is important to avoid overlapping between the keys : IP addresses and strings are stored in trees, so the first of the finest match will be used. Other keys are stored in lists, so the first matching occurrence will be used. The following array contains the list of all map functions available sorted by input type, match type and output type.
input type | match method | output type str | output type int | output type ip |
---|---|---|---|---|
str | str | map_str | map_str_int | map_str_ip |
str | beg | map_beg | map_beg_int | map_end_ip |
str | sub | map_sub | map_sub_int | map_sub_ip |
str | dir | map_dir | map_dir_int | map_dir_ip |
str | dom | map_dom | map_dom_int | map_dom_ip |
str | end | map_end | map_end_int | map_end_ip |
str | reg | map_reg | map_reg_int | map_reg_ip |
str | reg | map_regm | map_reg_int | map_reg_ip |
int | int | map_int | map_int_int | map_int_ip |
ip | ip | map_ip | map_ip_int | map_ip_ip |
The special map called "map_regm" expect matching zone in the regular expression and modify the output replacing back reference (like "\1") by the corresponding match text. The file contains one key + value per line. Lines which start with '#' are ignored, just like empty lines. Leading tabs and spaces are stripped. The key is then the first "word" (series of non-space/tabs characters), and the value is what follows this series of space/tab till the end of the line excluding trailing spaces/tabs.
# this is a comment and is ignored
2.22.246.0/23 United Kingdom \n
<-><-----------><--><------------><---->
| | | | `- trailing spaces ignored
| | | `---------- value
| | `-------------------- middle spaces ignored
| `---------------------------- key
`------------------------------------ leading spaces ignored
Divides the input value of type signed integer by <value>, and returns the remainder as an signed integer. If <value> is null, then zero is returned. <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Multiplies the input value of type signed integer by <value>, and returns the product as an signed integer. In case of overflow, the largest possible value for the sign is returned so that the operation doesn't wrap around. <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Takes an input value of type string, interprets it as a backend name and returns the number of usable servers in that backend. Can be used in places where we want to look up a backend from a dynamic name, like a result of a map lookup.
Takes the input value of type signed integer, computes the opposite value, and returns the remainder as an signed integer. 0 is identity. This operator is provided for reversed subtracts : in order to subtract the input from a constant, simply perform a "neg,add(value)".
Returns a boolean FALSE if the input value of type signed integer is non-null, otherwise returns TRUE. Used in conjunction with and(), it can be used to report true/false for bit testing on input values (e.g. verify the absence of a flag).
Returns a boolean TRUE if the input value of type signed integer is odd otherwise returns FALSE. It is functionally equivalent to "and(1),bool".
Performs a bitwise "OR" between <value> and the input value of type signed integer, and returns the result as an signed integer. <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response) "req" : the variable is shared only during request processing "res" : the variable is shared only during response processing This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
This extracts the protocol buffers message field in raw mode of an input binary sample representation of a protocol buffer message with <field_number> as field number (dotted notation) if <field_type> is not present, or as an integer sample if this field is present (see also "ungrpc" below). The list of the authorized types is the following one: "int32", "int64", "uint32", "uint64", "sint32", "sint64", "bool", "enum" for the "varint" wire type 0 "fixed64", "sfixed64", "double" for the 64bit wire type 1, "fixed32", "sfixed32", "float" for the wire type 5. Note that "string" is considered as a length-delimited type, so it does not require any <field_type> argument to be extracted. More information may be found here about the protocol buffers message field types: https://developers.google.com/protocol-buffers/docs/encoding
Applies a regex-based substitution to the input string. It does the same operation as the well-known "sed" utility with "s/<regex>/<subst>/". By default it will replace in the input string the first occurrence of the largest part matching the regular expression <regex> with the substitution string <subst>. It is possible to replace all occurrences instead by adding the flag "g" in the third argument <flags>. It is also possible to make the regex case insensitive by adding the flag "i" in <flags>. Since <flags> is a string, it is made up from the concatenation of all desired flags. Thus if both "i" and "g" are desired, using "gi" or "ig" will have the same effect. It is important to note that due to the current limitations of the configuration parser, some characters such as closing parenthesis, closing square brackets or comma are not possible to use in the arguments. The first use of this converter is to replace certain characters or sequence of characters with other ones.
# de-duplicate "/" in header "x-path".
# input: x-path: /////a///b/c/xzxyz/
# output: x-path: /a/b/c/xzxyz/
http-request set-header x-path %[hdr(x-path),regsub(/+,/,g)]
Capture the string entry in the request slot <id> and returns the entry as is. If the slot doesn't exist, the capture fails silently.
Capture the string entry in the response slot <id> and returns the entry as is. If the slot doesn't exist, the capture fails silently.
Hashes a binary input sample into an unsigned 32-bit quantity using the SDBM hash function. Optionally, it is possible to apply a full avalanche hash function to the output if the optional <avalanche> argument equals 1. This converter uses the same functions as used by the various hash-based load balancing algorithms, so it will provide exactly the same results. It is mostly intended for debugging, but can be used as a stick-table entry to collect rough statistics. It must not be used for security purposes as a 32-bit hash is trivial to break. See also "crc32", "djb2", "wt6", "crc32c", and the "hash-type" directive. set-var(<var name>) Sets a variable with the input content and returns the content on the output as-is. The variable keeps the value and the associated input type. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response), "req" : the variable is shared only during request processing, "res" : the variable is shared only during response processing. This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Converts a binary input sample to a SHA-1 digest. The result is a binary sample with length of 20 bytes.
Converts a binary input sample to a digest in the SHA-2 family. The result is a binary sample with length of <bits>/8 bytes. Valid values for <bits> are 224, 256, 384, 512, each corresponding to SHA-<bits>. The default value is 256. Please note that this converter is only available when haproxy has been compiled with USE_OPENSSL.
Takes an input value of type string, either a server name or <backend>/<server> format and returns the number of queued sessions on that server. Can be used in places where we want to look up queued sessions from a dynamic name, like a cookie value (e.g. req.cook(SRVID),srv_queue) and then make a decision to break persistence or direct a request elsewhere.
Compares the contents of <var> with the input value of type string. Returns the result as a signed integer compatible with strcmp(3): 0 if both strings are identical. A value less than 0 if the left string is lexicographically smaller than the right string or if the left string is shorter. A value greater than 0 otherwise (right string greater than left string or the right string is shorter).
http-request set-var(txn.host) hdr(host)
# Check whether the client is attempting domain fronting.
acl ssl_sni_http_host_match ssl_fc_sni,strcmp(txn.host) eq 0
Subtracts <value> from the input value of type signed integer, and returns the result as an signed integer. Note: in order to subtract the input from a constant, simply perform a "neg,add(value)". <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response), "req" : the variable is shared only during request processing, "res" : the variable is shared only during response processing. This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the average client-to-server bytes rate associated with the input sample in the designated table, measured in amount of bytes over the period configured in the table. See also the sc_bytes_in_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the average server-to-client bytes rate associated with the input sample in the designated table, measured in amount of bytes over the period configured in the table. See also the sc_bytes_out_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the cumulative number of incoming connections associated with the input sample in the designated table. See also the sc_conn_cnt sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the current amount of concurrent tracked connections associated with the input sample in the designated table. See also the sc_conn_cur sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the average incoming connection rate associated with the input sample in the designated table. See also the sc_conn_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, boolean value zero is returned. Otherwise the converter returns the current value of the first general purpose tag associated with the input sample in the designated table. See also the sc_get_gpt0 sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the current value of the first general purpose counter associated with the input sample in the designated table. See also the sc_get_gpc0 sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the frequency which the gpc0 counter was incremented over the configured period in the table, associated with the input sample in the designated table. See also the sc_get_gpc0_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the current value of the second general purpose counter associated with the input sample in the designated table. See also the sc_get_gpc1 sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the frequency which the gpc1 counter was incremented over the configured period in the table, associated with the input sample in the designated table. See also the sc_get_gpc1_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the cumulative number of HTTP errors associated with the input sample in the designated table. See also the sc_http_err_cnt sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the average rate of HTTP errors associated with the input sample in the designated table, measured in amount of errors over the period configured in the table. See also the sc_http_err_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the cumulative number of HTTP requests associated with the input sample in the designated table. See also the sc_http_req_cnt sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the average rate of HTTP requests associated with the input sample in the designated table, measured in amount of requests over the period configured in the table. See also the sc_http_req_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the cumulative number of client- to-server data associated with the input sample in the designated table, measured in kilobytes. The test is currently performed on 32-bit integers, which limits values to 4 terabytes. See also the sc_kbytes_in sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the cumulative number of server- to-client data associated with the input sample in the designated table, measured in kilobytes. The test is currently performed on 32-bit integers, which limits values to 4 terabytes. See also the sc_kbytes_out sample fetch keyword.
Uses the string representation of the input sample to perform a look up in
the specified table. If the key is not found in the table, integer value zero
is returned. Otherwise the converter returns the server ID associated with
the input sample in the designated table. A server ID is associated to a
sample by a "stick" rule when a connection to a server succeeds. A server ID
zero means that no server is associated with this key.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the cumulative number of incoming sessions associated with the input sample in the designated table. Note that a session here refers to an incoming connection being accepted by the "tcp-request connection" rulesets. See also the sc_sess_cnt sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the average incoming session rate associated with the input sample in the designated table. Note that a session here refers to an incoming connection being accepted by the "tcp-request connection" rulesets. See also the sc_sess_rate sample fetch keyword.
Uses the string representation of the input sample to perform a look up in the specified table. If the key is not found in the table, integer value zero is returned. Otherwise the converter returns the current amount of concurrent connections tracking the same key as the input sample in the designated table. It differs from table_conn_cur in that it does not rely on any stored information but on the table's reference count (the "use" value which is returned by "show table" on the CLI). This may sometimes be more suited for layer7 tracking. It can be used to tell a server how many concurrent connections there are from a given address for example. See also the sc_trackers sample fetch keyword.
Convert a string sample to upper case. This can only be placed after a string sample fetch function or after a transformation keyword returning a string type. The result is of type string.
Takes an url-encoded string provided as input and returns the decoded version as output. The input and the output are of type string. If the <in_form> argument is set to a non-zero integer value, the input string is assumed to be part of a form or query string and the '+' character will be turned into a space (' '). Otherwise this will only happen after a question mark indicating a query string ('?').
This extracts the protocol buffers message field in raw mode of an input binary
sample representation of a gRPC message with <field_number> as field number
(dotted notation) if <field_type> is not present, or as an integer sample if this
field is present.
The list of the authorized types is the following one: "int32", "int64", "uint32",
"uint64", "sint32", "sint64", "bool", "enum" for the "varint" wire type 0
"fixed64", "sfixed64", "double" for the 64bit wire type 1, "fixed32", "sfixed32",
"float" for the wire type 5. Note that "string" is considered as a length-delimited
type, so it does not require any <field_type> argument to be extracted.
More information may be found here about the protocol buffers message field types:
https://developers.google.com/protocol-buffers/docs/encoding
// with such a protocol buffer .proto file content adapted from
// https://github.com/grpc/grpc/blob/master/examples/protos/route_guide.proto
message Point {
int32 latitude = 1;
int32 longitude = 2;
}
message PPoint {
Point point = 59;
}
message Rectangle {
// One corner of the rectangle.
PPoint lo = 48;
// The other corner of the rectangle.
PPoint hi = 49;
}
let's say a body request is made of a "Rectangle" object value (two PPoint
protocol buffers messages), the four protocol buffers fields could be
extracted with these "ungrpc" directives:
req.body,ungrpc(48.59.1,int32) # "latitude" of "lo" first PPoint
req.body,ungrpc(48.59.2,int32) # "longitude" of "lo" first PPoint
req.body,ungrpc(49.59.1,int32) # "latitude" of "hi" second PPoint
req.body,ungrpc(49.59.2,int32) # "longitude" of "hi" second PPoint
We could also extract the intermediary 48.59 field as a binary sample as follows:
req.body,ungrpc(48.59)
As a gRPC message is always made of a gRPC header followed by protocol buffers
messages, in the previous example the "latitude" of "lo" first PPoint
could be extracted with these equivalent directives:
req.body,ungrpc(48.59),protobuf(1,int32)
req.body,ungrpc(48),protobuf(59.1,int32)
req.body,ungrpc(48),protobuf(59),protobuf(1,int32)
Note that the first convert must be "ungrpc", the remaining ones must be
"protobuf" and only the last one may have or not a second argument to
interpret the previous binary sample.
unset-var(<var name>) Unsets a variable if the input content is defined. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response), "req" : the variable is shared only during request processing, "res" : the variable is shared only during response processing. This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Converts an integer supposed to contain a date since epoch to a string representing this date in UTC time using a format defined by the <format> string using strftime(3). The purpose is to allow any date format to be used in logs. An optional <offset> in seconds may be applied to the input date (positive or negative). See the strftime() man page for the format supported by your operating system. See also the ltime converter.
# Emit two colons, one with the UTC time and another with ip:port
# e.g. 20140710162350 127.0.0.1:57325
log-format %[date,utime(%Y%m%d%H%M%S)]\ %ci:%cp
Extracts the nth word counting from the beginning (positive index) or from the end (negative index) considering given delimiters from an input string. Indexes start at 1 or -1 and delimiters are a string formatted list of chars. Delimiters at the beginning or end of the input string are ignored. Optionally you can specify <count> of words to extract (default: 1). Value of 0 indicates extraction of all remaining words.
str(f1_f2_f3__f5),word(4,_) # f5
str(f1_f2_f3__f5),word(2,_,0) # f2_f3__f5
str(f1_f2_f3__f5),word(3,_,2) # f3__f5
str(f1_f2_f3__f5),word(-2,_,3) # f1_f2_f3
str(f1_f2_f3__f5),word(-3,_,0) # f1_f2
str(/f1/f2/f3/f4),word(1,/) # f1
Hashes a binary input sample into an unsigned 32-bit quantity using the WT6 hash function. Optionally, it is possible to apply a full avalanche hash function to the output if the optional <avalanche> argument equals 1. This converter uses the same functions as used by the various hash-based load balancing algorithms, so it will provide exactly the same results. It is mostly intended for debugging, but can be used as a stick-table entry to collect rough statistics. It must not be used for security purposes as a 32-bit hash is trivial to break. See also "crc32", "djb2", "sdbm", "crc32c", and the "hash-type" directive.
Performs a bitwise "XOR" (exclusive OR) between <value> and the input value of type signed integer, and returns the result as an signed integer. <value> can be a numeric value or a variable name. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response), "req" : the variable is shared only during request processing, "res" : the variable is shared only during response processing. This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
Hashes a binary input sample into an unsigned 32-bit quantity using the 32-bit variant of the XXHash hash function. This hash supports a seed which defaults to zero but a different value maybe passed as the <seed> argument. This hash is known to be very good and very fast so it can be used to hash URLs and/or URL parameters for use as stick-table keys to collect statistics with a low collision rate, though care must be taken as the algorithm is not considered as cryptographically secure.
Hashes a binary input sample into a signed 64-bit quantity using the 64-bit variant of the XXHash hash function. This hash supports a seed which defaults to zero but a different value maybe passed as the <seed> argument. This hash is known to be very good and very fast so it can be used to hash URLs and/or URL parameters for use as stick-table keys to collect statistics with a low collision rate, though care must be taken as the algorithm is not considered as cryptographically secure.
A first set of sample fetch methods applies to internal information which does not even relate to any client information. These ones are sometimes used with "monitor-fail" directives to report an internal status to external watchers. The sample fetch methods described in this section are usable anywhere.
Always returns the boolean "false" value. It may be used with ACLs as a temporary replacement for another one when adjusting configurations.
Always returns the boolean "true" value. It may be used with ACLs as a temporary replacement for another one when adjusting configurations.
Returns the total number of queued connections of the designated backend divided by the number of active servers. The current backend is used if no backend is specified. This is very similar to "queue" except that the size of the farm is considered, in order to give a more accurate measurement of the time it may take for a new connection to be processed. The main usage is with ACL to return a sorry page to new users when it becomes certain they will get a degraded service, or to pass to the backend servers in a header so that they decide to work in degraded mode or to disable some functions to speed up the processing a bit. Note that in the event there would not be any active server anymore, twice the number of queued connections would be considered as the measured value. This is a fair estimate, as we expect one server to get back soon anyway, but we still prefer to send new traffic to another backend if in better shape. See also the "queue", "be_conn", and "be_sess_rate" sample fetches.
Applies to the number of currently established connections on the backend, possibly including the connection being evaluated. If no backend name is specified, the current one is used. But it is also possible to check another backend. It can be used to use a specific farm when the nominal one is full. See also the "fe_conn", "queue", "be_conn_free", and "be_sess_rate" criteria.
Returns an integer value corresponding to the number of available connections across available servers in the backend. Queue slots are not included. Backup servers are also not included, unless all other servers are down. If no backend name is specified, the current one is used. But it is also possible to check another backend. It can be used to use a specific farm when the nominal one is full. See also the "be_conn", "connslots", and "srv_conn_free" criteria. OTHER CAVEATS AND NOTES: if any of the server maxconn, or maxqueue is 0 (meaning unlimited), then this fetch clearly does not make sense, in which case the value returned will be -1.
Returns an integer value corresponding to the sessions creation rate on the backend, in number of new sessions per second. This is used with ACLs to switch to an alternate backend when an expensive or fragile one reaches too high a session rate, or to limit abuse of service (e.g. prevent sucking of an online dictionary). It can also be useful to add this element to logs using a log-format directive.
# Redirect to an error page if the dictionary is requested too often
backend dynamic
mode http
acl being_scanned be_sess_rate gt 100
redirect location /denied.html if being_scanned
Returns a binary chain. The input is the hexadecimal representation of the string.
Returns a boolean value. <bool> can be 'true', 'false', '1' or '0'. 'false' and '0' are the same. 'true' and '1' are the same.
Returns an integer value corresponding to the number of connection slots still available in the backend, by totaling the maximum amount of connections on all servers and the maximum queue size. This is probably only used with ACLs. The basic idea here is to be able to measure the number of connection "slots" still available (connection + queue), so that anything beyond that (intended usage; see "use_backend" keyword) can be redirected to a different backend. 'connslots' = number of available server connection slots, + number of available server queue slots. Note that while "fe_conn" may be used, "connslots" comes in especially useful when you have a case of traffic going to one single ip, splitting into multiple backends (perhaps using ACLs to do name-based load balancing) and you want to be able to differentiate between different backends, and their available "connslots". Also, whereas "nbsrv" only measures servers that are actually *down*, this fetch is more fine-grained and looks into the number of available connection slots as well. See also "queue" and "avg_queue". OTHER CAVEATS AND NOTES: at this point in time, the code does not take care of dynamic connections. Also, if any of the server maxconn, or maxqueue is 0, then this fetch clearly does not make sense, in which case the value returned will be -1.
Returns the number of calls to the task processing the stream or current request since it was allocated. This number is reset for each new request on the same connections in case of HTTP keep-alive. This value should usually be low and stable (around 2 calls for a typically simple request) but may become high if some processing (compression, caching or analysis) is performed. This is purely for performance monitoring purposes.
Returns the average number of nanoseconds spent in each call to the task processing the stream or current request. This number is reset for each new request on the same connections in case of HTTP keep-alive. This value indicates the overall cost of processing the request or the connection for each call. There is no good nor bad value but the time spent in a call automatically causes latency for other processing (see lat_ns_avg below), and may affect other connection's apparent response time. Certain operations like compression, complex regex matching or heavy Lua operations may directly affect this value, and having it in the logs will make it easier to spot the faulty processing that needs to be fixed to recover decent performance. Note: this value is exactly cpu_ns_tot divided by cpu_calls.
Returns the total number of nanoseconds spent in each call to the task processing the stream or current request. This number is reset for each new request on the same connections in case of HTTP keep-alive. This value indicates the overall cost of processing the request or the connection for each call. There is no good nor bad value but the time spent in a call automatically causes latency for other processing (see lat_ns_avg below), induces CPU costs on the machine, and may affect other connection's apparent response time. Certain operations like compression, complex regex matching or heavy Lua operations may directly affect this value, and having it in the logs will make it easier to spot the faulty processing that needs to be fixed to recover decent performance. The value may be artificially high due to a high cpu_calls count, for example when processing many HTTP chunks, and for this reason it is often preferred to log cpu_ns_avg instead.
Returns the current date as the epoch (number of seconds since 01/01/1970). If an offset value is specified, then it is added to the current date before returning the value. This is particularly useful to compute relative dates, as both positive and negative offsets are allowed. It is useful combined with the http_date converter. <unit> is facultative, and can be set to "s" for seconds (default behavior), "ms" for milliseconds or "us" for microseconds. If unit is set, return value is an integer reflecting either seconds, milliseconds or microseconds since epoch, plus offset. It is useful when a time resolution of less than a second is needed.
# set an expires header to now+1 hour in every response
http-response set-header Expires %[date(3600),http_date]
# set an expires header to now+1 hour in every response, with
# millisecond granularity
http-response set-header Expires %[date(3600000,ms),http_date(0,ms)]
Return the microseconds part of the date (the "second" part is returned by date sample). This sample is coherent with the date sample as it is comes from the same timeval structure.
Parses a distcc message and returns the body associated to occurrence #<occ> of the token <token>. Occurrences start at 1, and when unspecified, any may match though in practice only the first one is checked for now. This can be used to extract file names or arguments in files built using distcc through haproxy. Please refer to distcc's protocol documentation for the complete list of supported tokens.
Parses a distcc message and returns the parameter associated to occurrence #<occ> of the token <token>. Occurrences start at 1, and when unspecified, any may match though in practice only the first one is checked for now. This can be used to extract certain information such as the protocol version, the file size or the argument in files built using distcc through haproxy. Another use case consists in waiting for the start of the preprocessed file contents before connecting to the server to avoid keeping idle connections. Please refer to distcc's protocol documentation for the complete list of supported tokens.
# wait up to 20s for the pre-processed file to be uploaded
tcp-request inspect-delay 20s
tcp-request content accept if { distcc_param(DOTI) -m found }
# send large files to the big farm
use_backend big_farm if { distcc_param(DOTI) gt 1000000 }
Returns a string containing the value of environment variable <name>. As a reminder, environment variables are per-process and are sampled when the process starts. This can be useful to pass some information to a next hop server, or with ACLs to take specific action when the process is started a certain way.
# Pass the Via header to next hop with the local hostname in it
http-request add-header Via 1.1\ %[env(HOSTNAME)]
# reject cookie-less requests when the STOP environment variable is set
http-request deny if !{ cook(SESSIONID) -m found } { env(STOP) -m found }
Returns the number of currently established connections on the frontend, possibly including the connection being evaluated. If no frontend name is specified, the current one is used. But it is also possible to check another frontend. It can be used to return a sorry page before hard-blocking, or to use a specific backend to drain new requests when the farm is considered full. This is mostly used with ACLs but can also be used to pass some statistics to servers in HTTP headers. See also the "dst_conn", "be_conn", "fe_sess_rate" fetches.
Returns an integer value corresponding to the number of HTTP requests per second sent to a frontend. This number can differ from "fe_sess_rate" in situations where client-side keep-alive is enabled.
Returns an integer value corresponding to the sessions creation rate on the frontend, in number of new sessions per second. This is used with ACLs to limit the incoming session rate to an acceptable range in order to prevent abuse of service at the earliest moment, for example when combined with other layer 4 ACLs in order to force the clients to wait a bit for the rate to go down below the limit. It can also be useful to add this element to logs using a log-format directive. See also the "rate-limit sessions" directive for use in frontends.
# This frontend limits incoming mails to 10/s with a max of 100
# concurrent connections. We accept any connection below 10/s, and
# force excess clients to wait for 100 ms. Since clients are limited to
# 100 max, there cannot be more than 10 incoming mails per second.
frontend mail
bind :25
mode tcp
maxconn 100
acl too_fast fe_sess_rate ge 10
tcp-request inspect-delay 100ms
tcp-request content accept if ! too_fast
tcp-request content accept if WAIT_END
Returns the system hostname.
Returns a signed integer.
Returns an ipv4.
Returns an ipv6.
Returns the average number of nanoseconds spent between the moment the task handling the stream is woken up and the moment it is effectively called. This number is reset for each new request on the same connections in case of HTTP keep-alive. This value indicates the overall latency inflicted to the current request by all other requests being processed in parallel, and is a direct indicator of perceived performance due to noisy neighbours. In order to keep the value low, it is possible to reduce the scheduler's run queue depth using "tune.runqueue-depth", to reduce the number of concurrent events processed at once using "tune.maxpollevents", to decrease the stream's nice value using the "nice" option on the "bind" lines or in the frontend, or to look for other heavy requests in logs (those exhibiting large values of "cpu_ns_avg"), whose processing needs to be adjusted or fixed. Compression of large buffers could be a culprit, like heavy regex or long lists of regex. Note: this value is exactly lat_ns_tot divided by cpu_calls.
Returns the total number of nanoseconds spent between the moment the task handling the stream is woken up and the moment it is effectively called. This number is reset for each new request on the same connections in case of HTTP keep-alive. This value indicates the overall latency inflicted to the current request by all other requests being processed in parallel, and is a direct indicator of perceived performance due to noisy neighbours. In order to keep the value low, it is possible to reduce the scheduler's run queue depth using "tune.runqueue-depth", to reduce the number of concurrent events processed at once using "tune.maxpollevents", to decrease the stream's nice value using the "nice" option on the "bind" lines or in the frontend, or to look for other heavy requests in logs (those exhibiting large values of "cpu_ns_avg"), whose processing needs to be adjusted or fixed. Compression of large buffers could be a culprit, like heavy regex or long lists of regex. Note: while it may intuitively seem that the total latency adds to a transfer time, it is almost never true because while a task waits for the CPU, network buffers continue to fill up and the next call will process more at once. The value may be artificially high due to a high cpu_calls count, for example when processing many HTTP chunks, and for this reason it is often preferred to log lat_ns_avg instead, which is a more relevant performance indicator.
Returns a method.
Returns an integer value corresponding to the number of processes that were
started (it equals the global "nbproc" setting). This is useful for logging
and debugging purposes.
Returns an integer value corresponding to the number of usable servers of either the current backend or the named backend. This is mostly used with ACLs but can also be useful when added to logs. This is normally used to switch to an alternate backend when the number of servers is too low to to handle some load. It is useful to report a failure when combined with "monitor fail".
Returns the priority class of the current session for http mode or connection for tcp mode. The value will be that set by the last call to "http-request set-priority-class" or "tcp-request content set-priority-class".
Returns the priority offset of the current session for http mode or connection for tcp mode. The value will be that set by the last call to "http-request set-priority-offset" or "tcp-request content set-priority-offset".
Returns an integer value corresponding to the position of the process calling the function, between 1 and global.nbproc. This is useful for logging and debugging purposes.
Returns the total number of queued connections of the designated backend, including all the connections in server queues. If no backend name is specified, the current one is used, but it is also possible to check another one. This is useful with ACLs or to pass statistics to backend servers. This can be used to take actions when queuing goes above a known level, generally indicating a surge of traffic or a massive slowdown on the servers. One possible action could be to reject new users but still accept old ones. See also the "avg_queue", "be_conn", and "be_sess_rate" fetches.
Returns a random integer value within a range of <range> possible values, starting at zero. If the range is not specified, it defaults to 2^32, which gives numbers between 0 and 4294967295. It can be useful to pass some values needed to take some routing decisions for example, or just for debugging purposes. This random must not be used for security purposes.
Returns a UUID following the RFC4122 standard. If the version is not specified, a UUID version 4 (fully random) is returned. Currently, only version 4 is supported.
Returns an integer value corresponding to the number of currently established connections on the designated server, possibly including the connection being evaluated. If <backend> is omitted, then the server is looked up in the current backend. It can be used to use a specific farm when one server is full, or to inform the server about our view of the number of active connections with it. See also the "fe_conn", "be_conn", "queue", and "srv_conn_free" fetch methods.
Returns an integer value corresponding to the number of available connections on the designated server, possibly including the connection being evaluated. The value does not include queue slots. If <backend> is omitted, then the server is looked up in the current backend. It can be used to use a specific farm when one server is full, or to inform the server about our view of the number of active connections with it. See also the "be_conn_free" and "srv_conn" fetch methods. OTHER CAVEATS AND NOTES: If the server maxconn is 0, then this fetch clearly does not make sense, in which case the value returned will be -1.
Returns true when the designated server is UP, and false when it is either DOWN or in maintenance mode. If <backend> is omitted, then the server is looked up in the current backend. It is mainly used to take action based on an external status reported via a health check (e.g. a geographical site's availability). Another possible use which is more of a hack consists in using dummy servers as boolean variables that can be enabled or disabled from the CLI, so that rules depending on those ACLs can be tweaked in realtime.
Returns an integer value corresponding to the number of connections currently pending in the designated server's queue. If <backend> is omitted, then the server is looked up in the current backend. It can sometimes be used together with the "use-server" directive to force to use a known faster server when it is not much loaded. See also the "srv_conn", "avg_queue" and "queue" sample fetch methods.
Returns an integer corresponding to the sessions creation rate on the designated server, in number of new sessions per second. If <backend> is omitted, then the server is looked up in the current backend. This is mostly used with ACLs but can make sense with logs too. This is used to switch to an alternate backend when an expensive or fragile one reaches too high a session rate, or to limit abuse of service (e.g. prevent latent requests from overloading servers).
# Redirect to a separate back
acl srv1_full srv_sess_rate(be1/srv1) gt 50
acl srv2_full srv_sess_rate(be1/srv2) gt 50
use_backend be2 if srv1_full or srv2_full
Returns TRUE if the process calling the function is currently stopping. This can be useful for logging, or for relaxing certain checks or helping close certain connections upon graceful shutdown.
Returns a string.
Returns the total number of available entries in the current proxy's stick-table or in the designated stick-table. See also table_cnt.
Returns the total number of entries currently in use in the current proxy's stick-table or in the designated stick-table. See also src_conn_cnt and table_avl for other entry counting methods.
Returns an integer value corresponding to the position of the thread calling the function, between 0 and (global.nbthread-1). This is useful for logging and debugging purposes.
Returns a variable with the stored type. If the variable is not set, the sample fetch fails. The name of the variable starts with an indication about its scope. The scopes allowed are: "proc" : the variable is shared with the whole process "sess" : the variable is shared with the whole session "txn" : the variable is shared with the transaction (request and response), "req" : the variable is shared only during request processing, "res" : the variable is shared only during response processing. This prefix is followed by a name. The separator is a '.'. The name may only contain characters 'a-z', 'A-Z', '0-9', '.' and '_'.
The layer 4 usually describes just the transport layer which in haproxy is closest to the connection, where no content is yet made available. The fetch methods described here are usable as low as the "tcp-request connection" rule sets unless they require some future information. Those generally include TCP/IP addresses and ports, as well as elements from stick-tables related to the incoming connection. For retrieving a value from a sticky counters, the counter number can be explicitly set as 0, 1, or 2 using the pre-defined "sc0_", "sc1_", or "sc2_" prefix. These three pre-defined prefixes can only be used if MAX_SESS_STKCTR value does not exceed 3, otherwise the counter number can be specified as the first integer argument when using the "sc_" prefix. Starting from "sc_0" to "sc_N" where N is (MAX_SESS_STKCTR-1). An optional table may be specified with the "sc*" form, in which case the currently tracked key will be looked up into this alternate table instead of the table currently being tracked.
Returns the backend connection's HTTP major version encoding, which may be 1 for HTTP/0.9 to HTTP/1.1 or 2 for HTTP/2. Note, this is based on the on-wire encoding and not the version present in the request header.
Returns an integer containing the current backend's id. It can be used in frontends with responses to check which backend processed the request.
Returns a string containing the current backend's name. It can be used in frontends with responses to check which backend processed the request.
This is the destination IPv4 address of the connection on the client side, which is the address the client connected to. It can be useful when running in transparent mode. It is of type IP and works on both IPv4 and IPv6 tables. On IPv6 tables, IPv4 address is mapped to its IPv6 equivalent, according to RFC 4291. When the incoming connection passed through address translation or redirection involving connection tracking, the original destination address before the redirection will be reported. On Linux systems, the source and destination may seldom appear reversed if the nf_conntrack_tcp_loose sysctl is set, because a late response may reopen a timed out connection and switch what is believed to be the source and the destination.
Returns an integer value corresponding to the number of currently established connections on the same socket including the one being evaluated. It is normally used with ACLs but can as well be used to pass the information to servers in an HTTP header or in logs. It can be used to either return a sorry page before hard-blocking, or to use a specific backend to drain new requests when the socket is considered saturated. This offers the ability to assign different limits to different listening ports or addresses. See also the "fe_conn" and "be_conn" fetches.
Returns true if the destination address of the incoming connection is local to the system, or false if the address doesn't exist on the system, meaning that it was intercepted in transparent mode. It can be useful to apply certain rules by default to forwarded traffic and other rules to the traffic targeting the real address of the machine. For example the stats page could be delivered only on this address, or SSH access could be locally redirected. Please note that the check involves a few system calls, so it's better to do it only once per connection.
Returns an integer value corresponding to the destination TCP port of the connection on the client side, which is the port the client connected to. This might be used when running in transparent mode, when assigning dynamic ports to some clients for a whole application session, to stick all users to a same server, or to pass the destination port information to a server using an HTTP header.
Reports the front connection's HTTP major version encoding, which may be 1 for HTTP/0.9 to HTTP/1.1 or 2 for HTTP/2. Note, this is based on the on-wire encoding and not on the version present in the request header.
Returns the authority TLV sent by the client in the PROXY protocol header, if any.
Returns true if the client initiated the connection with a PROXY protocol header.
Returns the Round Trip Time (RTT) measured by the kernel for the client connection. <unit> is facultative, by default the unit is milliseconds. <unit> can be set to "ms" for milliseconds or "us" for microseconds. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the Round Trip Time (RTT) variance measured by the kernel for the client connection. <unit> is facultative, by default the unit is milliseconds. <unit> can be set to "ms" for milliseconds or "us" for microseconds. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the unacked counter measured by the kernel for the client connection. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the sacked counter measured by the kernel for the client connection. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the retransmits counter measured by the kernel for the client connection. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the fack counter measured by the kernel for the client connection. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the lost counter measured by the kernel for the client connection. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns the reordering counter measured by the kernel for the client connection. If the server connection is not established, if the connection is not TCP or if the operating system does not support TCP_INFO, for example Linux kernels before 2.4, the sample fetch fails.
Returns a string containing the frontend's default backend name. It can be used in frontends to check which backend will handle requests by default.
Returns an integer containing the current frontend's id. It can be used in backends to check from which frontend it was called, or to stick all users coming via a same frontend to the same server.
Returns a string containing the current frontend's name. It can be used in backends to check from which frontend it was called, or to stick all users coming via a same frontend to the same server.
Returns the average client-to-server bytes rate from the currently tracked counters, measured in amount of bytes over the period configured in the table. See also src_bytes_in_rate.
Returns the average server-to-client bytes rate from the currently tracked counters, measured in amount of bytes over the period configured in the table. See also src_bytes_out_rate.
Clears the first General Purpose Counter associated to the currently tracked counters, and returns its previous value. Before the first invocation, the stored value is zero, so first invocation will always return zero. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified :
# block if 5 consecutive requests continue to come faster than 10 sess
# per second, and reset the counter as soon as the traffic slows down.
acl abuse sc0_http_req_rate gt 10
acl kill sc0_inc_gpc0 gt 5
acl save sc0_clr_gpc0 ge 0
tcp-request connection accept if !abuse save
tcp-request connection reject if abuse kill
Clears the second General Purpose Counter associated to the currently tracked counters, and returns its previous value. Before the first invocation, the stored value is zero, so first invocation will always return zero. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified.
Returns the cumulative number of incoming connections from currently tracked counters. See also src_conn_cnt.
Returns the current amount of concurrent connections tracking the same tracked counters. This number is automatically incremented when tracking begins and decremented when tracking stops. See also src_conn_cur.
Returns the average connection rate from the currently tracked counters, measured in amount of connections over the period configured in the table. See also src_conn_rate.
Returns the value of the first General Purpose Counter associated to the currently tracked counters. See also src_get_gpc0 and sc/sc0/sc1/sc2_inc_gpc0.
Returns the value of the second General Purpose Counter associated to the currently tracked counters. See also src_get_gpc1 and sc/sc0/sc1/sc2_inc_gpc1.
Returns the value of the first General Purpose Tag associated to the currently tracked counters. See also src_get_gpt0.
Returns the average increment rate of the first General Purpose Counter associated to the currently tracked counters. It reports the frequency which the gpc0 counter was incremented over the configured period. See also src_gpc0_rate, sc/sc0/sc1/sc2_get_gpc0, and sc/sc0/sc1/sc2_inc_gpc0. Note that the "gpc0_rate" counter must be stored in the stick-table for a value to be returned, as "gpc0" only holds the event count.
Returns the average increment rate of the second General Purpose Counter associated to the currently tracked counters. It reports the frequency which the gpc1 counter was incremented over the configured period. See also src_gpcA_rate, sc/sc0/sc1/sc2_get_gpc1, and sc/sc0/sc1/sc2_inc_gpc1. Note that the "gpc1_rate" counter must be stored in the stick-table for a value to be returned, as "gpc1" only holds the event count.
Returns the cumulative number of HTTP errors from the currently tracked counters. This includes the both request errors and 4xx error responses. See also src_http_err_cnt.
Returns the average rate of HTTP errors from the currently tracked counters, measured in amount of errors over the period configured in the table. This includes the both request errors and 4xx error responses. See also src_http_err_rate.
Returns the cumulative number of HTTP requests from the currently tracked counters. This includes every started request, valid or not. See also src_http_req_cnt.
Returns the average rate of HTTP requests from the currently tracked counters, measured in amount of requests over the period configured in the table. This includes every started request, valid or not. See also src_http_req_rate.
Increments the first General Purpose Counter associated to the currently tracked counters, and returns its new value. Before the first invocation, the stored value is zero, so first invocation will increase it to 1 and will return 1. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified :
acl abuse sc0_http_req_rate gt 10
acl kill sc0_inc_gpc0 gt 0
tcp-request connection reject if abuse kill
Increments the second General Purpose Counter associated to the currently tracked counters, and returns its new value. Before the first invocation, the stored value is zero, so first invocation will increase it to 1 and will return 1. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified.
Returns the total amount of client-to-server data from the currently tracked counters, measured in kilobytes. The test is currently performed on 32-bit integers, which limits values to 4 terabytes. See also src_kbytes_in.
Returns the total amount of server-to-client data from the currently tracked counters, measured in kilobytes. The test is currently performed on 32-bit integers, which limits values to 4 terabytes. See also src_kbytes_out.
Returns the cumulative number of incoming connections that were transformed into sessions, which means that they were accepted by a "tcp-request connection" rule, from the currently tracked counters. A backend may count more sessions than connections because each connection could result in many backend sessions if some HTTP keep-alive is performed over the connection with the client. See also src_sess_cnt.
Returns the average session rate from the currently tracked counters, measured in amount of sessions over the period configured in the table. A session is a connection that got past the early "tcp-request connection" rules. A backend may count more sessions than connections because each connection could result in many backend sessions if some HTTP keep-alive is performed over the connection with the client. See also src_sess_rate.
Returns true if the designated session counter is currently being tracked by the current session. This can be useful when deciding whether or not we want to set some values in a header passed to the server.
Returns the current amount of concurrent connections tracking the same tracked counters. This number is automatically incremented when tracking begins and decremented when tracking stops. It differs from sc0_conn_cur in that it does not rely on any stored information but on the table's reference count (the "use" value which is returned by "show table" on the CLI). This may sometimes be more suited for layer7 tracking. It can be used to tell a server how many concurrent connections there are from a given address for example.
Returns an integer containing the current listening socket's id. It is useful
in frontends involving many "bind" lines, or to stick all users coming via a
same socket to the same server.
Returns a string containing the current listening socket's name, as defined
with name on a "bind" line. It can serve the same purposes as so_id but with
strings instead of integers.
This is the source IPv4 address of the client of the session. It is of type IP and works on both IPv4 and IPv6 tables. On IPv6 tables, IPv4 addresses are mapped to their IPv6 equivalent, according to RFC 4291. Note that it is the TCP-level source address which is used, and not the address of a client behind a proxy. However if the "accept-proxy" or "accept-netscaler-cip" bind directive is used, it can be the address of a client behind another PROXY-protocol compatible component for all rule sets except "tcp-request connection" which sees the real address. When the incoming connection passed through address translation or redirection involving connection tracking, the original destination address before the redirection will be reported. On Linux systems, the source and destination may seldom appear reversed if the nf_conntrack_tcp_loose sysctl is set, because a late response may reopen a timed out connection and switch what is believed to be the source and the destination.
# add an HTTP header in requests with the originating address' country
http-request set-header X-Country %[src,map_ip(geoip.lst)]
Returns the average bytes rate from the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in amount of bytes over the period configured in the table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_bytes_in_rate.
Returns the average bytes rate to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in amount of bytes over the period configured in the table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_bytes_out_rate.
Clears the first General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, and returns its previous value. If the address is not found, an entry is created and 0 is returned. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified :
# block if 5 consecutive requests continue to come faster than 10 sess
# per second, and reset the counter as soon as the traffic slows down.
acl abuse src_http_req_rate gt 10
acl kill src_inc_gpc0 gt 5
acl save src_clr_gpc0 ge 0
tcp-request connection accept if !abuse save
tcp-request connection reject if abuse kill
Clears the second General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, and returns its previous value. If the address is not found, an entry is created and 0 is returned. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified.
Returns the cumulative number of connections initiated from the current incoming connection's source address in the current proxy's stick-table or in the designated stick-table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_conn_cnt.
Returns the current amount of concurrent connections initiated from the current incoming connection's source address in the current proxy's stick-table or in the designated stick-table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_conn_cur.
Returns the average connection rate from the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in amount of connections over the period configured in the table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_conn_rate.
Returns the value of the first General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_get_gpc0 and src_inc_gpc0.
Returns the value of the second General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_get_gpc1 and src_inc_gpc1.
Returns the value of the first General Purpose Tag associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_get_gpt0.
Returns the average increment rate of the first General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. It reports the frequency which the gpc0 counter was incremented over the configured period. See also sc/sc0/sc1/sc2_gpc0_rate, src_get_gpc0, and sc/sc0/sc1/sc2_inc_gpc0. Note that the "gpc0_rate" counter must be stored in the stick-table for a value to be returned, as "gpc0" only holds the event count.
Returns the average increment rate of the second General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. It reports the frequency which the gpc1 counter was incremented over the configured period. See also sc/sc0/sc1/sc2_gpc1_rate, src_get_gpc1, and sc/sc0/sc1/sc2_inc_gpc1. Note that the "gpc1_rate" counter must be stored in the stick-table for a value to be returned, as "gpc1" only holds the event count.
Returns the cumulative number of HTTP errors from the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. This includes the both request errors and 4xx error responses. See also sc/sc0/sc1/sc2_http_err_cnt. If the address is not found, zero is returned.
Returns the average rate of HTTP errors from the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in amount of errors over the period configured in the table. This includes the both request errors and 4xx error responses. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_http_err_rate.
Returns the cumulative number of HTTP requests from the incoming connection's source address in the current proxy's stick-table or in the designated stick- table. This includes every started request, valid or not. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_http_req_cnt.
Returns the average rate of HTTP requests from the incoming connection's source address in the current proxy's stick-table or in the designated stick- table, measured in amount of requests over the period configured in the table. This includes every started request, valid or not. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_http_req_rate.
Increments the first General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, and returns its new value. If the address is not found, an entry is created and 1 is returned. See also sc0/sc2/sc2_inc_gpc0. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified :
acl abuse src_http_req_rate gt 10
acl kill src_inc_gpc0 gt 0
tcp-request connection reject if abuse kill
Increments the second General Purpose Counter associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, and returns its new value. If the address is not found, an entry is created and 1 is returned. See also sc0/sc2/sc2_inc_gpc1. This is typically used as a second ACL in an expression in order to mark a connection when a first ACL was verified.
Returns true if the source address of the incoming connection is local to the system, or false if the address doesn't exist on the system, meaning that it comes from a remote machine. Note that UNIX addresses are considered local. It can be useful to apply certain access restrictions based on where the client comes from (e.g. require auth or https for remote machines). Please note that the check involves a few system calls, so it's better to do it only once per connection.
Returns the total amount of data received from the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in kilobytes. If the address is not found, zero is returned. The test is currently performed on 32-bit integers, which limits values to 4 terabytes. See also sc/sc0/sc1/sc2_kbytes_in.
Returns the total amount of data sent to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in kilobytes. If the address is not found, zero is returned. The test is currently performed on 32-bit integers, which limits values to 4 terabytes. See also sc/sc0/sc1/sc2_kbytes_out.
Returns an integer value corresponding to the TCP source port of the connection on the client side, which is the port the client connected from. Usage of this function is very limited as modern protocols do not care much about source ports nowadays.
Returns the cumulative number of connections initiated from the incoming connection's source IPv4 address in the current proxy's stick-table or in the designated stick-table, that were transformed into sessions, which means that they were accepted by "tcp-request" rules. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_sess_cnt.
Returns the average session rate from the incoming connection's source address in the current proxy's stick-table or in the designated stick-table, measured in amount of sessions over the period configured in the table. A session is a connection that went past the early "tcp-request" rules. If the address is not found, zero is returned. See also sc/sc0/sc1/sc2_sess_rate.
Creates or updates the entry associated to the incoming connection's source address in the current proxy's stick-table or in the designated stick-table. This table must be configured to store the "conn_cnt" data type, otherwise the match will be ignored. The current count is incremented by one, and the expiration timer refreshed. The updated count is returned, so this match can't return zero. This was used to reject service abusers based on their source address. Note: it is recommended to use the more complete "track-sc*" actions in "tcp-request" rules instead.
# This frontend limits incoming SSH connections to 3 per 10 second for
# each source address, and rejects excess connections until a 10 second
# silence is observed. At most 20 addresses are tracked.
listen ssh
bind :22
mode tcp
maxconn 100
stick-table type ip size 20 expire 10s store conn_cnt
tcp-request content reject if { src_updt_conn_cnt gt 3 }
server local 127.0.0.1:22
Returns an integer containing the server's id when processing the response. While it's almost only used with ACLs, it may be used for logging or debugging.
Returns a string containing the server's name when processing the response. While it's almost only used with ACLs, it may be used for logging or debugging.
The layer 5 usually describes just the session layer which in haproxy is closest to the session once all the connection handshakes are finished, but when no content is yet made available. The fetch methods described here are usable as low as the "tcp-request content" rule sets unless they require some future information. Those generally include the results of SSL negotiations.
Returns values for the properties requested as a string, where values are separated by the delimiter specified with "51degrees-property-separator". The device is identified using all the important HTTP headers from the request. The function can be passed up to five property names, and if a property name can't be found, the value "NoData" is returned.
# Here the header "X-51D-DeviceTypeMobileTablet" is added to the request
# containing the three properties requested using all relevant headers from
# the request.
frontend http-in
bind *:8081
default_backend servers
http-request set-header X-51D-DeviceTypeMobileTablet \
%[51d.all(DeviceType,IsMobile,IsTablet)]
Returns true when the back connection was made via an SSL/TLS transport
layer and is locally deciphered. This means the outgoing connection was made
other a server with the "ssl" option.
Returns the symmetric cipher key size supported in bits when the outgoing connection was made over an SSL/TLS transport layer.
This extracts the Application Layer Protocol Negotiation field from an outgoing connection made via a TLS transport layer. The result is a string containing the protocol name negotiated with the server. The SSL library must have been built with support for TLS extensions enabled (check haproxy -vv). Note that the TLS ALPN extension is not advertised unless the "alpn" keyword on the "server" line specifies a protocol list. Also, nothing forces the server to pick a protocol from this list, any other one may be requested. The TLS ALPN extension is meant to replace the TLS NPN extension. See also "ssl_bc_npn".
Returns the name of the used cipher when the outgoing connection was made over an SSL/TLS transport layer.
Returns the client random of the back connection when the incoming connection was made over an SSL/TLS transport layer. It is useful to to decrypt traffic sent using ephemeral ciphers. This requires OpenSSL >= 1.1.0, or BoringSSL.
Returns true when the back connection was made over an SSL/TLS transport layer and the newly created SSL session was resumed using a cached session or a TLS ticket.
This extracts the Next Protocol Negotiation field from an outgoing connection made via a TLS transport layer. The result is a string containing the protocol name negotiated with the server . The SSL library must have been built with support for TLS extensions enabled (check haproxy -vv). Note that the TLS NPN extension is not advertised unless the "npn" keyword on the "server" line specifies a protocol list. Also, nothing forces the server to pick a protocol from this list, any other one may be used. Please note that the TLS NPN extension was replaced with ALPN.
Returns the name of the used protocol when the outgoing connection was made over an SSL/TLS transport layer.
When the outgoing connection was made over an SSL/TLS transport layer, returns the TLS unique ID as defined in RFC5929 section 3. The unique id can be encoded to base64 using the converter: "ssl_bc_unique_id,base64".
Returns the server random of the back connection when the incoming connection was made over an SSL/TLS transport layer. It is useful to to decrypt traffic sent using ephemeral ciphers. This requires OpenSSL >= 1.1.0, or BoringSSL.
Returns the SSL ID of the back connection when the outgoing connection was made over an SSL/TLS transport layer. It is useful to log if we want to know if session was reused or not.
Returns the SSL session master key of the back connection when the outgoing connection was made over an SSL/TLS transport layer. It is useful to decrypt traffic sent using ephemeral ciphers. This requires OpenSSL >= 1.1.0, or BoringSSL.
Returns the symmetric cipher key size used in bits when the outgoing connection was made over an SSL/TLS transport layer.
When the incoming connection was made over an SSL/TLS transport layer, returns the ID of the first error detected during verification of the client certificate at depth > 0, or 0 if no error was encountered during this verification process. Please refer to your SSL library's documentation to find the exhaustive list of error codes.
When the incoming connection was made over an SSL/TLS transport layer, returns the depth in the CA chain of the first error detected during the verification of the client certificate. If no error is encountered, 0 is returned.
Returns the DER formatted certificate presented by the client when the incoming connection was made over an SSL/TLS transport layer. When used for an ACL, the value(s) to match against can be passed in hexadecimal form.
When the incoming connection was made over an SSL/TLS transport layer, returns the ID of the first error detected during verification at depth 0, or 0 if no error was encountered during this verification process. Please refer to your SSL library's documentation to find the exhaustive list of error codes.
When the incoming connection was made over an SSL/TLS transport layer, returns the full distinguished name of the issuer of the certificate presented by the client when no <entry> is specified, or the value of the first given entry found from the beginning of the DN. If a positive/negative occurrence number is specified as the optional second argument, it returns the value of the nth given entry value from the beginning/end of the DN. For instance, "ssl_c_i_dn(OU,2)" the second organization unit, and "ssl_c_i_dn(CN)" retrieves the common name.
Returns the name of the algorithm used to generate the key of the certificate presented by the client when the incoming connection was made over an SSL/TLS transport layer.
Returns the end date presented by the client as a formatted string YYMMDDhhmmss[Z] when the incoming connection was made over an SSL/TLS transport layer.
Returns the start date presented by the client as a formatted string YYMMDDhhmmss[Z] when the incoming connection was made over an SSL/TLS transport layer.
When the incoming connection was made over an SSL/TLS transport layer, returns the full distinguished name of the subject of the certificate presented by the client when no <entry> is specified, or the value of the first given entry found from the beginning of the DN. If a positive/negative occurrence number is specified as the optional second argument, it returns the value of the nth given entry value from the beginning/end of the DN. For instance, "ssl_c_s_dn(OU,2)" the second organization unit, and "ssl_c_s_dn(CN)" retrieves the common name.
Returns the serial of the certificate presented by the client when the incoming connection was made over an SSL/TLS transport layer. When used for an ACL, the value(s) to match against can be passed in hexadecimal form.
Returns the SHA-1 fingerprint of the certificate presented by the client when the incoming connection was made over an SSL/TLS transport layer. This can be used to stick a client to a server, or to pass this information to a server. Note that the output is binary, so if you want to pass that signature to the server, you need to encode it in hex or base64, such as in the example below:
http-request set-header X-SSL-Client-SHA1 %[ssl_c_sha1,hex]
Returns the name of the algorithm used to sign the certificate presented by the client when the incoming connection was made over an SSL/TLS transport layer.
Returns true if current SSL session uses a client certificate even if current connection uses SSL session resumption. See also "ssl_fc_has_crt".
Returns the verify result error ID when the incoming connection was made over an SSL/TLS transport layer, otherwise zero if no error is encountered. Please refer to your SSL library's documentation for an exhaustive list of error codes.
Returns the version of the certificate presented by the client when the incoming connection was made over an SSL/TLS transport layer.
Returns the DER formatted certificate presented by the frontend when the incoming connection was made over an SSL/TLS transport layer. When used for an ACL, the value(s) to match against can be passed in hexadecimal form.
When the incoming connection was made over an SSL/TLS transport layer, returns the full distinguished name of the issuer of the certificate presented by the frontend when no <entry> is specified, or the value of the first given entry found from the beginning of the DN. If a positive/negative occurrence number is specified as the optional second argument, it returns the value of the nth given entry value from the beginning/end of the DN. For instance, "ssl_f_i_dn(OU,2)" the second organization unit, and "ssl_f_i_dn(CN)" retrieves the common name.
Returns the name of the algorithm used to generate the key of the certificate presented by the frontend when the incoming connection was made over an SSL/TLS transport layer.
Returns the end date presented by the frontend as a formatted string YYMMDDhhmmss[Z] when the incoming connection was made over an SSL/TLS transport layer.
Returns the start date presented by the frontend as a formatted string YYMMDDhhmmss[Z] when the incoming connection was made over an SSL/TLS transport layer.
When the incoming connection was made over an SSL/TLS transport layer, returns the full distinguished name of the subject of the certificate presented by the frontend when no <entry> is specified, or the value of the first given entry found from the beginning of the DN. If a positive/negative occurrence number is specified as the optional second argument, it returns the value of the nth given entry value from the beginning/end of the DN. For instance, "ssl_f_s_dn(OU,2)" the second organization unit, and "ssl_f_s_dn(CN)" retrieves the common name.
Returns the serial of the certificate presented by the frontend when the incoming connection was made over an SSL/TLS transport layer. When used for an ACL, the value(s) to match against can be passed in hexadecimal form.
Returns the SHA-1 fingerprint of the certificate presented by the frontend when the incoming connection was made over an SSL/TLS transport layer. This can be used to know which certificate was chosen using SNI.
Returns the name of the algorithm used to sign the certificate presented by the frontend when the incoming connection was made over an SSL/TLS transport layer.
Returns the version of the certificate presented by the frontend when the incoming connection was made over an SSL/TLS transport layer.
Returns true when the front connection was made via an SSL/TLS transport layer and is locally deciphered. This means it has matched a socket declared with a "bind" line having the "ssl" option.
# This passes "X-Proto: https" to servers when client connects over SSL
listen http-https
bind :80
bind :443 ssl crt /etc/haproxy.pem
http-request add-header X-Proto https if { ssl_fc }
Returns the symmetric cipher key size supported in bits when the incoming connection was made over an SSL/TLS transport layer.
This extracts the Application Layer Protocol Negotiation field from an incoming connection made via a TLS transport layer and locally deciphered by haproxy. The result is a string containing the protocol name advertised by the client. The SSL library must have been built with support for TLS extensions enabled (check haproxy -vv). Note that the TLS ALPN extension is not advertised unless the "alpn" keyword on the "bind" line specifies a protocol list. Also, nothing forces the client to pick a protocol from this list, any other one may be requested. The TLS ALPN extension is meant to replace the TLS NPN extension. See also "ssl_fc_npn".
Returns the name of the used cipher when the incoming connection was made over an SSL/TLS transport layer.
Returns the binary form of the client hello cipher list. The maximum returned value length is according with the value of "tune.ssl.capture-cipherlist-size".
Returns the binary form of the client hello cipher list encoded as hexadecimal. The maximum returned value length is according with the value of "tune.ssl.capture-cipherlist-size".
Returns the decoded text form of the client hello cipher list. The maximum number of ciphers returned is according with the value of "tune.ssl.capture-cipherlist-size". Note that this sample-fetch is only available with OpenSSL >= 1.0.2. If the function is not enabled, this sample-fetch returns the hash like "ssl_fc_cipherlist_xxh".
Returns a xxh64 of the cipher list. This hash can be return only is the value "tune.ssl.capture-cipherlist-size" is set greater than 0, however the hash take in account all the data of the cipher list.
Returns the client random of the front connection when the incoming connection was made over an SSL/TLS transport layer. It is useful to to decrypt traffic sent using ephemeral ciphers. This requires OpenSSL >= 1.1.0, or BoringSSL.
Returns true if a client certificate is present in an incoming connection over SSL/TLS transport layer. Useful if 'verify' statement is set to 'optional'. Note: on SSL session resumption with Session ID or TLS ticket, client certificate is not present in the current connection but may be retrieved from the cache or the ticket. So prefer "ssl_c_used" if you want to check if current SSL session uses a client certificate.
Returns true if early data were sent, and the handshake didn't happen yet. As it has security implications, it is useful to be able to refuse those, or wait until the handshake happened.
This checks for the presence of a Server Name Indication TLS extension (SNI) in an incoming connection was made over an SSL/TLS transport layer. Returns true when the incoming connection presents a TLS SNI field. This requires that the SSL library is built with support for TLS extensions enabled (check haproxy -vv).
Returns true if the SSL/TLS session has been resumed through the use of SSL session cache or TLS tickets on an incoming connection over an SSL/TLS transport layer.
This extracts the Next Protocol Negotiation field from an incoming connection made via a TLS transport layer and locally deciphered by haproxy. The result is a string containing the protocol name advertised by the client. The SSL library must have been built with support for TLS extensions enabled (check haproxy -vv). Note that the TLS NPN extension is not advertised unless the "npn" keyword on the "bind" line specifies a protocol list. Also, nothing forces the client to pick a protocol from this list, any other one may be requested. Please note that the TLS NPN extension was replaced with ALPN.
Returns the name of the used protocol when the incoming connection was made over an SSL/TLS transport layer.
When the incoming connection was made over an SSL/TLS transport layer, returns the TLS unique ID as defined in RFC5929 section 3. The unique id can be encoded to base64 using the converter: "ssl_bc_unique_id,base64".
Returns the server random of the front connection when the incoming connection was made over an SSL/TLS transport layer. It is useful to to decrypt traffic sent using ephemeral ciphers. This requires OpenSSL >= 1.1.0, or BoringSSL.
Returns the SSL ID of the front connection when the incoming connection was made over an SSL/TLS transport layer. It is useful to stick a given client to a server. It is important to note that some browsers refresh their session ID every few minutes.
Returns the SSL session master key of the front connection when the incoming connection was made over an SSL/TLS transport layer. It is useful to decrypt traffic sent using ephemeral ciphers. This requires OpenSSL >= 1.1.0, or BoringSSL.
This extracts the Server Name Indication TLS extension (SNI) field from an incoming connection made via an SSL/TLS transport layer and locally deciphered by haproxy. The result (when present) typically is a string matching the HTTPS host name (253 chars or less). The SSL library must have been built with support for TLS extensions enabled (check haproxy -vv). This fetch is different from "req_ssl_sni" above in that it applies to the connection being deciphered by haproxy and not to SSL contents being blindly forwarded. See also "ssl_fc_sni_end" and "ssl_fc_sni_reg" below. This requires that the SSL library is built with support for TLS extensions enabled (check haproxy -vv). ACL derivatives : ssl_fc_sni_end : suffix match ssl_fc_sni_reg : regex match
Returns the symmetric cipher key size used in bits when the incoming connection was made over an SSL/TLS transport layer.
Fetching samples from buffer contents is a bit different from the previous sample fetches above because the sampled data are ephemeral. These data can only be used when they're available and will be lost when they're forwarded. For this reason, samples fetched from buffer contents during a request cannot be used in a response for example. Even while the data are being fetched, they can change. Sometimes it is necessary to set some delays or combine multiple sample fetch methods to ensure that the expected data are complete and usable, for example through TCP request content inspection. Please see the "tcp-request content" keyword for more detailed information on the subject.
This is an alias for "req.payload" when used in the context of a request (e.g. "stick on", "stick match"), and for "res.payload" when used in the context of a response such as in "stick store response".
This is an alias for "req.payload_lv" when used in the context of a request (e.g. "stick on", "stick match"), and for "res.payload_lv" when used in the context of a response such as in "stick store response".
Returns an integer value corresponding to the number of bytes present in the request buffer. This is mostly used in ACL. It is important to understand that this test does not return false as long as the buffer is changing. This means that a check with equality to zero will almost always immediately match at the beginning of the session, while a test for more data will wait for that data to come in and return false only when haproxy is certain that no more data will come in. This test was designed to be used with TCP request content inspection.
This extracts a binary block of <length> bytes and starting at byte <offset> in the request buffer. As a special case, if the <length> argument is zero, the the whole buffer from <offset> to the end is extracted. This can be used with ACLs in order to check for the presence of some content in a buffer at any location. ACL alternatives : payload(<offset>,<length>) : hex binary match
This extracts a binary block whose size is specified at <offset1> for <length> bytes, and which starts at <offset2> if specified or just after the length in the request buffer. The <offset2> parameter also supports relative offsets if prepended with a '+' or '-' sign. ACL alternatives : payload_lv(<offset1>,<length>[,<offset2>]) : hex binary match
please consult the example from the "stick store-response" keyword.
Returns true when data in the request buffer look like HTTP and correctly parses as such. It is the same parser as the common HTTP request parser which is used so there should be no surprises. The test does not match until the request is complete, failed or timed out. This test may be used to report the protocol in TCP logs, but the biggest use is to block TCP request analysis until a complete HTTP request is present in the buffer, for example to track a header.
# track request counts per "base" (concatenation of Host+URL)
tcp-request inspect-delay 10s
tcp-request content reject if !HTTP
tcp-request content track-sc0 base table req-rate
When the request buffer looks like the RDP protocol, extracts the RDP cookie <name>, or any cookie if unspecified. The parser only checks for the first cookie, as illustrated in the RDP protocol specification. The cookie name is case insensitive. Generally the "MSTS" cookie name will be used, as it can contain the user name of the client connecting to the server if properly configured on the client. The "MSTSHASH" cookie is often used as well for session stickiness to servers. This differs from "balance rdp-cookie" in that any balancing algorithm may be used and thus the distribution of clients to backend servers is not linked to a hash of the RDP cookie. It is envisaged that using a balancing algorithm such as "balance roundrobin" or "balance leastconn" will lead to a more even distribution of clients to backend servers than the hash used by "balance rdp-cookie". ACL derivatives : req_rdp_cookie([<name>]) : exact string match
listen tse-farm
bind 0.0.0.0:3389
# wait up to 5s for an RDP cookie in the request
tcp-request inspect-delay 5s
tcp-request content accept if RDP_COOKIE
# apply RDP cookie persistence
persist rdp-cookie
# Persist based on the mstshash cookie
# This is only useful makes sense if
# balance rdp-cookie is not used
stick-table type string size 204800
stick on req.rdp_cookie(mstshash)
server srv1 1.1.1.1:3389
server srv1 1.1.1.2:3389
Tries to parse the request buffer as RDP protocol, then returns an integer corresponding to the number of RDP cookies found. If an optional cookie name is passed, only cookies matching this name are considered. This is mostly used in ACL. ACL derivatives : req_rdp_cookie_cnt([<name>]) : integer match
Returns a string containing the values of the Application-Layer Protocol Negotiation (ALPN) TLS extension (RFC7301), sent by the client within the SSL ClientHello message. Note that this only applies to raw contents found in the request buffer and not to the contents deciphered via an SSL data layer, so this will not work with "bind" lines having the "ssl" option. This is useful in ACL to make a routing decision based upon the ALPN preferences of a TLS client, like in the example below. See also "ssl_fc_alpn".
# Wait for a client hello for at most 5 seconds
tcp-request inspect-delay 5s
tcp-request content accept if { req_ssl_hello_type 1 }
use_backend bk_acme if { req.ssl_alpn acme-tls/1 }
default_backend bk_default
Returns a boolean identifying if client sent the Supported Elliptic Curves Extension as defined in RFC4492, section 5.1. within the SSL ClientHello message. This can be used to present ECC compatible clients with EC certificate and to use RSA for all others, on the same IP address. Note that this only applies to raw contents found in the request buffer and not to contents deciphered via an SSL data layer, so this will not work with "bind" lines having the "ssl" option.
Returns an integer value containing the type of the SSL hello message found in the request buffer if the buffer contains data that parse as a complete SSL (v3 or superior) client hello message. Note that this only applies to raw contents found in the request buffer and not to contents deciphered via an SSL data layer, so this will not work with "bind" lines having the "ssl" option. This is mostly used in ACL to detect presence of an SSL hello message that is supposed to contain an SSL session ID usable for stickiness.
Returns a string containing the value of the Server Name TLS extension sent by a client in a TLS stream passing through the request buffer if the buffer contains data that parse as a complete SSL (v3 or superior) client hello message. Note that this only applies to raw contents found in the request buffer and not to contents deciphered via an SSL data layer, so this will not work with "bind" lines having the "ssl" option. SNI normally contains the name of the host the client tries to connect to (for recent browsers). SNI is useful for allowing or denying access to certain hosts when SSL/TLS is used by the client. This test was designed to be used with TCP request content inspection. If content switching is needed, it is recommended to first wait for a complete client hello (type 1), like in the example below. See also "ssl_fc_sni". ACL derivatives : req_ssl_sni : exact string match
# Wait for a client hello for at most 5 seconds
tcp-request inspect-delay 5s
tcp-request content accept if { req_ssl_hello_type 1 }
use_backend bk_allow if { req_ssl_sni -f allowed_sites }
default_backend bk_sorry_page
Returns 0 if the client didn't send a SessionTicket TLS Extension (RFC5077) Returns 1 if the client sent SessionTicket TLS Extension Returns 2 if the client also sent non-zero length TLS SessionTicket Note that this only applies to raw contents found in the request buffer and not to contents deciphered via an SSL data layer, so this will not work with "bind" lines having the "ssl" option. This can for example be used to detect whether the client sent a SessionTicket or not and stick it accordingly, if no SessionTicket then stick on SessionID or don't stick as there's no server side state is there when SessionTickets are in use.
Returns an integer value containing the version of the SSL/TLS protocol of a stream present in the request buffer. Both SSLv2 hello messages and SSLv3 messages are supported. TLSv1 is announced as SSL version 3.1. The value is composed of the major version multiplied by 65536, added to the minor version. Note that this only applies to raw contents found in the request buffer and not to contents deciphered via an SSL data layer, so this will not work with "bind" lines having the "ssl" option. The ACL version of the test matches against a decimal notation in the form MAJOR.MINOR (e.g. 3.1). This fetch is mostly used in ACL. ACL derivatives : req_ssl_ver : decimal match
Returns an integer value corresponding to the number of bytes present in the response buffer. This is mostly used in ACL. It is important to understand that this test does not return false as long as the buffer is changing. This means that a check with equality to zero will almost always immediately match at the beginning of the session, while a test for more data will wait for that data to come in and return false only when haproxy is certain that no more data will come in. This test was designed to be used with TCP response content inspection.
This extracts a binary block of <length> bytes and starting at byte <offset> in the response buffer. As a special case, if the <length> argument is zero, the the whole buffer from <offset> to the end is extracted. This can be used with ACLs in order to check for the presence of some content in a buffer at any location.
This extracts a binary block whose size is specified at <offset1> for <length> bytes, and which starts at <offset2> if specified or just after the length in the response buffer. The <offset2> parameter also supports relative offsets if prepended with a '+' or '-' sign.
please consult the example from the "stick store-response" keyword.
Returns an integer value containing the type of the SSL hello message found in the response buffer if the buffer contains data that parses as a complete SSL (v3 or superior) hello message. Note that this only applies to raw contents found in the response buffer and not to contents deciphered via an SSL data layer, so this will not work with "server" lines having the "ssl" option. This is mostly used in ACL to detect presence of an SSL hello message that is supposed to contain an SSL session ID usable for stickiness.
This fetch either returns true when the inspection period is over, or does not fetch. It is only used in ACLs, in conjunction with content analysis to avoid returning a wrong verdict early. It may also be used to delay some actions, such as a delayed reject for some special addresses. Since it either stops the rules evaluation or immediately returns true, it is recommended to use this acl as the last one in a rule. Please note that the default ACL "WAIT_END" is always usable without prior declaration. This test was designed to be used with TCP request content inspection.
# delay every incoming request by 2 seconds
tcp-request inspect-delay 2s
tcp-request content accept if WAIT_END
# don't immediately tell bad guys they are rejected
tcp-request inspect-delay 10s
acl goodguys src 10.0.0.0/24
acl badguys src 10.0.1.0/24
tcp-request content accept if goodguys
tcp-request content reject if badguys WAIT_END
tcp-request content reject
It is possible to fetch samples from HTTP contents, requests and responses. This application layer is also called layer 7. It is only possible to fetch the data in this section when a full HTTP request or response has been parsed from its respective request or response buffer. This is always the case with all HTTP specific rules and for sections running with "mode http". When using TCP content inspection, it may be necessary to support an inspection delay in order to let the request or response come in first. These fetches may require a bit more CPU resources than the layer 4 ones, but not much since the request and response are indexed.
This returns the concatenation of the first Host header and the path part of the request, which starts at the first slash and ends before the question mark. It can be useful in virtual hosted environments to detect URL abuses as well as to improve shared caches efficiency. Using this with a limited size stick table also allows one to collect statistics about most commonly requested objects by host/path. With ACLs it can allow simple content switching rules involving the host and the path at the same time, such as "www.example.com/favicon.ico". See also "path" and "uri". ACL derivatives : base : exact string match base_beg : prefix match base_dir : subdir match base_dom : domain match base_end : suffix match base_len : length match base_reg : regex match base_sub : substring match
This returns a 32-bit hash of the value returned by the "base" fetch method above. This is useful to track per-URL activity on high traffic sites without having to store all URLs. Instead a shorter hash is stored, saving a lot of memory. The output type is an unsigned integer. The hash function used is SDBM with full avalanche on the output. Technically, base32 is exactly equal to "base,sdbm(1)".
This returns the concatenation of the base32 fetch above and the src fetch below. The resulting type is of type binary, with a size of 8 or 20 bytes depending on the source address family. This can be used to track per-IP, per-URL counters.
This extracts the content of the header captured by the "capture request header", idx is the position of the capture keyword in the configuration.
This extracts the METHOD of an HTTP request. It can be used in both request and response. Unlike "method", it can be used in both request and response because it's allocated.
This extracts the request's URI, which starts at the first slash and ends before the first space in the request (without the host part). Unlike "path" and "url", it can be used in both request and response because it's allocated.
This extracts the request's HTTP version and returns either "HTTP/1.0" or "HTTP/1.1". Unlike "req.ver", it can be used in both request, response, and logs because it relies on a persistent flag.
This extracts the content of the header captured by the "capture response header", idx is the position of the capture keyword in the configuration. The first entry is an index of 0.
This extracts the response's HTTP version and returns either "HTTP/1.0" or "HTTP/1.1". Unlike "res.ver", it can be used in logs because it relies on a persistent flag.
This returns the HTTP request's available body as a block of data. It requires that the request body has been buffered made available using "option http-buffer-request". In case of chunked-encoded body, currently only the first chunk is analyzed.
This fetch assumes that the body of the POST request is url-encoded. The user can check if the "content-type" contains the value "application/x-www-form-urlencoded". This extracts the first occurrence of the parameter <name> in the body, which ends before '&'. The parameter name is case-sensitive. If no name is given, any parameter will match, and the first one will be returned. The result is a string corresponding to the value of the parameter <name> as presented in the request body (no URL decoding is performed). Note that the ACL version of this fetch iterates over multiple parameters and will iteratively report all parameters values if no name is given.
This returns the length of the HTTP request's available body in bytes. It may be lower than the advertised length if the body is larger than the buffer. It requires that the request body has been buffered made available using "option http-buffer-request".
This returns the advertised length of the HTTP request's body in bytes. It will represent the advertised Content-Length header, or the size of the first chunk in case of chunked encoding. In order to parse the chunks, it requires that the request body has been buffered made available using "option http-buffer-request".
This extracts the last occurrence of the cookie name <name> on a "Cookie" header line from the request, and returns its value as string. If no name is specified, the first cookie value is returned. When used with ACLs, all matching cookies are evaluated. Spaces around the name and the value are ignored as requested by the Cookie header specification (RFC6265). The cookie name is case-sensitive. Empty cookies are valid, so an empty cookie may very well return an empty value if it is present. Use the "found" match to detect presence. Use the res.cook() variant for response cookies sent by the server. ACL derivatives : cook([<name>]) : exact string match cook_beg([<name>]) : prefix match cook_dir([<name>]) : subdir match cook_dom([<name>]) : domain match cook_end([<name>]) : suffix match cook_len([<name>]) : length match cook_reg([<name>]) : regex match cook_sub([<name>]) : substring match
Returns an integer value representing the number of occurrences of the cookie <name> in the request, or all cookies if <name> is not specified.
This extracts the last occurrence of the cookie name <name> on a "Cookie" header line from the request, and converts its value to an integer which is returned. If no name is specified, the first cookie value is returned. When used in ACLs, all matching names are iterated over until a value matches.
This extracts the last occurrence of the cookie name <name> on a "Cookie" header line from the request, or a "Set-Cookie" header from the response, and returns its value as a string. A typical use is to get multiple clients sharing a same profile use the same server. This can be similar to what "appsession" did with the "request-learn" statement, but with support for multi-peer synchronization and state keeping across restarts. If no name is specified, the first cookie value is returned. This fetch should not be used anymore and should be replaced by req.cook() or res.cook() instead as it ambiguously uses the direction based on the context where it is used.
This is equivalent to req.hdr() when used on requests, and to res.hdr() when used on responses. Please refer to these respective fetches for more details. In case of doubt about the fetch direction, please use the explicit ones. Note that contrary to the hdr() sample fetch method, the hdr_* ACL keywords unambiguously apply to the request headers.
This extracts the last occurrence of header <name> in an HTTP request. When used from an ACL, all occurrences are iterated over until a match is found. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. It differs from req.hdr() in that any commas present in the value are returned and are not used as delimiters. This is sometimes useful with headers such as User-Agent.
Returns an integer value representing the number of occurrences of request header field name <name>, or the total number of header fields if <name> is not specified. Contrary to its req.hdr_cnt() cousin, this function returns the number of full line headers and does not stop on commas.
This extracts the last occurrence of header <name> in an HTTP request. When used from an ACL, all occurrences are iterated over until a match is found. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. A typical use is with the X-Forwarded-For header once converted to IP, associated with an IP stick-table. The function considers any comma as a delimiter for distinct values. If full-line headers are desired instead, use req.fhdr(). Please carefully check RFC7231 to know how certain headers are supposed to be parsed. Also, some of them are case insensitive (e.g. Connection). ACL derivatives : hdr([<name>[,<occ>]]) : exact string match hdr_beg([<name>[,<occ>]]) : prefix match hdr_dir([<name>[,<occ>]]) : subdir match hdr_dom([<name>[,<occ>]]) : domain match hdr_end([<name>[,<occ>]]) : suffix match hdr_len([<name>[,<occ>]]) : length match hdr_reg([<name>[,<occ>]]) : regex match hdr_sub([<name>[,<occ>]]) : substring match
Returns an integer value representing the number of occurrences of request header field name <name>, or the total number of header field values if <name> is not specified. It is important to remember that one header line may count as several headers if it has several values. The function considers any comma as a delimiter for distinct values. If full-line headers are desired instead, req.fhdr_cnt() should be used instead. With ACLs, it can be used to detect presence, absence or abuse of a specific header, as well as to block request smuggling attacks by rejecting requests which contain more than one of certain headers. See "req.hdr" for more information on header matching.
This extracts the last occurrence of header <name> in an HTTP request, converts it to an IPv4 or IPv6 address and returns this address. When used with ACLs, all occurrences are checked, and if <name> is omitted, every value of every header is checked. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. A typical use is with the X-Forwarded-For and X-Client-IP headers.
This extracts the last occurrence of header <name> in an HTTP request, and converts it to an integer value. When used with ACLs, all occurrences are checked, and if <name> is omitted, every value of every header is checked. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. A typical use is with the X-Forwarded-For header.
Returns the current request headers as string including the last empty line separating headers from the request body. The last empty line can be used to detect a truncated header block. This sample fetch is useful for some SPOE headers analyzers and for advanced logging.
Returns the current request headers contained in preparsed binary form. This is useful for offloading some processing with SPOE. Each string is described by a length followed by the number of bytes indicated in the length. The length is represented using the variable integer encoding detailed in the SPOE documentation. The end of the list is marked by a couple of empty header names and values (length of 0 for both). *(<str:header-name><str:header-value>)<empty string><empty string> int: refer to the SPOE documentation for the encoding str: <int:length><bytes>
Returns a boolean indicating whether the authentication data received from the client match a username & password stored in the specified userlist. This fetch function is not really useful outside of ACLs. Currently only http basic auth is supported.
Returns a string corresponding to the user name found in the authentication data received from the client if both the user name and password are valid according to the specified userlist. The main purpose is to use it in ACLs where it is then checked whether the user belongs to any group within a list. This fetch function is not really useful outside of ACLs. Currently only http basic auth is supported. ACL derivatives : http_auth_group(<userlist>) : group ... Returns true when the user extracted from the request and whose password is valid according to the specified userlist belongs to at least one of the groups.
Returns the user's password found in the authentication data received from the client, as supplied in the Authorization header. Not checks are performed by this sample fetch. Only Basic authentication is supported.
Returns the authentication method found in the authentication data received from the client, as supplied in the Authorization header. Not checks are performed by this sample fetch. Only Basic authentication is supported.
Returns the user name found in the authentication data received from the client, as supplied in the Authorization header. Not checks are performed by this sample fetch. Only Basic authentication is supported.
Returns true when the request being processed is the first one of the connection. This can be used to add or remove headers that may be missing from some requests when a request is not the first one, or to help grouping requests in the logs.
Returns an integer value corresponding to the method in the HTTP request. For example, "GET" equals 1 (check sources to establish the matching). Value 9 means "other method" and may be converted to a string extracted from the stream. This should not be used directly as a sample, this is only meant to be used from ACLs, which transparently convert methods from patterns to these integer + string values. Some predefined ACL already check for most common methods. ACL derivatives : method : case insensitive method match
# only accept GET and HEAD requests
acl valid_method method GET HEAD
http-request deny if ! valid_method
This extracts the request's URL path, which starts at the first slash and ends before the question mark (without the host part). A typical use is with prefetch-capable caches, and with portals which need to aggregate multiple information from databases and keep them in caches. Note that with outgoing caches, it would be wiser to use "url" instead. With ACLs, it's typically used to match exact file names (e.g. "/login.php"), or directory parts using the derivative forms. See also the "url" and "base" fetch methods. ACL derivatives : path : exact string match path_beg : prefix match path_dir : subdir match path_dom : domain match path_end : suffix match path_len : length match path_reg : regex match path_sub : substring match
This extracts the request's query string, which starts after the first question mark. If no question mark is present, this fetch returns nothing. If a question mark is present but nothing follows, it returns an empty string. This means it's possible to easily know whether a query string is present using the "found" matching method. This fetch is the complement of "path" which stops before the question mark.
This builds a string made from the concatenation of all header names as they appear in the request when the rule is evaluated. The default delimiter is the comma (',') but it may be overridden as an optional argument <delim>. In this case, only the first character of <delim> is considered.
Returns the version string from the HTTP request, for example "1.1". This can be useful for logs, but is mostly there for ACL. Some predefined ACL already check for versions 1.0 and 1.1. ACL derivatives : req_ver : exact string match
Returns the boolean "true" value if the response has been compressed by HAProxy, otherwise returns boolean "false". This may be used to add information in the logs.
Returns a string containing the name of the algorithm used if the response was compressed by HAProxy, for example : "deflate". This may be used to add some information in the logs.
This extracts the last occurrence of the cookie name <name> on a "Set-Cookie" header line from the response, and returns its value as string. If no name is specified, the first cookie value is returned. ACL derivatives : scook([<name>] : exact string match
Returns an integer value representing the number of occurrences of the cookie <name> in the response, or all cookies if <name> is not specified. This is mostly useful when combined with ACLs to detect suspicious responses.
This extracts the last occurrence of the cookie name <name> on a "Set-Cookie" header line from the response, and converts its value to an integer which is returned. If no name is specified, the first cookie value is returned.
This extracts the last occurrence of header <name> in an HTTP response, or of the last header if no <name> is specified. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. It differs from res.hdr() in that any commas present in the value are returned and are not used as delimiters. If this is not desired, the res.hdr() fetch should be used instead. This is sometimes useful with headers such as Date or Expires.
Returns an integer value representing the number of occurrences of response header field name <name>, or the total number of header fields if <name> is not specified. Contrary to its res.hdr_cnt() cousin, this function returns the number of full line headers and does not stop on commas. If this is not desired, the res.hdr_cnt() fetch should be used instead.
This extracts the last occurrence of header <name> in an HTTP response, or of the last header if no <name> is specified. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. This can be useful to learn some data into a stick-table. The function considers any comma as a delimiter for distinct values. If this is not desired, the res.fhdr() fetch should be used instead. ACL derivatives : shdr([<name>[,<occ>]]) : exact string match shdr_beg([<name>[,<occ>]]) : prefix match shdr_dir([<name>[,<occ>]]) : subdir match shdr_dom([<name>[,<occ>]]) : domain match shdr_end([<name>[,<occ>]]) : suffix match shdr_len([<name>[,<occ>]]) : length match shdr_reg([<name>[,<occ>]]) : regex match shdr_sub([<name>[,<occ>]]) : substring match
Returns an integer value representing the number of occurrences of response header field name <name>, or the total number of header fields if <name> is not specified. The function considers any comma as a delimiter for distinct values. If this is not desired, the res.fhdr_cnt() fetch should be used instead.
This extracts the last occurrence of header <name> in an HTTP response, convert it to an IPv4 or IPv6 address and returns this address. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. This can be useful to learn some data into a stick table.
This builds a string made from the concatenation of all header names as they appear in the response when the rule is evaluated. The default delimiter is the comma (',') but it may be overridden as an optional argument <delim>. In this case, only the first character of <delim> is considered.
This extracts the last occurrence of header <name> in an HTTP response, and converts it to an integer value. Optionally, a specific occurrence might be specified as a position number. Positive values indicate a position from the first occurrence, with 1 being the first one. Negative values indicate positions relative to the last one, with -1 being the last one. This can be useful to learn some data into a stick table.
Returns the version string from the HTTP response, for example "1.1". This can be useful for logs, but is mostly there for ACL. ACL derivatives : resp_ver : exact string match
This extracts the last occurrence of the cookie name <name> on a "Set-Cookie" header line from the response and uses the corresponding value to match. This can be comparable to what "appsession" did with default options, but with support for multi-peer synchronization and state keeping across restarts. This fetch function is deprecated and has been superseded by the "res.cook" fetch. This keyword will disappear soon.
Returns an integer containing the HTTP status code in the HTTP response, for example, 302. It is mostly used within ACLs and integer ranges, for example, to remove any Location header if the response is not a 3xx.
Returns the unique-id attached to the request. The directive "unique-id-format" must be set. If it is not set, the unique-id sample fetch fails. Note that the unique-id is usually used with HTTP requests, however this sample fetch can be used with other protocols. Obviously, if it is used with other protocols than HTTP, the unique-id-format directive must not contain HTTP parts. See: unique-id-format and unique-id-header
This extracts the request's URL as presented in the request. A typical use is with prefetch-capable caches, and with portals which need to aggregate multiple information from databases and keep them in caches. With ACLs, using "path" is preferred over using "url", because clients may send a full URL as is normally done with proxies. The only real use is to match "*" which does not match in "path", and for which there is already a predefined ACL. See also "path" and "base". ACL derivatives : url : exact string match url_beg : prefix match url_dir : subdir match url_dom : domain match url_end : suffix match url_len : length match url_reg : regex match url_sub : substring match
This extracts the IP address from the request's URL when the host part is presented as an IP address. Its use is very limited. For instance, a monitoring system might use this field as an alternative for the source IP in order to test what path a given source address would follow, or to force an entry in a table for a given source address. With ACLs it can be used to restrict access to certain systems through a proxy, for example when combined with option "http_proxy".
This extracts the port part from the request's URL. Note that if the port is not specified in the request, port 80 is assumed. With ACLs it can be used to restrict access to certain systems through a proxy, for example when combined with option "http_proxy".
This extracts the first occurrence of the parameter <name> in the query string, which begins after either '?' or <delim>, and which ends before '&', ';' or <delim>. The parameter name is case-sensitive. If no name is given, any parameter will match, and the first one will be returned. The result is a string corresponding to the value of the parameter <name> as presented in the request (no URL decoding is performed). This can be used for session stickiness based on a client ID, to extract an application cookie passed as a URL parameter, or in ACLs to apply some checks. Note that the ACL version of this fetch iterates over multiple parameters and will iteratively report all parameters values if no name is given ACL derivatives : urlp(<name>[,<delim>]) : exact string match urlp_beg(<name>[,<delim>]) : prefix match urlp_dir(<name>[,<delim>]) : subdir match urlp_dom(<name>[,<delim>]) : domain match urlp_end(<name>[,<delim>]) : suffix match urlp_len(<name>[,<delim>]) : length match urlp_reg(<name>[,<delim>]) : regex match urlp_sub(<name>[,<delim>]) : substring match
# match http://example.com/foo?PHPSESSIONID=some_id
stick on urlp(PHPSESSIONID)
# match http://example.com/foo;JSESSIONID=some_id
stick on urlp(JSESSIONID,;)
See "urlp" above. This one extracts the URL parameter <name> in the request and converts it to an integer value. This can be used for session stickiness based on a user ID for example, or with ACLs to match a page number or price.
This returns a 32-bit hash of the value obtained by concatenating the first Host header and the whole URL including parameters (not only the path part of the request, as in the "base32" fetch above). This is useful to track per-URL activity. A shorter hash is stored, saving a lot of memory. The output type is an unsigned integer.
This returns the concatenation of the "url32" fetch and the "src" fetch. The resulting type is of type binary, with a size of 8 or 20 bytes depending on the source address family. This can be used to track per-IP, per-URL counters.
Some predefined ACLs are hard-coded so that they do not have to be declared in every frontend which needs them. They all have their names in upper case in order to avoid confusion. Their equivalence is provided below.
ACL name | Equivalent to | Usage |
---|---|---|
FALSE | always_false | never match |
HTTP | req_proto_http | match if protocol is valid HTTP |
HTTP_1.0 | req_ver 1.0 | match HTTP version 1.0 |
HTTP_1.1 | req_ver 1.1 | match HTTP version 1.1 |
HTTP_CONTENT | hdr_val(content-length) gt 0 | match an existing content-length |
HTTP_URL_ABS | url_reg ^[^/:]*:// | match absolute URL with scheme |
HTTP_URL_SLASH | url_beg / | match URL beginning with "/" |
HTTP_URL_STAR | url * | match URL equal to "*" |
LOCALHOST | src 127.0.0.1/8 | match connection from local host |
METH_CONNECT | method CONNECT | match HTTP CONNECT method |
METH_DELETE | method DELETE | match HTTP DELETE method |
METH_GET | method GET HEAD | match HTTP GET or HEAD method |
METH_HEAD | method HEAD | match HTTP HEAD method |
METH_OPTIONS | method OPTIONS | match HTTP OPTIONS method |
METH_POST | method POST | match HTTP POST method |
METH_PUT | method PUT | match HTTP PUT method |
METH_TRACE | method TRACE | match HTTP TRACE method |
RDP_COOKIE | req_rdp_cookie_cnt gt 0 | match presence of an RDP cookie |
REQ_CONTENT | req_len gt 0 | match data in the request buffer |
TRUE | always_true | always match |
WAIT_END | wait_end | wait for end of content analysis |
One of HAProxy's strong points certainly lies is 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 information provided in logs include client ports, TCP/HTTP state timers, precise session state at termination and precise termination cause, information about decisions to direct traffic 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-instance system and internal errors (lack of resource, bugs, ...) - per-instance external troubles (servers up/down, max connections) - per-instance activity (client connections), either at the establishment or at the termination. - per-request control of log-level, e.g. http-request set-log-level silent if sensitive_request 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.
TCP and HTTP connections can be logged with information such as the date, time, source IP address, destination address, connection duration, response times, HTTP request, HTTP return code, number of bytes transmitted, conditions in which the session ended, and even exchanged cookies values. For example track a particular user's problems. All messages may be sent to up to two syslog servers. Check the "log" keyword in section 4.2 for more information about log facilities.
HAProxy supports 5 log formats. Several fields are common between these formats and will be detailed in the following sections. A few of them may vary slightly with the configuration, due to indicators specific to certain options. The supported formats are as follows : - the default format, which is very basic and very rarely used. It only provides very basic information about the incoming connection at the moment it is accepted : source IP:port, destination IP:port, and frontend-name. This mode will eventually disappear so it will not be described to great extents. - the TCP format, which is more advanced. This format is enabled when "option tcplog" is set on the frontend. HAProxy will then usually wait for the connection to terminate before logging. This format provides much richer information, such as timers, connection counts, queue size, etc... This format is recommended for pure TCP proxies. - the HTTP format, which is the most advanced for HTTP proxying. This format is enabled when "option httplog" is set on the frontend. It provides the same information as the TCP format with some HTTP-specific fields such as the request, the status code, and captures of headers and cookies. This format is recommended for HTTP proxies. - the CLF HTTP format, which is equivalent to the HTTP format, but with the fields arranged in the same order as the CLF format. In this mode, all timers, captures, flags, etc... appear one per field after the end of the common fields, in the same order they appear in the standard HTTP format. - the custom log format, allows you to make your own log line. Next sections will go deeper into details for each of these formats. Format specification will be performed on a "field" basis. Unless stated otherwise, a field is a portion of text delimited by any number of spaces. Since syslog servers are susceptible of inserting fields at the beginning of a line, it is always assumed that the first field is the one containing the process name and identifier. Note : Since log lines may be quite long, the log examples in sections below might be broken into multiple lines. The example log lines will be prefixed with 3 closing angle brackets ('>>>') and each time a log is broken into multiple lines, each non-final line will end with a backslash ('\') and the next line will start indented by two characters.
This format is used when no specific option is set. The log is emitted as soon as the connection is accepted. One should note that this currently is the only format which logs the request's destination IP and ports.
listen www
mode http
log global
server srv1 127.0.0.1:8000
>>> Feb 6 12:12:09 localhost \
haproxy[14385]: Connect from 10.0.1.2:33312 to 10.0.3.31:8012 \
(www/HTTP)
Field Format Extract from the example above 1 process_name '[' pid ']:' haproxy[14385]: 2 'Connect from' Connect from 3 source_ip ':' source_port 10.0.1.2:33312 4 'to' to 5 destination_ip ':' destination_port 10.0.3.31:8012 6 '(' frontend_name '/' mode ')' (www/HTTP) Detailed fields description : - "source_ip" is the IP address of the client which initiated the connection. - "source_port" is the TCP port of the client which initiated the connection. - "destination_ip" is the IP address the client connected to. - "destination_port" is the TCP port the client connected to. - "frontend_name" is the name of the frontend (or listener) which received and processed the connection. - "mode is the mode the frontend is operating (TCP or HTTP). In case of a UNIX socket, the source and destination addresses are marked as "unix:" and the ports reflect the internal ID of the socket which accepted the connection (the same ID as reported in the stats). It is advised not to use this deprecated format for newer installations as it will eventually disappear.
The TCP format is used when "option tcplog" is specified in the frontend, and is the recommended format for pure TCP proxies. It provides a lot of precious information for troubleshooting. Since this format includes timers and byte counts, the log is normally emitted at the end of the session. It can be emitted earlier if "option logasap" is specified, which makes sense in most environments with long sessions such as remote terminals. Sessions which match the "monitor" rules are never logged. It is also possible not to emit logs for sessions for which no data were exchanged between the client and the server, by specifying "option dontlognull" in the frontend. Successful connections will not be logged if "option dontlog-normal" is specified in the frontend. A few fields may slightly vary depending on some configuration options, those are marked with a star ('*') after the field name below.
frontend fnt
mode tcp
option tcplog
log global
default_backend bck
backend bck
server srv1 127.0.0.1:8000
>>> Feb 6 12:12:56 localhost \
haproxy[14387]: 10.0.1.2:33313 [06/Feb/2009:12:12:51.443] fnt \
bck/srv1 0/0/5007 212 -- 0/0/0/0/3 0/0
Field Format Extract from the example above 1 process_name '[' pid ']:' haproxy[14387]: 2 client_ip ':' client_port 10.0.1.2:33313 3 '[' accept_date ']' [06/Feb/2009:12:12:51.443] 4 frontend_name fnt 5 backend_name '/' server_name bck/srv1 6 Tw '/' Tc '/' Tt* 0/0/5007 7 bytes_read* 212 8 termination_state -- 9 actconn '/' feconn '/' beconn '/' srv_conn '/' retries* 0/0/0/0/3 10 srv_queue '/' backend_queue 0/0 Detailed fields description : - "client_ip" is the IP address of the client which initiated the TCP connection to haproxy. If the connection was accepted on a UNIX socket instead, the IP address would be replaced with the word "unix". Note that when the connection is accepted on a socket configured with "accept-proxy" and the PROXY protocol is correctly used, or with a "accept-netscaler-cip" and the NetScaler Client IP insertion protocol is correctly used, then the logs will reflect the forwarded connection's information. - "client_port" is the TCP port of the client which initiated the connection. If the connection was accepted on a UNIX socket instead, the port would be replaced with the ID of the accepting socket, which is also reported in the stats interface. - "accept_date" is the exact date when the connection was received by haproxy (which might be very slightly different from the date observed on the network if there was some queuing in the system's backlog). This is usually the same date which may appear in any upstream firewall's log. When used in HTTP mode, the accept_date field will be reset to the first moment the connection is ready to receive a new request (end of previous response for HTTP/1, immediately after previous request for HTTP/2). - "frontend_name" is the name of the frontend (or listener) which received and processed the connection. - "backend_name" is the name of the backend (or listener) which was selected to manage the connection to the server. This will be the same as the frontend if no switching rule has been applied, which is common for TCP applications. - "server_name" is the name of the last server to which the connection was sent, which might differ from the first one if there were connection errors and a redispatch occurred. Note that this server belongs to the backend which processed the request. If the connection was aborted before reaching a server, "<NOSRV>" is indicated instead of a server name. - "Tw" is the total time in milliseconds spent waiting in the various queues. It can be "-1" if the connection was aborted before reaching the queue. See "Timers" below for more details. - "Tc" is the total time in milliseconds spent waiting for the connection to establish to the final server, including retries. It can be "-1" if the connection was aborted before a connection could be established. See "Timers" below for more details. - "Tt" is the total time in milliseconds elapsed between the accept and the last close. It covers all possible processing. There is one exception, if "option logasap" was specified, then the time counting stops at the moment the log is emitted. In this case, a '+' sign is prepended before the value, indicating that the final one will be larger. See "Timers" below for more details. - "bytes_read" is the total number of bytes transmitted from the server to the client when the log is emitted. If "option logasap" is specified, the this value will be prefixed with a '+' sign indicating that the final one may be larger. Please note that this value is a 64-bit counter, so log analysis tools must be able to handle it without overflowing. - "termination_state" is the condition the session was in when the session ended. This indicates the session state, which side caused the end of session to happen, and for what reason (timeout, error, ...). The normal flags should be "--", indicating the session was closed by either end with no data remaining in buffers. See below "Session state at disconnection" for more details. - "actconn" is the total number of concurrent connections on the process when the session was logged. It is useful to detect when some per-process system limits have been reached. For instance, if actconn is close to 512 when multiple connection errors occur, chances are high that the system limits the process to use a maximum of 1024 file descriptors and that all of them are used. See section 3 "Global parameters" to find how to tune the system. - "feconn" is the total number of concurrent connections on the frontend when the session was logged. It is useful to estimate the amount of resource required to sustain high loads, and to detect when the frontend's "maxconn" has been reached. Most often when this value increases by huge jumps, it is because there is congestion on the backend servers, but sometimes it can be caused by a denial of service attack. - "beconn" is the total number of concurrent connections handled by the backend when the session was logged. It includes the total number of concurrent connections active on servers as well as the number of connections pending in queues. It is useful to estimate the amount of additional servers needed to support high loads for a given application. Most often when this value increases by huge jumps, it is because there is congestion on the backend servers, but sometimes it can be caused by a denial of service attack. - "srv_conn" is the total number of concurrent connections still active on the server when the session was logged. It can never exceed the server's configured "maxconn" parameter. If this value is very often close or equal to the server's "maxconn", it means that traffic regulation is involved a lot, meaning that either the server's maxconn value is too low, or that there aren't enough servers to process the load with an optimal response time. When only one of the server's "srv_conn" is high, it usually means that this server has some trouble causing the connections to take longer to be processed than on other servers. - "retries" is the number of connection retries experienced by this session when trying to connect to the server. It must normally be zero, unless a server is being stopped at the same moment the connection was attempted. Frequent retries generally indicate either a network problem between haproxy and the server, or a misconfigured system backlog on the server preventing new connections from being queued. This field may optionally be prefixed with a '+' sign, indicating that the session has experienced a redispatch after the maximal retry count has been reached on the initial server. In this case, the server name appearing in the log is the one the connection was redispatched to, and not the first one, though both may sometimes be the same in case of hashing for instance. So as a general rule of thumb, when a '+' is present in front of the retry count, this count should not be attributed to the logged server. - "srv_queue" is the total number of requests which were processed before this one in the server queue. It is zero when the request has not gone through the server queue. It makes it possible to estimate the approximate server's response time by dividing the time spent in queue by the number of requests in the queue. It is worth noting that if a session experiences a redispatch and passes through two server queues, their positions will be cumulative. A request should not pass through both the server queue and the backend queue unless a redispatch occurs. - "backend_queue" is the total number of requests which were processed before this one in the backend's global queue. It is zero when the request has not gone through the global queue. It makes it possible to estimate the average queue length, which easily translates into a number of missing servers when divided by a server's "maxconn" parameter. It is worth noting that if a session experiences a redispatch, it may pass twice in the backend's queue, and then both positions will be cumulative. A request should not pass through both the server queue and the backend queue unless a redispatch occurs.
The HTTP format is the most complete and the best suited for HTTP proxies. It is enabled by when "option httplog" is specified in the frontend. It provides the same level of information as the TCP format with additional features which are specific to the HTTP protocol. Just like the TCP format, the log is usually emitted at the end of the session, unless "option logasap" is specified, which generally only makes sense for download sites. A session which matches the "monitor" rules will never logged. It is also possible not to log sessions for which no data were sent by the client by specifying "option dontlognull" in the frontend. Successful connections will not be logged if "option dontlog-normal" is specified in the frontend. Most fields are shared with the TCP log, some being different. A few fields may slightly vary depending on some configuration options. Those ones are marked with a star ('*') after the field name below.
frontend http-in
mode http
option httplog
log global
default_backend bck
backend static
server srv1 127.0.0.1:8000
>>> Feb 6 12:14:14 localhost \
haproxy[14389]: 10.0.1.2:33317 [06/Feb/2009:12:14:14.655] http-in \
static/srv1 10/0/30/69/109 200 2750 - - ---- 1/1/1/1/0 0/0 {1wt.eu} \
{} "GET /index.html HTTP/1.1"
Field Format Extract from the example above 1 process_name '[' pid ']:' haproxy[14389]: 2 client_ip ':' client_port 10.0.1.2:33317 3 '[' request_date ']' [06/Feb/2009:12:14:14.655] 4 frontend_name http-in 5 backend_name '/' server_name static/srv1 6 TR '/' Tw '/' Tc '/' Tr '/' Ta* 10/0/30/69/109 7 status_code 200 8 bytes_read* 2750 9 captured_request_cookie - 10 captured_response_cookie - 11 termination_state ---- 12 actconn '/' feconn '/' beconn '/' srv_conn '/' retries* 1/1/1/1/0 13 srv_queue '/' backend_queue 0/0 14 '{' captured_request_headers* '}' {haproxy.1wt.eu} 15 '{' captured_response_headers* '}' {} 16 '"' http_request '"' "GET /index.html HTTP/1.1" Detailed fields description : - "client_ip" is the IP address of the client which initiated the TCP connection to haproxy. If the connection was accepted on a UNIX socket instead, the IP address would be replaced with the word "unix". Note that when the connection is accepted on a socket configured with "accept-proxy" and the PROXY protocol is correctly used, or with a "accept-netscaler-cip" and the NetScaler Client IP insertion protocol is correctly used, then the logs will reflect the forwarded connection's information. - "client_port" is the TCP port of the client which initiated the connection. If the connection was accepted on a UNIX socket instead, the port would be replaced with the ID of the accepting socket, which is also reported in the stats interface. - "request_date" is the exact date when the first byte of the HTTP request was received by haproxy (log field %tr). - "frontend_name" is the name of the frontend (or listener) which received and processed the connection. - "backend_name" is the name of the backend (or listener) which was selected to manage the connection to the server. This will be the same as the frontend if no switching rule has been applied. - "server_name" is the name of the last server to which the connection was sent, which might differ from the first one if there were connection errors and a redispatch occurred. Note that this server belongs to the backend which processed the request. If the request was aborted before reaching a server, "<NOSRV>" is indicated instead of a server name. If the request was intercepted by the stats subsystem, "<STATS>" is indicated instead. - "TR" is the total time in milliseconds spent waiting for a full HTTP request from the client (not counting body) after the first byte was received. It can be "-1" if the connection was aborted before a complete request could be received or a bad request was received. It should always be very small because a request generally fits in one single packet. Large times here generally indicate network issues between the client and haproxy or requests being typed by hand. See section 8.4 "Timing Events" for more details. - "Tw" is the total time in milliseconds spent waiting in the various queues. It can be "-1" if the connection was aborted before reaching the queue. See section 8.4 "Timing Events" for more details. - "Tc" is the total time in milliseconds spent waiting for the connection to establish to the final server, including retries. It can be "-1" if the request was aborted before a connection could be established. See section 8.4 "Timing Events" for more details. - "Tr" is the total time in milliseconds spent waiting for the server to send a full HTTP response, not counting data. It can be "-1" if the request was aborted before a complete response could be received. It generally matches the server's processing time for the request, though it may be altered by the amount of data sent by the client to the server. Large times here on "GET" requests generally indicate an overloaded server. See section 8.4 "Timing Events" for more details. - "Ta" is the time the request remained active in haproxy, which is the total time in milliseconds elapsed between the first byte of the request was received and the last byte of response was sent. It covers all possible processing except the handshake (see Th) and idle time (see Ti). There is one exception, if "option logasap" was specified, then the time counting stops at the moment the log is emitted. In this case, a '+' sign is prepended before the value, indicating that the final one will be larger. See section 8.4 "Timing Events" for more details. - "status_code" is the HTTP status code returned to the client. This status is generally set by the server, but it might also be set by haproxy when the server cannot be reached or when its response is blocked by haproxy. - "bytes_read" is the total number of bytes transmitted to the client when the log is emitted. This does include HTTP headers. If "option logasap" is specified, this value will be prefixed with a '+' sign indicating that the final one may be larger. Please note that this value is a 64-bit counter, so log analysis tools must be able to handle it without overflowing. - "captured_request_cookie" is an optional "name=value" entry indicating that the client had this cookie in the request. The cookie name and its maximum length are defined by the "capture cookie" statement in the frontend configuration. The field is a single dash ('-') when the option is not set. Only one cookie may be captured, it is generally used to track session ID exchanges between a client and a server to detect session crossing between clients due to application bugs. For more details, please consult the section "Capturing HTTP headers and cookies" below. - "captured_response_cookie" is an optional "name=value" entry indicating that the server has returned a cookie with its response. The cookie name and its maximum length are defined by the "capture cookie" statement in the frontend configuration. The field is a single dash ('-') when the option is not set. Only one cookie may be captured, it is generally used to track session ID exchanges between a client and a server to detect session crossing between clients due to application bugs. For more details, please consult the section "Capturing HTTP headers and cookies" below. - "termination_state" is the condition the session was in when the session ended. This indicates the session state, which side caused the end of session to happen, for what reason (timeout, error, ...), just like in TCP logs, and information about persistence operations on cookies in the last two characters. The normal flags should begin with "--", indicating the session was closed by either end with no data remaining in buffers. See below "Session state at disconnection" for more details. - "actconn" is the total number of concurrent connections on the process when the session was logged. It is useful to detect when some per-process system limits have been reached. For instance, if actconn is close to 512 or 1024 when multiple connection errors occur, chances are high that the system limits the process to use a maximum of 1024 file descriptors and that all of them are used. See section 3 "Global parameters" to find how to tune the system. - "feconn" is the total number of concurrent connections on the frontend when the session was logged. It is useful to estimate the amount of resource required to sustain high loads, and to detect when the frontend's "maxconn" has been reached. Most often when this value increases by huge jumps, it is because there is congestion on the backend servers, but sometimes it can be caused by a denial of service attack. - "beconn" is the total number of concurrent connections handled by the backend when the session was logged. It includes the total number of concurrent connections active on servers as well as the number of connections pending in queues. It is useful to estimate the amount of additional servers needed to support high loads for a given application. Most often when this value increases by huge jumps, it is because there is congestion on the backend servers, but sometimes it can be caused by a denial of service attack. - "srv_conn" is the total number of concurrent connections still active on the server when the session was logged. It can never exceed the server's configured "maxconn" parameter. If this value is very often close or equal to the server's "maxconn", it means that traffic regulation is involved a lot, meaning that either the server's maxconn value is too low, or that there aren't enough servers to process the load with an optimal response time. When only one of the server's "srv_conn" is high, it usually means that this server has some trouble causing the requests to take longer to be processed than on other servers. - "retries" is the number of connection retries experienced by this session when trying to connect to the server. It must normally be zero, unless a server is being stopped at the same moment the connection was attempted. Frequent retries generally indicate either a network problem between haproxy and the server, or a misconfigured system backlog on the server preventing new connections from being queued. This field may optionally be prefixed with a '+' sign, indicating that the session has experienced a redispatch after the maximal retry count has been reached on the initial server. In this case, the server name appearing in the log is the one the connection was redispatched to, and not the first one, though both may sometimes be the same in case of hashing for instance. So as a general rule of thumb, when a '+' is present in front of the retry count, this count should not be attributed to the logged server. - "srv_queue" is the total number of requests which were processed before this one in the server queue. It is zero when the request has not gone through the server queue. It makes it possible to estimate the approximate server's response time by dividing the time spent in queue by the number of requests in the queue. It is worth noting that if a session experiences a redispatch and passes through two server queues, their positions will be cumulative. A request should not pass through both the server queue and the backend queue unless a redispatch occurs. - "backend_queue" is the total number of requests which were processed before this one in the backend's global queue. It is zero when the request has not gone through the global queue. It makes it possible to estimate the average queue length, which easily translates into a number of missing servers when divided by a server's "maxconn" parameter. It is worth noting that if a session experiences a redispatch, it may pass twice in the backend's queue, and then both positions will be cumulative. A request should not pass through both the server queue and the backend queue unless a redispatch occurs. - "captured_request_headers" is a list of headers captured in the request due to the presence of the "capture request header" statement in the frontend. Multiple headers can be captured, they will be delimited by a vertical bar ('|'). When no capture is enabled, the braces do not appear, causing a shift of remaining fields. It is important to note that this field may contain spaces, and that using it requires a smarter log parser than when it's not used. Please consult the section "Capturing HTTP headers and cookies" below for more details. - "captured_response_headers" is a list of headers captured in the response due to the presence of the "capture response header" statement in the frontend. Multiple headers can be captured, they will be delimited by a vertical bar ('|'). When no capture is enabled, the braces do not appear, causing a shift of remaining fields. It is important to note that this field may contain spaces, and that using it requires a smarter log parser than when it's not used. Please consult the section "Capturing HTTP headers and cookies" below for more details. - "http_request" is the complete HTTP request line, including the method, request and HTTP version string. Non-printable characters are encoded (see below the section "Non-printable characters"). This is always the last field, and it is always delimited by quotes and is the only one which can contain quotes. If new fields are added to the log format, they will be added before this field. This field might be truncated if the request is huge and does not fit in the standard syslog buffer (1024 characters). This is the reason why this field must always remain the last one.
The directive log-format allows you to customize the logs in http mode and tcp mode. It takes a string as argument. HAProxy understands some log format variables. % precedes log format variables. Variables can take arguments using braces ('{}'), and multiple arguments are separated by commas within the braces. Flags may be added or removed by prefixing them with a '+' or '-' sign. Special variable "%o" may be used to propagate its flags to all other variables on the same format string. This is particularly handy with quoted ("Q") and escaped ("E") string formats. If a variable is named between square brackets ('[' .. ']') then it is used as a sample expression rule (see section 7.3). This it useful to add some less common information such as the client's SSL certificate's DN, or to log the key that would be used to store an entry into a stick table. Note: spaces must be escaped. A space character is considered as a separator. In order to emit a verbatim '%', it must be preceded by another '%' resulting in '%%'. HAProxy will automatically merge consecutive separators. Note: when using the RFC5424 syslog message format, the characters '"', '\' and ']' inside PARAM-VALUE should be escaped with '\' as prefix (see https://tools.ietf.org/html/rfc5424#section-6.3.3 for more details). In such cases, the use of the flag "E" should be considered. Flags are : * Q: quote a string * X: hexadecimal representation (IPs, Ports, %Ts, %rt, %pid) * E: escape characters '"', '\' and ']' in a string with '\' as prefix (intended purpose is for the RFC5424 structured-data log formats)
log-format %T\ %t\ Some\ Text
log-format %{+Q}o\ %t\ %s\ %{-Q}r
log-format-sd %{+Q,+E}o\ [exampleSDID@1234\ header=%[capture.req.hdr(0)]]
At the moment, the default HTTP format is defined this way : log-format "%ci:%cp [%tr] %ft %b/%s %TR/%Tw/%Tc/%Tr/%Ta %ST %B %CC \ %CS %tsc %ac/%fc/%bc/%sc/%rc %sq/%bq %hr %hs %{+Q}r" the default CLF format is defined this way : log-format "%{+Q}o %{-Q}ci - - [%trg] %r %ST %B \"\" \"\" %cp \ %ms %ft %b %s %TR %Tw %Tc %Tr %Ta %tsc %ac %fc \ %bc %sc %rc %sq %bq %CC %CS %hrl %hsl" and the default TCP format is defined this way : log-format "%ci:%cp [%t] %ft %b/%s %Tw/%Tc/%Tt %B %ts \ %ac/%fc/%bc/%sc/%rc %sq/%bq" Please refer to the table below for currently defined variables : +---+------+-----------------------------------------------+-------------+ | R | var | field name (8.2.2 and 8.2.3 for description) | type | +---+------+-----------------------------------------------+-------------+ | | %o | special variable, apply flags on all next var | | +---+------+-----------------------------------------------+-------------+ | | %B | bytes_read (from server to client) | numeric | | H | %CC | captured_request_cookie | string | | H | %CS | captured_response_cookie | string | | | %H | hostname | string | | H | %HM | HTTP method (ex: POST) | string | | H | %HP | HTTP request URI without query string | string | | H | %HQ | HTTP request URI query string (ex: ?bar=baz) | string | | H | %HU | HTTP request URI (ex: /foo?bar=baz) | string | | H | %HV | HTTP version (ex: HTTP/1.0) | string | | | %ID | unique-id | string | | | %ST | status_code | numeric | | | %T | gmt_date_time | date | | | %Ta | Active time of the request (from TR to end) | numeric | | | %Tc | Tc | numeric | | | %Td | Td = Tt - (Tq + Tw + Tc + Tr) | numeric | | | %Tl | local_date_time | date | | | %Th | connection handshake time (SSL, PROXY proto) | numeric | | H | %Ti | idle time before the HTTP request | numeric | | H | %Tq | Th + Ti + TR | numeric | | H | %TR | time to receive the full request from 1st byte| numeric | | H | %Tr | Tr (response time) | numeric | | | %Ts | timestamp | numeric | | | %Tt | Tt | numeric | | | %Tw | Tw | numeric | | | %U | bytes_uploaded (from client to server) | numeric | | | %ac | actconn | numeric | | | %b | backend_name | string | | | %bc | beconn (backend concurrent connections) | numeric | | | %bi | backend_source_ip (connecting address) | IP | | | %bp | backend_source_port (connecting address) | numeric | | | %bq | backend_queue | numeric | | | %ci | client_ip (accepted address) | IP | | | %cp | client_port (accepted address) | numeric | | | %f | frontend_name | string | | | %fc | feconn (frontend concurrent connections) | numeric | | | %fi | frontend_ip (accepting address) | IP | | | %fp | frontend_port (accepting address) | numeric | | | %ft | frontend_name_transport ('~' suffix for SSL) | string | | | %lc | frontend_log_counter | numeric | | | %hr | captured_request_headers default style | string | | | %hrl | captured_request_headers CLF style | string list | | | %hs | captured_response_headers default style | string | | | %hsl | captured_response_headers CLF style | string list | | | %ms | accept date milliseconds (left-padded with 0) | numeric | | | %pid | PID | numeric | | H | %r | http_request | string | | | %rc | retries | numeric | | | %rt | request_counter (HTTP req or TCP session) | numeric | | | %s | server_name | string | | | %sc | srv_conn (server concurrent connections) | numeric | | | %si | server_IP (target address) | IP | | | %sp | server_port (target address) | numeric | | | %sq | srv_queue | numeric | | S | %sslc| ssl_ciphers (ex: AES-SHA) | string | | S | %sslv| ssl_version (ex: TLSv1) | string | | | %t | date_time (with millisecond resolution) | date | | H | %tr | date_time of HTTP request | date | | H | %trg | gmt_date_time of start of HTTP request | date | | H | %trl | local_date_time of start of HTTP request | date | | | %ts | termination_state | string | | H | %tsc | termination_state with cookie status | string | +---+------+-----------------------------------------------+-------------+ R = Restrictions : H = mode http only ; S = SSL only
When an incoming connection fails due to an SSL handshake or an invalid PROXY protocol header, haproxy will log the event using a shorter, fixed line format. By default, logs are emitted at the LOG_INFO level, unless the option "log-separate-errors" is set in the backend, in which case the LOG_ERR level will be used. Connections on which no data are exchanged (e.g. probes) are not logged if the "dontlognull" option is set. The format looks like this : >>> Dec 3 18:27:14 localhost \ haproxy[6103]: 127.0.0.1:56059 [03/Dec/2012:17:35:10.380] frt/f1: \ Connection error during SSL handshake Field Format Extract from the example above 1 process_name '[' pid ']:' haproxy[6103]: 2 client_ip ':' client_port 127.0.0.1:56059 3 '[' accept_date ']' [03/Dec/2012:17:35:10.380] 4 frontend_name "/" bind_name ":" frt/f1: 5 message Connection error during SSL handshake These fields just provide minimal information to help debugging connection failures.
Some advanced logging options are often looked for but are not easy to find out just by looking at the various options. Here is an entry point for the few options which can enable better logging. Please refer to the keywords reference for more information about their usage.
It is quite common to have some monitoring tools perform health checks on haproxy. Sometimes it will be a layer 3 load-balancer such as LVS or any commercial load-balancer, and sometimes it will simply be a more complete monitoring system such as Nagios. When the tests are very frequent, users often ask how to disable logging for those checks. There are three possibilities : - if connections come from everywhere and are just TCP probes, it is often desired to simply disable logging of connections without data exchange, by setting "option dontlognull" in the frontend. It also disables logging of port scans, which may or may not be desired. - if the connection come from a known source network, use "monitor-net" to declare this network as monitoring only. Any host in this network will then only be able to perform health checks, and their requests will not be logged. This is generally appropriate to designate a list of equipment such as other load-balancers. - if the tests are performed on a known URI, use "monitor-uri" to declare this URI as dedicated to monitoring. Any host sending this request will only get the result of a health-check, and the request will not be logged.
The problem with logging at end of connection is that you have no clue about what is happening during very long sessions, such as remote terminal sessions or large file downloads. This problem can be worked around by specifying "option logasap" in the frontend. HAProxy will then 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 larger.
Sometimes it is more convenient to separate normal traffic from errors logs, for instance in order to ease error monitoring from log files. When the option "log-separate-errors" is used, connections which experience errors, timeouts, retries, redispatches or HTTP status codes 5xx will see their syslog level raised from "info" to "err". This will help a syslog daemon store the log in a separate file. It is very important to keep the errors in the normal traffic file too, so that log ordering is not altered. You should also be careful if you already have configured your syslog daemon to store all logs higher than "notice" in an "admin" file, because the "err" level is higher than "notice".
Although this may sound strange at first, some large sites have to deal with multiple thousands of logs per second and are experiencing difficulties keeping them intact for a long time or detecting errors within them. If the option "dontlog-normal" is set on the frontend, all normal connections will not be logged. In this regard, a normal connection is defined as one without any error, timeout, retry nor redispatch. In HTTP, the status code is checked too, and a response with a status 5xx is not considered normal and will be logged too. Of course, doing is is really discouraged as it will remove most of the useful information from the logs. Do this only if you have no other alternative.
Timers provide a great help in troubleshooting network problems. All values are reported in milliseconds (ms). These timers should be used in conjunction with the session termination flags. In TCP mode with "option tcplog" set on the frontend, 3 control points are reported under the form "Tw/Tc/Tt", and in HTTP mode, 5 control points are reported under the form "TR/Tw/Tc/Tr/Ta". In addition, three other measures are provided, "Th", "Ti", and "Tq". Timings events in HTTP mode: first request 2nd request |<-------------------------------->|<-------------- ... t tr t tr ... ---|----|----|----|----|----|----|----|----|-- : Th Ti TR Tw Tc Tr Td : Ti ... :<---- Tq ---->: : :<-------------- Tt -------------->: :<--------- Ta --------->: Timings events in TCP mode: TCP session |<----------------->| t t ---|----|----|----|----|--- | Th Tw Tc Td | |<------ Tt ------->| - Th: total time to accept tcp connection and execute handshakes for low level protocols. Currently, these protocols are proxy-protocol and SSL. This may only happen once during the whole connection's lifetime. A large time here may indicate that the client only pre-established the connection without speaking, that it is experiencing network issues preventing it from completing a handshake in a reasonable time (e.g. MTU issues), or that an SSL handshake was very expensive to compute. Please note that this time is reported only before the first request, so it is safe to average it over all request to calculate the amortized value. The second and subsequent request will always report zero here. - Ti: is the idle time before the HTTP request (HTTP mode only). This timer counts between the end of the handshakes and the first byte of the HTTP request. When dealing with a second request in keep-alive mode, it starts to count after the end of the transmission the previous response. When a multiplexed protocol such as HTTP/2 is used, it starts to count immediately after the previous request. Some browsers pre-establish connections to a server in order to reduce the latency of a future request, and keep them pending until they need it. This delay will be reported as the idle time. A value of -1 indicates that nothing was received on the connection. - TR: total time to get the client request (HTTP mode only). It's the time elapsed between the first bytes received and the moment the proxy received the empty line marking the end of the HTTP headers. The value "-1" indicates that the end of headers has never been seen. This happens when the client closes prematurely or times out. This time is usually very short since most requests fit in a single packet. A large time may indicate a request typed by hand during a test. - Tq: total time to get the client request from the accept date or since the emission of the last byte of the previous response (HTTP mode only). It's exactly equal to Th + Ti + TR unless any of them is -1, in which case it returns -1 as well. This timer used to be very useful before the arrival of HTTP keep-alive and browsers' pre-connect feature. It's recommended to drop it in favor of TR nowadays, as the idle time adds a lot of noise to the reports. - Tw: total time spent in the queues waiting for a connection slot. It accounts for backend queue as well as the server queues, and depends on the queue size, and the time needed for the server to complete previous requests. The value "-1" means that the request was killed before reaching the queue, which is generally what happens with invalid or denied requests. - 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 by the server, or between the TCP SYN packet and the matching SYN/ACK packet in return. The value "-1" means that the connection never established. - Tr: server response time (HTTP mode only). It's the time elapsed between the moment the TCP connection was established to the server and the moment the server sent its complete response headers. It purely shows its request processing time, without the network overhead due to the data transmission. It is worth noting that when the client has data to send to the server, for instance during a POST request, the time already runs, and this can distort apparent response time. For this reason, it's generally wise not to trust too much this field for POST requests initiated from clients behind an untrusted network. A value of "-1" here means that the last the response header (empty line) was never seen, most likely because the server timeout stroke before the server managed to process the request. - Ta: total active time for the HTTP request, between the moment the proxy received the first byte of the request header and the emission of the last byte of the response body. The exception is when the "logasap" option is specified. In this case, it only equals (TR+Tw+Tc+Tr), and is prefixed with a '+' sign. From this field, we can deduce "Td", the data transmission time, by subtracting other timers when valid : Td = Ta - (TR + Tw + Tc + Tr) Timers with "-1" values have to be excluded from this equation. Note that "Ta" can never be negative. - 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 (Th+Ti+TR+Tw+Tc+Tr), and is prefixed with a '+' sign. From this field, we can deduce "Td", the data transmission time, by subtracting other timers when valid : Td = Tt - (Th + Ti + TR + Tw + Tc + Tr) Timers with "-1" values have to be excluded from this equation. In TCP mode, "Ti", "Tq" and "Tr" have to be excluded too. Note that "Tt" can never be negative and that for HTTP, Tt is simply equal to (Th+Ti+Ta). 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 lost packets due to network problems (wires, negotiation, congestion). Moreover, if "Ta" or "Tt" is close to a timeout value specified in the configuration, it often means that a session has been aborted on timeout. Most common cases : - If "Th" or "Ti" are close to 3000, a packet has probably been lost between the client and the proxy. This is very rare on local networks but might happen when clients are on far remote networks and send large requests. It may happen that values larger than usual appear here without any network cause. Sometimes, during an attack or just after a resource starvation has ended, haproxy may accept thousands of connections in a few milliseconds. The time spent accepting these connections will inevitably slightly delay processing of other connections, and it can happen that request times in the order of a few tens of milliseconds are measured after a few thousands of new connections have been accepted at once. Using one of the keep-alive modes may display larger idle times since "Ti" measures the time spent waiting for additional requests. - If "Tc" is close to 3000, a packet has probably been lost between the server and the proxy during the server connection phase. This value should always be very low, such as 1 ms on local networks and less than a few tens of ms on remote networks. - 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 "Ta" is large even for small byte counts, it generally is because neither the client nor the server decides to close the connection while haproxy is running in tunnel mode and both have agreed on a keep-alive connection mode. In order to solve this issue, it will be needed to specify one of the HTTP options to manipulate keep-alive or close options on either the frontend or the backend. Having the smallest possible 'Ta' or 'Tt' is important when connection regulation is used with the "maxconn" option on the servers, since no new connection will be sent to the server until another one is released. Other noticeable HTTP log cases ('xx' means any value to be ignored) : TR/Tw/Tc/Tr/+Ta The "option logasap" is present on the frontend and the log was emitted before the data phase. All the timers are valid except "Ta" which is shorter than reality. -1/xx/xx/xx/Ta The client was not able to send a complete request in time or it aborted too early. Check the session termination flags then "timeout http-request" and "timeout client" settings. TR/-1/xx/xx/Ta It was not possible to process the request, maybe because servers were out of order, because the request was invalid or forbidden by ACL rules. Check the session termination flags. TR/Tw/-1/xx/Ta The connection could not establish on the server. Either it actively refused it or it timed out after Ta-(TR+Tw) ms. Check the session termination flags, then check the "timeout connect" setting. Note that the tarpit action might return similar-looking patterns, with "Tw" equal to the time the client connection was maintained open. TR/Tw/Tc/-1/Ta The server has accepted the connection but did not return a complete response in time, or it closed its connection unexpectedly after Ta-(TR+Tw+Tc) ms. Check the session termination flags, then check the "timeout server" setting.
TCP and HTTP logs provide a session termination indicator in the "termination_state" field, just before the number of active connections. It is 2-characters long in TCP mode, and is extended to 4 characters in HTTP mode, 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, because of a security check which detected and blocked a dangerous error in server response which might have caused information leak (e.g. cacheable cookie). L : the session was locally processed by haproxy and was not passed to a server. This is what happens for stats and redirects. 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. If this happens, it must be considered as a very serious anomaly which should be fixed as soon as possible by any means. 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 would almost certainly be a bug. It would be wise to preventively restart the process after such an event too, in case it would be caused by memory corruption. D : the session was killed by haproxy because the server was detected as down and was configured to kill all connections when going down. U : the session was killed by haproxy on this backup server because an active server was detected as up and was configured to kill all backup connections when going up. K : the session was actively killed by an admin operating on haproxy. c : the client-side timeout expired while waiting for the client to send or receive data. s : the server-side timeout expired while waiting for the server to send or receive data. - : normal session completion, both the client and the server closed with nothing left in the buffers. - on the second character, the TCP or HTTP session state when it was closed : R : the proxy was waiting for a complete, valid REQUEST from the client (HTTP mode only). Nothing was sent to any server. Q : the proxy was waiting in the QUEUE for a connection slot. This can only happen when servers have a 'maxconn' parameter set. It can also happen in the global queue after a redispatch consecutive to a failed attempt to connect to a dying server. If no redispatch is reported, then no connection attempt was made to any server. C : the proxy was waiting for the CONNECTION to establish on the server. The server might at most have noticed a connection attempt. H : the proxy was waiting for complete, valid response HEADERS from the server (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. This one is very rare as it can only happen when the client dies while receiving the last packets. T : the request was tarpitted. It has been held open with the client during the whole "timeout tarpit" duration or until the client closed, both of which will be reported in the "Tw" timer. - : 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 for new visitors, so counting the number of occurrences of this flag in the logs generally indicate a valid trend for the site frequentation. 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, persistence conditionally ignored, or an attack. D : the client provided a cookie designating a server which was DOWN, so either "option persist" 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. E : the client provided a valid cookie, but with a last date which was older than what is allowed by the "maxidle" cookie parameter, so the cookie is consider EXPIRED and is ignored. The request will be redispatched just as if there was no cookie. O : the client provided a valid cookie, but with a first date which was older than what is allowed by the "maxlife" cookie parameter, so the cookie is consider too OLD and is ignored. The request will be redispatched just as if there was no cookie. U : a cookie was present but was not used to select the server because some other server selection mechanism was used instead (typically a "use-server" rule). - : 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. Note that in "cookie insert" mode, if the server provides a cookie, it will still be overwritten and reported as "I" here. U : the proxy UPDATED the last date in the cookie that was presented by the client. This can only happen in insert mode with "maxidle". It happens every time there is activity at a different date than the date indicated in the cookie. If any other change happens, such as a redispatch, then the cookie will be marked as inserted instead. P : a cookie was PROVIDED by the server and transmitted as-is. R : the cookie provided by the server was REWRITTEN by the proxy, which happens in "cookie rewrite" or "cookie prefix" modes. 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 gives a lot of information about what was happening when the session terminated, and why it did terminate. It can be helpful to detect server saturation, network troubles, local system resource starvation, attacks, etc... The most common termination flags combinations are indicated below. They are alphabetically sorted, with the lowercase set just after the upper case for easier finding and understanding. Flags Reason -- Normal termination. CC The client aborted before the connection could be established to the server. This can happen when haproxy tries to connect to a recently dead (or unchecked) server, and the client aborts while haproxy is waiting for the server to respond or for "timeout connect" to expire. CD The client unexpectedly aborted during data transfer. This can be caused by a browser crash, by an intermediate equipment between the client and haproxy which decided to actively break the connection, by network routing issues between the client and haproxy, or by a keep-alive session between the server and the client terminated first by the client. cD The client did not send nor acknowledge any data for as long as the "timeout client" delay. This is often caused by network failures on the client side, or the client simply leaving the net uncleanly. 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. cH The "timeout client" stroke while waiting for client data during a POST request. This is sometimes caused by too large TCP MSS values for PPPoE networks which cannot transport full-sized packets. It can also happen when client timeout is smaller than server timeout and the server takes too long to respond. 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 that the assigned server was taking too long a time to respond. CR The client aborted before sending a full HTTP request. Most likely the request was typed by hand using a telnet client, and aborted too early. The HTTP status code is likely a 400 here. Sometimes this might also be caused by an IDS killing the connection between haproxy and the client. "option http-ignore-probes" can be used to ignore connections without any data transfer. cR The "timeout http-request" stroke before the client sent a full HTTP 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, or forgetting to enter the empty line at the end of the request. The HTTP status code is likely a 408 here. Note: recently, some browsers started to implement a "pre-connect" feature consisting in speculatively connecting to some recently visited web sites just in case the user would like to visit them. This results in many connections being established to web sites, which end up in 408 Request Timeout if the timeout strikes first, or 400 Bad Request when the browser decides to close them first. These ones pollute the log and feed the error counters. Some versions of some browsers have even been reported to display the error code. It is possible to work around the undesirable effects of this behavior by adding "option http-ignore-probes" in the frontend, resulting in connections with zero data transfer to be totally ignored. This will definitely hide the errors of people experiencing connectivity issues though. CT The client aborted while its session was tarpitted. It is important to check if this happens on valid requests, in order to be sure that no wrong tarpit rules have been written. If a lot of them happen, it might make sense to lower the "timeout tarpit" value to something closer to the average reported "Tw" timer, in order not to consume resources for just a few attackers. LR The request was intercepted and locally handled by haproxy. Generally it means that this was a redirect or a stats request. SC The server or an equipment between it and haproxy explicitly refused the TCP connection (the proxy received a TCP RST or an ICMP message in return). Under some circumstances, it can also be the network stack telling the proxy that the server is unreachable (e.g. no route, or no ARP response on local network). When this happens in HTTP mode, the status code is likely a 502 or 503 here. sC The "timeout connect" stroke before a connection to the server could complete. When this happens in HTTP mode, the status code is likely a 503 or 504 here. SD The connection to the server died with an error during the data transfer. This usually means that haproxy has received an RST from the server or an ICMP message from an intermediate equipment while exchanging data with the server. This can be caused by a server crash or by a network issue on an intermediate equipment. sD The server did not send nor acknowledge any data for as long as the "timeout server" setting during the data phase. This is often caused by too short timeouts on L4 equipment before the server (firewalls, load-balancers, ...), as well as keep-alive sessions maintained between the client and the server expiring first on haproxy. SH The server aborted before sending its full HTTP response headers, or it crashed while processing the request. Since a server aborting at this moment is very rare, it would be wise to inspect its logs to control whether it crashed and why. The logged request may indicate a small set of faulty requests, demonstrating bugs in the application. Sometimes this might also be caused by an IDS killing the connection between haproxy and the server. sH The "timeout server" stroke before the server could return its response headers. This is the most common anomaly, indicating too long transactions, probably caused by server or database saturation. The immediate workaround consists in increasing the "timeout server" setting, but it is important to keep in mind that the user experience will suffer from these long response times. The only long term solution is to fix the application. sQ The session spent too much time in queue and has been expired. See the "timeout queue" and "timeout connect" settings to find out how to fix this if it happens too often. If it often happens massively in short periods, it may indicate general problems on the affected servers due to I/O or database congestion, or saturation caused by external attacks. PC The proxy refused to establish a connection to the server because the process's socket limit has been reached while attempting to connect. The global "maxconn" parameter may be increased in the configuration so that it does not happen anymore. This status is very rare and might happen when the global "ulimit-n" parameter is forced by hand. PD The proxy blocked an incorrectly formatted chunked encoded message in a request or a response, after the server has emitted its headers. In most cases, this will indicate an invalid message from the server to the client. HAProxy supports chunk sizes of up to 2GB - 1 (2147483647 bytes). Any larger size will be considered as an 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. One possible cause for this error is an invalid syntax in an HTTP header name containing unauthorized characters. It is also possible but quite rare, that the proxy blocked a chunked-encoding request from the client due to an invalid syntax, before the server responded. In this case, an HTTP 400 error is sent to the client and reported in the logs. PR The proxy blocked the client's HTTP 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. 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. The connection was maintained open for as long as reported by the "Tw" timer field. 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. This is very rare and can only be solved by proper system tuning. The combination of the two last flags gives a lot of information about how persistence was handled by the client, the server and by haproxy. This is very important to troubleshoot disconnections, when users complain they have to re-authenticate. The commonly encountered flags are : -- Persistence cookie is not enabled. NN No cookie was provided by the client, none was inserted in the response. For instance, this can be in insert mode with "postonly" set on a GET request. II A cookie designating an invalid server was provided by the client, a valid one was inserted in the response. This typically happens when a "server" entry is removed from the configuration, since its cookie value can be presented by a client when no other server knows it. NI No cookie was provided by the client, one was inserted in the response. This typically happens for first requests from every user in "insert" mode, which makes it an easy way to count real users. VN A cookie was provided by the client, none was inserted in the response. This happens for most responses for which the client has already got a cookie. VU A cookie was provided by the client, with a last visit date which is not completely up-to-date, so an updated cookie was provided in response. This can also happen if there was no date at all, or if there was a date but the "maxidle" parameter was not set, so that the cookie can be switched to unlimited time. EI A cookie was provided by the client, with a last visit date which is too old for the "maxidle" parameter, so the cookie was ignored and a new cookie was inserted in the response. OI A cookie was provided by the client, with a first visit date which is too old for the "maxlife" parameter, so the cookie was ignored and a new cookie was inserted in the response. DI The server designated by the cookie was down, a new server was selected and a new cookie was emitted in the response. VI The server designated by the cookie was not marked dead but could not be reached. A redispatch happened and selected another one, which was then advertised in the response.
In order not to cause trouble to log analysis tools or terminals during log consulting, non-printable characters are not sent as-is into log files, but are converted to the two-digits hexadecimal representation of their ASCII code, prefixed by the character '#'. The only characters that can be logged without being escaped are comprised between 32 and 126 (inclusive). Obviously, the escape character '#' itself is also encoded to avoid any ambiguity ("#23"). It is the same for the character '"' which becomes "#22", as well as '{', '|' and '}' when logging headers. Note that the space character (' ') is not encoded in headers, which can cause issues for tools relying on space count to locate fields. A typical header containing spaces is "User-Agent". Last, it has been observed that some syslog daemons such as syslog-ng escape the quote ('"') with a backslash ('\'). The reverse operation can safely be performed since no quote may appear anywhere else in the logs.
Cookie capture simplifies the tracking a complete user session. This can be achieved using the "capture cookie" statement in the frontend. Please refer to section 4.2 for more details. Only one cookie can be captured, and the same cookie will simultaneously be checked in the request ("Cookie:" header) and in the response ("Set-Cookie:" header). The respective values will be reported in the HTTP logs at the "captured_request_cookie" and "captured_response_cookie" locations (see section 8.2.3 about HTTP log format). When either cookie is not seen, a dash ('-') replaces the value. 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. It is also possible to detect if a server unexpectedly sets a wrong cookie to a client, leading to session crossing.
# 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
Header captures are useful to track unique request identifiers set by an upper 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. Header captures are performed using the "capture request header" and "capture response header" statements in the frontend. Please consult their definition in section 4.2 for more details. It is possible to include both request headers and response headers at the same time. Non-existent headers are logged as empty strings, and if one header appears more than once, only its last occurrence will be logged. 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. As a special case, it is possible to specify an HTTP header capture in a TCP frontend. The purpose is to enable logging of headers which will be parsed in an HTTP backend if the request is then switched to this HTTP backend.
# This instance chains to the outgoing proxy
listen proxy-out
mode http
option httplog
option logasap
log global
server cache1 192.168.1.1:3128
# log the name of the virtual server
capture request header Host len 20
# log the amount of data uploaded during a POST
capture request header Content-Length len 10
# log the beginning of the referrer
capture request header Referer len 20
# server name (useful for outgoing proxies only)
capture response header Server len 20
# logging the content-length is useful with "option logasap"
capture response header Content-Length len 10
# log the expected cache behavior on the response
capture response header Cache-Control len 8
# the Via header will report the next proxy's name
capture response header Via len 20
# log the URL location during a redirection
capture response header Location len 20
>>> Aug 9 20:26:09 localhost \
haproxy[2022]: 127.0.0.1:34014 [09/Aug/2004:20:26:09] proxy-out \
proxy-out/cache1 0/0/0/162/+162 200 +350 - - ---- 0/0/0/0/0 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] proxy-out \
proxy-out/cache1 0/0/0/182/+182 200 +279 - - ---- 0/0/0/0/0 0/0 \
{w.ods.org||} {Formilux/0.1.8|3495|||} \
"GET http://trafic.1wt.eu/ HTTP/1.1"
>>> Aug 9 20:30:46 localhost \
haproxy[2022]: 127.0.0.1:34028 [09/Aug/2004:20:30:46] proxy-out \
proxy-out/cache1 0/0/2/126/+128 301 +223 - - ---- 0/0/0/0/0 0/0 \
{www.sytadin.equipement.gouv.fr||http://trafic.1wt.eu/} \
{Apache|230|||http://www.sytadin.} \
"GET http://www.sytadin.equipement.gouv.fr/ HTTP/1.1"
These are real-world examples of logs accompanied with an explanation. Some of them have been made up by hand. The syslog part has been removed for better reading. Their sole purpose is to explain how to decipher them. >>> haproxy[674]: 127.0.0.1:33318 [15/Oct/2003:08:31:57.130] px-http \ px-http/srv1 6559/0/7/147/6723 200 243 - - ---- 5/3/3/1/0 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/2003:08:31:57.149] px-http \ px-http/srv1 6559/1230/7/147/6870 200 243 - - ---- 324/239/239/99/0 \ 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/2003:08:32:17.654] px-http \ px-http/srv1 9/0/7/14/+30 200 +243 - - ---- 3/3/3/1/0 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 transferring 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/2003:08:32:17.925] px-http \ px-http/srv1 9/0/7/14/30 502 243 - - PH-- 3/2/2/0/0 0/0 \ "GET /cgi-bin/bug.cgi? HTTP/1.0" => the proxy blocked a server response either because of an "http-response deny" rule, or because the response was improperly formatted and not HTTP-compliant, or because it blocked sensitive information which risked being cached. In this case, the response is replaced with a "502 bad gateway". The flags ("PH--") tell us that it was haproxy who decided to return the 502 and not the server. >>> haproxy[18113]: 127.0.0.1:34548 [15/Oct/2003:15:18:55.798] px-http \ px-http/<NOSRV> -1/-1/-1/-1/8490 -1 0 - - CR-- 2/2/2/0/0 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 any server. >>> haproxy[18113]: 127.0.0.1:34549 [15/Oct/2003:15:19:06.103] px-http \ px-http/<NOSRV> -1/-1/-1/-1/50001 408 0 - - cR-- 2/2/2/0/0 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 any server, but the proxy could send a 408 return code to the client. >>> haproxy[18989]: 127.0.0.1:34550 [15/Oct/2003:15:24:28.312] px-tcp \ px-tcp/srv1 0/0/5007 0 cD 0/0/0/0/0 0/0 => This log was produced with "option tcplog". The client timed out after 5 seconds ("c----"). >>> haproxy[18989]: 10.0.0.1:34552 [15/Oct/2003:15:26:31.462] px-http \ px-http/srv1 3183/-1/-1/-1/11215 503 0 - - SC-- 205/202/202/115/3 \ 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 attempts of 2 seconds (config says 'retries 3'), and no redispatch (otherwise we would have seen "/+3"). Status code 503 was returned 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.
Here are listed officially supported filters with the list of parameters they accept. Depending on compile options, some of these filters might be unavailable. The list of available filters is reported in haproxy -vv.
<name> is an arbitrary name that will be reported in messages. If no name is provided, "TRACE" is used. <random-parsing> enables the random parsing of data exchanged between the client and the server. By default, this filter parses all available data. With this parameter, it only parses a random amount of the available data. <random-forwarding> enables the random forwarding of parsed data. By default, this filter forwards all previously parsed data. With this parameter, it only forwards a random amount of the parsed data. <hexdump> dumps all forwarded data to the server and the client.
This filter can be used as a base to develop new filters. It defines all callbacks and print a message on the standard error stream (stderr) with useful information for all of them. It may be useful to debug the activity of other filters or, quite simply, HAProxy's activity. Using <random-parsing> and/or <random-forwarding> parameters is a good way to tests the behavior of a filter that parses data exchanged between a client and a server by adding some latencies in the processing.
The HTTP compression has been moved in a filter in HAProxy 1.7. "compression" keyword must still be used to enable and configure the HTTP compression. And when no other filter is used, it is enough. When used with the cache or the fcgi-app enabled, it is also enough. In this case, the compression is always done after the response is stored in the cache. But it is mandatory to explicitly use a filter line to enable the HTTP compression when at least one filter other than the cache or the fcgi-app is used for the same listener/frontend/backend. This is important to know the filters evaluation order.
<name> is the engine name that will be used to find the right scope in the configuration file. If not provided, all the file will be parsed. <file> is the path of the engine configuration file. This file can contain configuration of several engines. In this case, each part must be placed in its own scope.
The Stream Processing Offload Engine (SPOE) is a filter communicating with external components. It allows the offload of some specifics processing on the streams in tiered applications. These external components and information exchanged with them are configured in dedicated files, for the main part. It also requires dedicated backends, defined in HAProxy configuration. SPOE communicates with external components using an in-house binary protocol, the Stream Processing Offload Protocol (SPOP). For all information about the SPOE configuration and the SPOP specification, see "doc/SPOE.txt".
<name> is name of the cache section this filter will use.
The cache uses a filter to store cacheable responses. The HTTP rules "cache-store" and "cache-use" must be used to define how and when to use a cache. By default the corresponding filter is implicitly defined. And when no other filters than fcgi-app or compression are used, it is enough. In such case, the compression filter is always evaluated after the cache filter. But it is mandatory to explicitly use a filter line to use a cache when at least one filter other than the compression or the fcgi-app is used for the same listener/frontend/backend. This is important to know the filters evaluation order.
<name> is name of the fcgi-app section this filter will use.
The FastCGI application uses a filter to evaluate all custom parameters on the
request path, and to process the headers on the response path. the <name> must
reference an existing fcgi-app section. The directive "use-fcgi-app" should be
used to define the application to use. By default the corresponding filter is
implicitly defined. And when no other filters than cache or compression are
used, it is enough. But it is mandatory to explicitly use a filter line to a
fcgi-app when at least one filter other than the compression or the cache is
used for the same backend. This is important to know the filters evaluation
order.
HAProxy is able to send HTTP requests to Responder FastCGI applications. This
feature was added in HAProxy 2.1. To do so, servers must be configured to use
the FastCGI protocol (using the keyword "proto fcgi" on the server line) and a
FastCGI application must be configured and used by the backend managing these
servers (using the keyword "use-fcgi-app" into the proxy section). Several
FastCGI applications may be defined, but only one can be used at a time by a
backend.
HAProxy implements all features of the FastCGI specification for Responder
application. Especially it is able to multiplex several requests on a simple
connection.
Declare a FastCGI application named <name>. To be valid, at least the document root must be defined.
Declare or complete an access list. See "acl" keyword in section 4.2 and section 7 about ACL usage for details. ACLs defined for a FastCGI application are private. They cannot be used by any other application or by any proxy. In the same way, ACLs defined in any other section are not usable by a FastCGI application. However, Pre-defined ACLs are available.
Define the script name that will be appended after an URI that ends with a slash ("/") to set the default value of the FastCGI parameter SCRIPT_NAME. It is an optional setting.
index index.php
Enable logging of STDERR messages reported by the FastCGI application. See "log" keyword in section 4.2 for details. It is an optional setting. By default STDERR messages are ignored.
Specify the name of a request header which will be passed to the FastCGI application. It may optionally be followed by an ACL-based condition, in which case it will only be evaluated if the condition is true. Most request headers are already available to the FastCGI application, prefixed with "HTTP_". Thus, this directive is only required to pass headers that are purposefully omitted. Currently, the headers "Authorization", "Proxy-Authorization" and hop-by-hop headers are omitted. Note that the headers "Content-type" and "Content-length" are never passed to the FastCGI application because they are already converted into parameters.
Define a regular expression to extract the script-name and the path-info from the URL-decoded path. Thus, <regex> may have two captures: the first one to capture the script name and the second one to capture the path-info. The first one is mandatory, the second one is optional. This way, it is possible to extract the script-name from the path ignoring the path-info. It is an optional setting. If it is not defined, no matching is performed on the path. and the FastCGI parameters PATH_INFO and PATH_TRANSLATED are not filled. For security reason, when this regular expression is defined, the newline and the null characters are forbidden from the path, once URL-decoded. The reason to such limitation is because otherwise the matching always fails (due to a limitation one the way regular expression are executed in HAProxy). So if one of these two characters is found in the URL-decoded path, an error is returned to the client. The principle of least astonishment is applied here.
path-info ^(/.+\.php)(/.*)?$ # both script-name and path-info may be set
path-info ^(/.+\.php) # the path-info is ignored
Enable or disable the retrieve of variables about connection management. HAproxy is able to send the record FCGI_GET_VALUES on connection establishment to retrieve the value for following variables: * FCGI_MAX_REQS The maximum number of concurrent requests this application will accept. * FCGI_MPXS_CONNS "0" if this application does not multiplex connections, "1" otherwise. Some FastCGI applications does not support this feature. Some others close the connexion immediately after sending their response. So, by default, this option is disabled. Note that the maximum number of concurrent requests accepted by a FastCGI application is a connection variable. It only limits the number of streams per connection. If the global load must be limited on the application, the server parameters "maxconn" and "pool-max-conn" must be set. In addition, if an application does not support connection multiplexing, the maximum number of concurrent requests is automatically set to 1.
Instruct the FastCGI application to keep the connection open or not after sending a response. If disabled, the FastCGI application closes the connection after responding to this request. By default, this option is enabled.
Define the maximum number of concurrent requests this application will accept. This option may be overwritten if the variable FCGI_MAX_REQS is retrieved during connection establishment. Furthermore, if the application does not support connection multiplexing, this option will be ignored. By default set to 1.
Enable or disable the support of connection multiplexing. This option may be overwritten if the variable FCGI_MPXS_CONNS is retrieved during connection establishment. It is disabled by default.
Set a FastCGI parameter that should be passed to this application. Its value, defined by <fmt> must follows the log-format rules (see section 8.2.4 "Custom Log format"). It may optionally be followed by an ACL-based condition, in which case it will only be evaluated if the condition is true. With this directive, it is possible to overwrite the value of default FastCGI parameters. If the value is evaluated to an empty string, the rule is ignored. These directives are evaluated in their declaration order.
# PHP only, required if PHP was built with --enable-force-cgi-redirect
set-param REDIRECT_STATUS 200
set-param PHP_AUTH_DIGEST %[req.hdr(Authorization)]
Define the FastCGI application to use for the backend.
<name> is the name of the FastCGI application to use.
This keyword is only available for HTTP proxies with the backend capability and with at least one FastCGI server. However, FastCGI servers can be mixed with HTTP servers. But except there is a good reason to do so, it is not recommended (see section 10.3 about the limitations for details). Only one application may be defined at a time per backend. Note that, once a FastCGI application is referenced for a backend, depending on the configuration some processing may be done even if the request is not sent to a FastCGI server. Rules to set parameters or pass headers to an application are evaluated.
frontend front-http mode http bind *:80 bind *: use_backend back-dynamic if { path_reg ^/.+\.php(/.*)?$ } default_backend back-static backend back-static mode http server www A.B.C.D:80 backend back-dynamic mode http use-fcgi-app php-fpm server php-fpm A.B.C.D:9000 proto fcgi fcgi-app php-fpm log-stderr global option keep-conn docroot /var/www/my-app index index.php path-info ^(/.+\.php)(/.*)?$
A Responder FastCGI application has the same purpose as a CGI/1.1 program. In the CGI/1.1 specification (RFC3875), several variables must be passed to the script. So HAProxy set them and some others commonly used by FastCGI applications. All these variables may be overwritten, with caution though. +-------------------+-----------------------------------------------------+ | AUTH_TYPE | Identifies the mechanism, if any, used by HAProxy | | | to authenticate the user. Concretely, only the | | | BASIC authentication mechanism is supported. | | | | +-------------------+-----------------------------------------------------+ | CONTENT_LENGTH | Contains the size of the message-body attached to | | | the request. It means only requests with a known | | | size are considered as valid and sent to the | | | application. | | | | +-------------------+-----------------------------------------------------+ | CONTENT_TYPE | Contains the type of the message-body attached to | | | the request. It may not be set. | | | | +-------------------+-----------------------------------------------------+ | DOCUMENT_ROOT | Contains the document root on the remote host under | | | which the script should be executed, as defined in | | | the application's configuration. | | | | +-------------------+-----------------------------------------------------+ | GATEWAY_INTERFACE | Contains the dialect of CGI being used by HAProxy | | | to communicate with the FastCGI application. | | | Concretely, it is set to "CGI/1.1". | | | | +-------------------+-----------------------------------------------------+ | PATH_INFO | Contains the portion of the URI path hierarchy | | | following the part that identifies the script | | | itself. To be set, the directive "path-info" must | | | be defined. | | | | +-------------------+-----------------------------------------------------+ | PATH_TRANSLATED | If PATH_INFO is set, it is its translated version. | | | It is the concatenation of DOCUMENT_ROOT and | | | PATH_INFO. If PATH_INFO is not set, this parameters | | | is not set too. | | | | +-------------------+-----------------------------------------------------+ | QUERY_STRING | Contains the request's query string. It may not be | | | set. | | | | +-------------------+-----------------------------------------------------+ | REMOTE_ADDR | Contains the network address of the client sending | | | the request. | | | | +-------------------+-----------------------------------------------------+ | REMOTE_USER | Contains the user identification string supplied by | | | client as part of user authentication. | | | | +-------------------+-----------------------------------------------------+ | REQUEST_METHOD | Contains the method which should be used by the | | | script to process the request. | | | | +-------------------+-----------------------------------------------------+ | REQUEST_URI | Contains the request's URI. | | | | +-------------------+-----------------------------------------------------+ | SCRIPT_FILENAME | Contains the absolute pathname of the script. it is | | | the concatenation of DOCUMENT_ROOT and SCRIPT_NAME. | | | | +-------------------+-----------------------------------------------------+ | SCRIPT_NAME | Contains the name of the script. If the directive | | | "path-info" is defined, it is the first part of the | | | URI path hierarchy, ending with the script name. | | | Otherwise, it is the entire URI path. | | | | +-------------------+-----------------------------------------------------+ | SERVER_NAME | Contains the name of the server host to which the | | | client request is directed. It is the value of the | | | header "Host", if defined. Otherwise, the | | | destination address of the connection on the client | | | side. | | | | +-------------------+-----------------------------------------------------+ | SERVER_PORT | Contains the destination TCP port of the connection | | | on the client side, which is the port the client | | | connected to. | | | | +-------------------+-----------------------------------------------------+ | SERVER_PROTOCOL | Contains the request's protocol. | | | | +-------------------+-----------------------------------------------------+ | HTTPS | Set to a non-empty value ("on") if the script was | | | queried through the HTTPS protocol. | | | | +-------------------+-----------------------------------------------------+
The current implementation have some limitations. The first one is about the way some request headers are hidden to the FastCGI applications. This happens during the headers analysis, on the backend side, before the connection establishment. At this stage, HAProxy know the backend is using a FastCGI application but it don't know if the request will be routed to a FastCGI server or not. But to hide request headers, it simply removes them from the HTX message. So, if the request is finally routed to an HTTP server, it never see these headers. For this reason, it is not recommended to mix FastCGI servers and HTTP servers under the same backend. Similarly, the rules "set-param" and "pass-header" are evaluated during the request headers analysis. So the evaluation is always performed, even if the requests is finally forwarded to an HTTP server. About the rules "set-param", when a rule is applied, a pseudo header is added into the HTX message. So, the same way than for HTTP header rewrites, it may fail if the buffer is full. The rules "set-param" will compete with "http-request" ones. Finally, all FastCGI params and HTTP headers are sent into a unique record FCGI_PARAM. Encoding of this record must be done in one pass, otherwise a processing error is returned. It means the record FCGI_PARAM, once encoded, must not exceeds the size of a buffer. However, there is no reserve to respect here.