---------------------- HAProxy Configuration Manual ---------------------- version 2.4 2023/12/14 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. Summary ------- 1. Quick reminder about HTTP 1.1. The HTTP transaction model 1.2. HTTP request 1.2.1. The request line 1.2.2. The request headers 1.3. HTTP response 1.3.1. The response line 1.3.2. The response headers 2. Configuring HAProxy 2.1. Configuration file format 2.2. Quoting and escaping 2.3. Environment variables 2.4. Conditional blocks 2.5. Time format 2.6. Size format 2.7. Examples 3. Global parameters 3.1. Process management and security 3.2. Performance tuning 3.3. Debugging 3.4. Userlists 3.5. Peers 3.6. Mailers 3.7. Programs 3.8. HTTP-errors 3.9. Rings 3.10. Log forwarding 4. Proxies 4.1. Proxy keywords matrix 4.2. Alphabetically sorted keywords reference 5. Bind and server options 5.1. Bind options 5.2. Server and default-server options 5.3. Server DNS resolution 5.3.1. Global overview 5.3.2. The resolvers section 6. Cache 6.1. Limitation 6.2. Setup 6.2.1. Cache section 6.2.2. Proxy section 7. Using ACLs and fetching samples 7.1. ACL basics 7.1.1. Matching booleans 7.1.2. Matching integers 7.1.3. Matching strings 7.1.4. Matching regular expressions (regexes) 7.1.5. Matching arbitrary data blocks 7.1.6. Matching IPv4 and IPv6 addresses 7.2. Using ACLs to form conditions 7.3. Fetching samples 7.3.1. Converters 7.3.2. Fetching samples from internal states 7.3.3. Fetching samples at Layer 4 7.3.4. Fetching samples at Layer 5 7.3.5. Fetching samples from buffer contents (Layer 6) 7.3.6. Fetching HTTP samples (Layer 7) 7.3.7. Fetching samples for developers 7.4. Pre-defined ACLs 8. Logging 8.1. Log levels 8.2. Log formats 8.2.1. Default log format 8.2.2. TCP log format 8.2.3. HTTP log format 8.2.4. Custom log format 8.2.5. Error log format 8.3. Advanced logging options 8.3.1. Disabling logging of external tests 8.3.2. Logging before waiting for the session to terminate 8.3.3. Raising log level upon errors 8.3.4. Disabling logging of successful connections 8.4. Timing events 8.5. Session state at disconnection 8.6. Non-printable characters 8.7. Capturing HTTP cookies 8.8. Capturing HTTP headers 8.9. Examples of logs 9. Supported filters 9.1. Trace 9.2. HTTP compression 9.3. Stream Processing Offload Engine (SPOE) 9.4. Cache 9.5. fcgi-app 9.6. OpenTracing 10. FastCGI applications 10.1. Setup 10.1.1. Fcgi-app section 10.1.2. Proxy section 10.1.3. Example 10.2. Default parameters 10.3. Limitations 11. Address formats 11.1. Address family prefixes 11.2. Socket type prefixes 11.3. Protocol prefixes 1. Quick reminder about HTTP ---------------------------- 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. 1.1. The HTTP transaction model ------------------------------- 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. 1.2. HTTP request ----------------- 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 1.2.1. The Request line ----------------------- 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"). 1.2.2. The request headers -------------------------- 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. 1.3. HTTP response ------------------ 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. 1.3.1. The response line ------------------------ 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 501 when HAProxy is unable to satisfy a client request because of an unsupported feature 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). 1.3.2. The response headers --------------------------- 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. 2. Configuring HAProxy ---------------------- 2.1. Configuration file format ------------------------------ HAProxy's configuration process involves 3 major sources of parameters : - the arguments from the command-line, which always take precedence - the configuration file(s), whose format is described here - the running process's environment, in case some environment variables are explicitly referenced The configuration file follows a fairly simple hierarchical format which obey a few basic rules: 1. a configuration file is an ordered sequence of statements 2. a statement is a single non-empty line before any unprotected "#" (hash) 3. a line is a series of tokens or "words" delimited by unprotected spaces or tab characters 4. the first word or sequence of words of a line is one of the keywords or keyword sequences listed in this document 5. all other words are all arguments of the first one, some being well-known keywords listed in this document, others being values, references to other parts of the configuration, or expressions 6. certain keywords delimit a section inside which only a subset of keywords are supported 7. a section ends at the end of a file or on a special keyword starting a new section This is all that is needed to know to write a simple but reliable configuration generator, but this is not enough to reliably parse any configuration nor to figure how to deal with certain corner cases. First, there are a few consequences of the rules above. Rule 6 and 7 imply that the keywords used to define a new section are valid everywhere and cannot have a different meaning in a specific section. These keywords are always a single word (as opposed to a sequence of words), and traditionally the section that follows them is designated using the same name. For example when speaking about the "global section", it designates the section of configuration that follows the "global" keyword. This usage is used a lot in error messages to help locate the parts that need to be addressed. A number of sections create an internal object or configuration space, which requires to be distinguished from other ones. In this case they will take an extra word which will set the name of this particular section. For some of them the section name is mandatory. For example "frontend foo" will create a new section of type "frontend" named "foo". Usually a name is specific to its section and two sections of different types may use the same name, but this is not recommended as it tends to complexify configuration management. A direct consequence of rule 7 is that when multiple files are read at once, each of them must start with a new section, and the end of each file will end a section. A file cannot contain sub-sections nor end an existing section and start a new one. Rule 1 mentioned that ordering matters. Indeed, some keywords create directives that can be repeated multiple times to create ordered sequences of rules to be applied in a certain order. For example "tcp-request" can be used to alternate "accept" and "reject" rules on varying criteria. As such, a configuration file processor must always preserve a section's ordering when editing a file. The ordering of sections usually does not matter except for the global section which must be placed before other sections, but it may be repeated if needed. In addition, some automatic identifiers may automatically be assigned to some of the created objects (e.g. proxies), and by reordering sections, their identifiers will change. These ones appear in the statistics for example. As such, the configuration below will assign "foo" ID number 1 and "bar" ID number 2, which will be swapped if the two sections are reversed: listen foo bind :80 listen bar bind :81 Another important point is that according to rules 2 and 3 above, empty lines, spaces, tabs, and comments following and unprotected "#" character are not part of the configuration as they are just used as delimiters. This implies that the following configurations are strictly equivalent: global#this is the global section daemon#daemonize frontend foo mode http # or tcp and: global daemon # this is the public web frontend frontend foo mode http The common practice is to align to the left only the keyword that initiates a new section, and indent (i.e. prepend a tab character or a few spaces) all other keywords so that it's instantly visible that they belong to the same section (as done in the second example above). Placing comments before a new section helps the reader decide if it's the desired one. Leaving a blank line at the end of a section also visually helps spotting the end when editing it. Tabs are very convenient for indent but they do not copy-paste well. If spaces are used instead, it is recommended to avoid placing too many (2 to 4) so that editing in field doesn't become a burden with limited editors that do not support automatic indent. In the early days it used to be common to see arguments split at fixed tab positions because most keywords would not take more than two arguments. With modern versions featuring complex expressions this practice does not stand anymore, and is not recommended. 2.2. Quoting and escaping ------------------------- In modern configurations, some arguments require the use of some characters that were previously considered as pure delimiters. In order to make this possible, HAProxy supports character escaping by prepending a backslash ('\') in front of the character to be escaped, weak quoting within double quotes ('"') and strong quoting within single quotes ("'"). This is pretty similar to what is done in a number of programming languages and very close to what is commonly encountered in Bourne shell. The principle is the following: while the configuration parser cuts the lines into words, it also takes care of quotes and backslashes to decide whether a character is a delimiter or is the raw representation of this character within the current word. The escape character is then removed, the quotes are removed, and the remaining word is used as-is as a keyword or argument for example. If a backslash is needed in a word, it must either be escaped using itself (i.e. double backslash) or be strongly quoted. Escaping outside quotes 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 In addition, a few non-printable characters may be emitted using their usual C-language representation: \n to insert a line feed (LF, character \x0a or ASCII 10 decimal) \r to insert a carriage return (CR, character \x0d or ASCII 13 decimal) \t to insert a tab (character \x09 or ASCII 9 decimal) \xNN to insert character having ASCII code hex NN (e.g \x0a for LF). Weak quoting is achieved by surrounding double quotes ("") around the character or sequence of characters to protect. Weak quoting prevents the interpretation of: space or tab as a word separator ' single quote as a strong quoting delimiter # hash as a comment start Weak quoting permits the interpretation of environment variables (which are not evaluated outside of quotes) by preceding them with a dollar sign ('$'). If a dollar character is needed inside double quotes, it must be escaped using a backslash. Strong quoting is achieved by surrounding single quotes ('') around the character or sequence of characters to protect. Inside single quotes, nothing is interpreted, it's the efficient way to quote regular expressions. As a result, here is the matrix indicating how special characters can be entered in different contexts (unprintable characters are replaced with their name within angle brackets). Note that some characters that may only be represented escaped have no possible representation inside single quotes, hence the '-' there: Character | Unquoted | Weakly quoted | Strongly quoted -----------+---------------+-----------------------------+----------------- | \, \x09 | "", "\", "\x09" | '' | \n, \x0a | "\n", "\x0a" | - | \r, \x0d | "\r", "\x0d" | - | \, \x20 | "", "\", "\x20" | '' " | \", \x22 | "\"", "\x22" | '"' # | \#, \x23 | "#", "\#", "\x23" | '#' $ | $, \$, \x24 | "\$", "\x24" | '$' ' | \', \x27 | "'", "\'", "\x27" | - \ | \\, \x5c | "\\", "\x5c" | '\' Example: # those are all strictly equivalent: 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 There is one particular case where a second level of quoting or escaping may be necessary. Some keywords take arguments within parenthesis, sometimes delimited by commas. These arguments are commonly integers or predefined words, but when they are arbitrary strings, it may be required to perform a separate level of escaping to disambiguate the characters that belong to the argument from the characters that are used to delimit the arguments themselves. A pretty common case is the "regsub" converter. It takes a regular expression in argument, and if a closing parenthesis is needed inside, this one will require to have its own quotes. The keyword argument parser is exactly the same as the top-level one regarding quotes, except that the \#, \$, and \xNN escapes are not processed. But what is not always obvious is that the delimiters used inside must first be escaped or quoted so that they are not resolved at the top level. Let's take this example making use of the "regsub" converter which takes 3 arguments, one regular expression, one replacement string and one set of flags: # replace all occurrences of "foo" with "blah" in the path: http-request set-path %[path,regsub(foo,blah,g)] Here no special quoting was necessary. But if now we want to replace either "foo" or "bar" with "blah", we'll need the regular expression "(foo|bar)". We cannot write: http-request set-path %[path,regsub((foo|bar),blah,g)] because we would like the string to cut like this: http-request set-path %[path,regsub((foo|bar),blah,g)] |---------|----|-| arg1 _/ / / arg2 __________/ / arg3 ______________/ but actually what is passed is a string between the opening and closing parenthesis then garbage: http-request set-path %[path,regsub((foo|bar),blah,g)] |--------|--------| arg1=(foo|bar _/ / trailing garbage _________/ The obvious solution here seems to be that the closing parenthesis needs to be quoted, but alone this will not work, because as mentioned above, quotes are processed by the top-level parser which will resolve them before processing this word: http-request set-path %[path,regsub("(foo|bar)",blah,g)] ------------ -------- ---------------------------------- word1 word2 word3=%[path,regsub((foo|bar),blah,g)] So we didn't change anything for the argument parser at the second level which still sees a truncated regular expression as the only argument, and garbage at the end of the string. By escaping the quotes they will be passed unmodified to the second level: http-request set-path %[path,regsub(\"(foo|bar)\",blah,g)] ------------ -------- ------------------------------------ word1 word2 word3=%[path,regsub("(foo|bar)",blah,g)] |---------||----|-| arg1=(foo|bar) _/ / / arg2=blah ___________/ / arg3=g _______________/ Another approach consists in using single quotes outside the whole string and double quotes inside (so that the double quotes are not stripped again): http-request set-path '%[path,regsub("(foo|bar)",blah,g)]' ------------ -------- ---------------------------------- word1 word2 word3=%[path,regsub("(foo|bar)",blah,g)] |---------||----|-| arg1=(foo|bar) _/ / / arg2 ___________/ / arg3 _______________/ When using regular expressions, it can happen that the dollar ('$') character appears in the expression or that a backslash ('\') is used in the replacement string. In this case these ones will also be processed inside the double quotes thus single quotes are preferred (or double escaping). Example: http-request set-path '%[path,regsub("^/(here)(/|$)","my/\1",g)]' ------------ -------- ----------------------------------------- word1 word2 word3=%[path,regsub("^/(here)(/|$)","my/\1",g)] |-------------| |-----||-| arg1=(here)(/|$) _/ / / arg2=my/\1 ________________/ / arg3 ______________________/ Remember that backslashes are not escape characters within single quotes and that the whole word above is already protected against them using the single quotes. Conversely, if double quotes had been used around the whole expression, single the dollar character and the backslashes would have been resolved at top level, breaking the argument contents at the second level. Unfortunately, since single quotes can't be escaped inside of strong quoting, if you need to include single quotes in your argument, you will need to escape or quote them twice. There are a few ways to do this: http-request set-var(txn.foo) str("\\'foo\\'") http-request set-var(txn.foo) str(\"\'foo\'\") http-request set-var(txn.foo) str(\\\'foo\\\') When in doubt, simply do not use quotes anywhere, and start to place single or double quotes around arguments that require a comma or a closing parenthesis, and think about escaping these quotes using a backslash if the string contains a dollar or a backslash. Again, this is pretty similar to what is used under a Bourne shell when double-escaping a command passed to "eval". For API writers the best is probably to place escaped quotes around each and every argument, regardless of their contents. Users will probably find that using single quotes around the whole expression and double quotes around each argument provides more readable configurations. 2.3. Environment variables -------------------------- 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 ("$") and optionally enclosed with braces ("{}") similarly to what is done in Bourne shell. Variable names can contain alphanumerical characters or the character underscore ("_") but should not start with a digit. If the variable contains a list of several values separated by spaces, it can be expanded as individual arguments by enclosing the variable with braces and appending the suffix '[*]' before the closing brace. Example: bind "fd@${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. * HAPROXY_STARTUP_VERSION: contains the version used to start, in master-worker mode this is the version which was used to start the master, even after updating the binary and reloading. In addition, some pseudo-variables are internally resolved and may be used as regular variables. Pseudo-variables always start with a dot ('.'), and are the only ones where the dot is permitted. The current list of pseudo-variables is: * .FILE: the name of the configuration file currently being parsed. * .LINE: the line number of the configuration file currently being parsed, starting at one. * .SECTION: the name of the section currently being parsed, or its type if the section doesn't have a name (e.g. "global"), or an empty string before the first section. These variables are resolved at the location where they are parsed. For example if a ".LINE" variable is used in a "log-format" directive located in a defaults section, its line number will be resolved before parsing and compiling the "log-format" directive, so this same line number will be reused by subsequent proxies. This way it is possible to emit information to help locate a rule in variables, logs, error statuses, health checks, header values, or even to use line numbers to name some config objects like servers for example. See also "external-check command" for other variables. 2.4. Conditional blocks ----------------------- It may sometimes be convenient to be able to conditionally enable or disable some arbitrary parts of the configuration, for example to enable/disable SSL or ciphers, enable or disable some pre-production listeners without modifying the configuration, or adjust the configuration's syntax to support two distinct versions of HAProxy during a migration.. HAProxy brings a set of nestable preprocessor-like directives which allow to integrate or ignore some blocks of text. These directives must be placed on their own line and they act on the lines that follow them. Two of them support an expression, the other ones only switch to an alternate block or end a current level. The 4 following directives are defined to form conditional blocks: - .if - .elif - .else - .endif The ".if" directive nests a new level, ".elif" stays at the same level, ".else" as well, and ".endif" closes a level. Each ".if" must be terminated by a matching ".endif". The ".elif" may only be placed after ".if" or ".elif", and there is no limit to the number of ".elif" that may be chained. There may be only one ".else" per ".if" and it must always be after the ".if" or the last ".elif" of a block. Comments may be placed on the same line if needed after a '#', they will be ignored. The directives are tokenized like other configuration directives, and as such it is possible to use environment variables in conditions. The conditions are currently limited to: - an empty string, always returns "false" - the integer zero ('0'), always returns "false" - a non-nul integer (e.g. '1'), always returns "true". - a predicate optionally followed by argument(s) in parenthesis. The list of currently supported predicates is the following: - defined() : returns true if an environment variable exists, regardless of its contents - feature() : returns true if feature is listed as present in the features list reported by "haproxy -vv" (which means a appears after a '+') - streq(,) : returns true only if the two strings are equal - strneq(,) : returns true only if the two strings differ - version_atleast(): returns true if the current haproxy version is at least as recent as otherwise false. The version syntax is the same as shown by "haproxy -v" and missing components are assumed as being zero. - version_before() : returns true if the current haproxy version is strictly older than otherwise false. The version syntax is the same as shown by "haproxy -v" and missing components are assumed as being zero. Example: .if defined(HAPROXY_MWORKER) listen mwcli_px bind :1111 ... .endif .if strneq("$SSL_ONLY",yes) bind :80 .endif .if streq("$WITH_SSL",yes) .if feature(OPENSSL) bind :443 ssl crt ... .endif .endif .if version_atleast(2.4-dev19) profiling.memory on .endif Four other directives are provided to report some status: - .diag "message" : emit this message only when in diagnostic mode (-dD) - .notice "message" : emit this message at level NOTICE - .warning "message" : emit this message at level WARNING - .alert "message" : emit this message at level ALERT Messages emitted at level WARNING may cause the process to fail to start if the "strict-mode" is enabled. Messages emitted at level ALERT will always cause a fatal error. These can be used to detect some inappropriate conditions and provide advice to the user. Example: .if "${A}" .if "${B}" .notice "A=1, B=1" .elif "${C}" .notice "A=1, B=0, C=1" .elif "${D}" .warning "A=1, B=0, C=0, D=1" .else .alert "A=1, B=0, C=0, D=0" .endif .else .notice "A=0" .endif .diag "WTA/2021-05-07: replace 'redirect' with 'return' after switch to 2.4" http-request redirect location /goaway if ABUSE 2.5. Time format ---------------- 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 2.6. Size format ---------------- Some parameters involve values representing size, such as bandwidth limits. These values are generally expressed in bytes (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 case insensitive : - k : kilobytes. 1 kilobyte = 1024 bytes - m : megabytes. 1 megabyte = 1048576 bytes - g : gigabytes. 1 gigabyte = 1073741824 bytes Both time and size formats require integers, decimal notation is not allowed. 2.7. Examples ------------- # 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 3. Global parameters -------------------- 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 - 51degrees-cache-size - 51degrees-data-file - 51degrees-property-name-list - 51degrees-property-separator - ca-base - chroot - cpu-map - crt-base - daemon - default-path - description - deviceatlas-json-file - deviceatlas-log-level - deviceatlas-properties-cookie - deviceatlas-separator - expose-experimental-directives - external-check - gid - group - h1-case-adjust - h1-case-adjust-file - h2-workaround-bogus-websocket-clients - hard-stop-after - insecure-fork-wanted - insecure-setuid-wanted - issuers-chain-path - localpeer - log - log-send-hostname - log-tag - lua-load - lua-load-per-thread - lua-prepend-path - mworker-max-reloads - nbproc - nbthread - node - numa-cpu-mapping - pidfile - pp2-never-send-local - presetenv - resetenv - set-dumpable - set-var - setenv - ssl-default-bind-ciphers - ssl-default-bind-ciphersuites - ssl-default-bind-curves - ssl-default-bind-options - ssl-default-server-ciphers - ssl-default-server-ciphersuites - ssl-default-server-options - ssl-dh-param-file - ssl-server-verify - ssl-skip-self-issued-ca - stats - strict-limits - uid - ulimit-n - unix-bind - unsetenv - user - wurfl-cache-size - wurfl-data-file - wurfl-information-list - wurfl-information-list-separator * Performance tuning - busy-polling - max-spread-checks - maxcompcpuusage - maxcomprate - maxconn - maxconnrate - maxpipes - maxsessrate - maxsslconn - maxsslrate - maxzlibmem - no-memory-trimming - noepoll - noevports - nogetaddrinfo - nokqueue - nopoll - noreuseport - nosplice - profiling.tasks - server-state-base - server-state-file - spread-checks - ssl-engine - ssl-mode-async - tune.buffers.limit - tune.buffers.reserve - tune.bufsize - tune.chksize - tune.comp.maxlevel - tune.fail-alloc - tune.fd.edge-triggered - tune.h2.header-table-size - tune.h2.initial-window-size - tune.h2.max-concurrent-streams - tune.h2.max-frame-size - tune.http.cookielen - tune.http.logurilen - tune.http.maxhdr - tune.idle-pool.shared - tune.idletimer - tune.lua.forced-yield - tune.lua.maxmem - tune.lua.service-timeout - tune.lua.session-timeout - tune.lua.task-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.sched.low-latency - tune.sndbuf.client - tune.sndbuf.server - tune.ssl.cachesize - tune.ssl.capture-cipherlist-size - tune.ssl.default-dh-param - tune.ssl.force-private-cache - tune.ssl.keylog - tune.ssl.lifetime - tune.ssl.maxrecord - tune.ssl.ssl-ctx-cache-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 - quiet - zero-warning 3.1. Process management and security ------------------------------------ 51degrees-data-file 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. 51degrees-property-name-list [ ...] 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. 51degrees-property-separator 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. 51degrees-cache-size Sets the size of the 51Degrees converter cache to 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. ca-base Assigns a default directory to fetch SSL CA certificates and CRLs from when a relative path is used with "ca-file", "ca-verify-file" or "crl-file" directives. Absolute locations specified in "ca-file", "ca-verify-file" and "crl-file" prevail and ignore "ca-base". chroot Changes current directory to 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 is both empty and non-writable to anyone. cpu-map [auto:][/] ... 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]] > 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 starting at 0 for the first CPU or a range with two such numbers delimited by a dash ('-'). Outside of Linux and BSDs, there may be a limitation on the maximum CPU index to either 31 or 63. 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. Examples: 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 crt-base Assigns a default directory to fetch SSL certificates from when a relative path is used with "crtfile" or "crt" directives. Absolute locations specified prevail and ignore "crt-base". daemon 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. default-path { current | config | parent | origin } By default HAProxy loads all files designated by a relative path from the location the process is started in. In some circumstances it might be desirable to force all relative paths to start from a different location just as if the process was started from such locations. This is what this directive is made for. Technically it will perform a temporary chdir() to the designated location while processing each configuration file, and will return to the original directory after processing each file. It takes an argument indicating the policy to use when loading files whose path does not start with a slash ('/'): - "current" indicates that all relative files are to be loaded from the directory the process is started in ; this is the default. - "config" indicates that all relative files should be loaded from the directory containing the configuration file. More specifically, if the configuration file contains a slash ('/'), the longest part up to the last slash is used as the directory to change to, otherwise the current directory is used. This mode is convenient to bundle maps, errorfiles, certificates and Lua scripts together as relocatable packages. When multiple configuration files are loaded, the directory is updated for each of them. - "parent" indicates that all relative files should be loaded from the parent of the directory containing the configuration file. More specifically, if the configuration file contains a slash ('/'), ".." is appended to the longest part up to the last slash is used as the directory to change to, otherwise the directory is "..". This mode is convenient to bundle maps, errorfiles, certificates and Lua scripts together as relocatable packages, but where each part is located in a different subdirectory (e.g. "config/", "certs/", "maps/", ...). - "origin" indicates that all relative files should be loaded from the designated (mandatory) path. This may be used to ease management of different HAProxy instances running in parallel on a system, where each instance uses a different prefix but where the rest of the sections are made easily relocatable. Each "default-path" directive instantly replaces any previous one and will possibly result in switching to a different directory. While this should always result in the desired behavior, it is really not a good practice to use multiple default-path directives, and if used, the policy ought to remain consistent across all configuration files. Warning: some configuration elements such as maps or certificates are uniquely identified by their configured path. By using a relocatable layout, it becomes possible for several of them to end up with the same unique name, making it difficult to update them at run time, especially when multiple configuration files are loaded from different directories. It is essential to observe a strict collision-free file naming scheme before adopting relative paths. A robust approach could consist in prefixing all files names with their respective site name, or in doing so at the directory level. description 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. deviceatlas-json-file 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. deviceatlas-log-level Sets the level of information returned by the API. This directive is optional and set to 0 by default if not set. deviceatlas-properties-cookie 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. deviceatlas-separator Sets the character separator for the API properties results. This directive is optional and set to | by default if not set. expose-experimental-directives This statement must appear before using directives tagged as experimental or the config file will be rejected. external-check Allows the use of an external agent to perform health checks. This is disabled by default as a security precaution, and even when enabled, checks may still fail unless "insecure-fork-wanted" is enabled as well. If the program launched makes use of a setuid executable (it should really not), you may also need to set "insecure-setuid-wanted" in the global section. See "option external-check", and "insecure-fork-wanted", and "insecure-setuid-wanted". gid Changes the process's group ID to . 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". group Similar to "gid" but uses the GID of group name from /etc/group. See also "gid" and "user". h1-case-adjust Defines the case adjustment to apply, when enabled, to the header name , to change it to before sending it to HTTP/1 clients or servers. must be in lower case, and and 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. Example: 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". h1-case-adjust-file 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 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". h2-workaround-bogus-websocket-clients This disables the announcement of the support for h2 websockets to clients. This can be use to overcome clients which have issues when implementing the relatively fresh RFC8441, such as Firefox 88. To allow clients to automatically downgrade to http/1.1 for the websocket tunnel, specify h2 support on the bind line using "alpn" without an explicit "proto" keyword. If this statement was previously activated, this can be disabled by prefixing the keyword with "no'. hard-stop-after