| 2020/03/05 Willy Tarreau |
| HAProxy Technologies |
| The PROXY protocol |
| Versions 1 & 2 |
| |
| Abstract |
| |
| The PROXY protocol provides a convenient way to safely transport connection |
| information such as a client's address across multiple layers of NAT or TCP |
| proxies. It is designed to require little changes to existing components and |
| to limit the performance impact caused by the processing of the transported |
| information. |
| |
| |
| Revision history |
| |
| 2010/10/29 - first version |
| 2011/03/20 - update: implementation and security considerations |
| 2012/06/21 - add support for binary format |
| 2012/11/19 - final review and fixes |
| 2014/05/18 - modify and extend PROXY protocol version 2 |
| 2014/06/11 - fix example code to consider ver+cmd merge |
| 2014/06/14 - fix v2 header check in example code, and update Forwarded spec |
| 2014/07/12 - update list of implementations (add Squid) |
| 2015/05/02 - update list of implementations and format of the TLV add-ons |
| 2017/03/10 - added the checksum, noop and more SSL-related TLV types, |
| reserved TLV type ranges, added TLV documentation, clarified |
| string encoding. With contributions from Andriy Palamarchuk |
| (Amazon.com). |
| 2020/03/05 - added the unique ID TLV type (Tim Düsterhus) |
| |
| |
| 1. Background |
| |
| Relaying TCP connections through proxies generally involves a loss of the |
| original TCP connection parameters such as source and destination addresses, |
| ports, and so on. Some protocols make it a little bit easier to transfer such |
| information. For SMTP, Postfix authors have proposed the XCLIENT protocol [1] |
| which received broad adoption and is particularly suited to mail exchanges. |
| For HTTP, there is the "Forwarded" extension [2], which aims at replacing the |
| omnipresent "X-Forwarded-For" header which carries information about the |
| original source address, and the less common X-Original-To which carries |
| information about the destination address. |
| |
| However, both mechanisms require a knowledge of the underlying protocol to be |
| implemented in intermediaries. |
| |
| Then comes a new class of products which we'll call "dumb proxies", not because |
| they don't do anything, but because they're processing protocol-agnostic data. |
| Both Stunnel[3] and Stud[4] are examples of such "dumb proxies". They talk raw |
| TCP on one side, and raw SSL on the other one, and do that reliably, without |
| any knowledge of what protocol is transported on top of the connection. HAProxy |
| running in pure TCP mode obviously falls into that category as well. |
| |
| The problem with such a proxy when it is combined with another one such as |
| haproxy, is to adapt it to talk the higher level protocol. A patch is available |
| for Stunnel to make it capable of inserting an X-Forwarded-For header in the |
| first HTTP request of each incoming connection. HAProxy is able not to add |
| another one when the connection comes from Stunnel, so that it's possible to |
| hide it from the servers. |
| |
| The typical architecture becomes the following one : |
| |
| |
| +--------+ HTTP :80 +----------+ |
| | client | --------------------------------> | | |
| | | | haproxy, | |
| +--------+ +---------+ | 1 or 2 | |
| / / HTTPS | stunnel | HTTP :81 | listening| |
| <________/ ---------> | (server | ---------> | ports | |
| | mode) | | | |
| +---------+ +----------+ |
| |
| |
| The problem appears when haproxy runs with keep-alive on the side towards the |
| client. The Stunnel patch will only add the X-Forwarded-For header to the first |
| request of each connection and all subsequent requests will not have it. One |
| solution could be to improve the patch to make it support keep-alive and parse |
| all forwarded data, whether they're announced with a Content-Length or with a |
| Transfer-Encoding, taking care of special methods such as HEAD which announce |
| data without transferring them, etc... In fact, it would require implementing a |
| full HTTP stack in Stunnel. It would then become a lot more complex, a lot less |
| reliable and would not anymore be the "dumb proxy" that fits every purposes. |
| |
| In practice, we don't need to add a header for each request because we'll emit |
| the exact same information every time : the information related to the client |
| side connection. We could then cache that information in haproxy and use it for |
| every other request. But that becomes dangerous and is still limited to HTTP |
| only. |
| |
| Another approach consists in prepending each connection with a header reporting |
| the characteristics of the other side's connection. This method is simpler to |
| implement, does not require any protocol-specific knowledge on either side, and |
| completely fits the purpose since what is desired precisely is to know the |
| other side's connection endpoints. It is easy to perform for the sender (just |
| send a short header once the connection is established) and to parse for the |
| receiver (simply perform one read() on the incoming connection to fill in |
| addresses after an accept). The protocol used to carry connection information |
| across proxies was thus called the PROXY protocol. |
| |
| |
| 2. The PROXY protocol header |
| |
| This document uses a few terms that are worth explaining here : |
| - "connection initiator" is the party requesting a new connection |
| - "connection target" is the party accepting a connection request |
| - "client" is the party for which a connection was requested |
| - "server" is the party to which the client desired to connect |
| - "proxy" is the party intercepting and relaying the connection |
| from the client to the server. |
| - "sender" is the party sending data over a connection. |
| - "receiver" is the party receiving data from the sender. |
| - "header" or "PROXY protocol header" is the block of connection information |
| the connection initiator prepends at the beginning of a connection, which |
| makes it the sender from the protocol point of view. |
| |
| The PROXY protocol's goal is to fill the server's internal structures with the |
| information collected by the proxy that the server would have been able to get |
| by itself if the client was connecting directly to the server instead of via a |
| proxy. The information carried by the protocol are the ones the server would |
| get using getsockname() and getpeername() : |
| - address family (AF_INET for IPv4, AF_INET6 for IPv6, AF_UNIX) |
| - socket protocol (SOCK_STREAM for TCP, SOCK_DGRAM for UDP) |
| - layer 3 source and destination addresses |
| - layer 4 source and destination ports if any |
| |
| Unlike the XCLIENT protocol, the PROXY protocol was designed with limited |
| extensibility in order to help the receiver parse it very fast. Version 1 was |
| focused on keeping it human-readable for better debugging possibilities, which |
| is always desirable for early adoption when few implementations exist. Version |
| 2 adds support for a binary encoding of the header which is much more efficient |
| to produce and to parse, especially when dealing with IPv6 addresses that are |
| expensive to emit in ASCII form and to parse. |
| |
| In both cases, the protocol simply consists in an easily parsable header placed |
| by the connection initiator at the beginning of each connection. The protocol |
| is intentionally stateless in that it does not expect the sender to wait for |
| the receiver before sending the header, nor the receiver to send anything back. |
| |
| This specification supports two header formats, a human-readable format which |
| is the only format supported in version 1 of the protocol, and a binary format |
| which is only supported in version 2. Both formats were designed to ensure that |
| the header cannot be confused with common higher level protocols such as HTTP, |
| SSL/TLS, FTP or SMTP, and that both formats are easily distinguishable one from |
| each other for the receiver. |
| |
| Version 1 senders MAY only produce the human-readable header format. Version 2 |
| senders MAY only produce the binary header format. Version 1 receivers MUST at |
| least implement the human-readable header format. Version 2 receivers MUST at |
| least implement the binary header format, and it is recommended that they also |
| implement the human-readable header format for better interoperability and ease |
| of upgrade when facing version 1 senders. |
| |
| Both formats are designed to fit in the smallest TCP segment that any TCP/IP |
| host is required to support (576 - 40 = 536 bytes). This ensures that the whole |
| header will always be delivered at once when the socket buffers are still empty |
| at the beginning of a connection. The sender must always ensure that the header |
| is sent at once, so that the transport layer maintains atomicity along the path |
| to the receiver. The receiver may be tolerant to partial headers or may simply |
| drop the connection when receiving a partial header. Recommendation is to be |
| tolerant, but implementation constraints may not always easily permit this. It |
| is important to note that nothing forces any intermediary to forward the whole |
| header at once, because TCP is a streaming protocol which may be processed one |
| byte at a time if desired, causing the header to be fragmented when reaching |
| the receiver. But due to the places where such a protocol is used, the above |
| simplification generally is acceptable because the risk of crossing such a |
| device handling one byte at a time is close to zero. |
| |
| The receiver MUST NOT start processing the connection before it receives a |
| complete and valid PROXY protocol header. This is particularly important for |
| protocols where the receiver is expected to speak first (eg: SMTP, FTP or SSH). |
| The receiver may apply a short timeout and decide to abort the connection if |
| the protocol header is not seen within a few seconds (at least 3 seconds to |
| cover a TCP retransmit). |
| |
| The receiver MUST be configured to only receive the protocol described in this |
| specification and MUST not try to guess whether the protocol header is present |
| or not. This means that the protocol explicitly prevents port sharing between |
| public and private access. Otherwise it would open a major security breach by |
| allowing untrusted parties to spoof their connection addresses. The receiver |
| SHOULD ensure proper access filtering so that only trusted proxies are allowed |
| to use this protocol. |
| |
| Some proxies are smart enough to understand transported protocols and to reuse |
| idle server connections for multiple messages. This typically happens in HTTP |
| where requests from multiple clients may be sent over the same connection. Such |
| proxies MUST NOT implement this protocol on multiplexed connections because the |
| receiver would use the address advertised in the PROXY header as the address of |
| all forwarded requests's senders. In fact, such proxies are not dumb proxies, |
| and since they do have a complete understanding of the transported protocol, |
| they MUST use the facilities provided by this protocol to present the client's |
| address. |
| |
| |
| 2.1. Human-readable header format (Version 1) |
| |
| This is the format specified in version 1 of the protocol. It consists in one |
| line of US-ASCII text matching exactly the following block, sent immediately |
| and at once upon the connection establishment and prepended before any data |
| flowing from the sender to the receiver : |
| |
| - a string identifying the protocol : "PROXY" ( \x50 \x52 \x4F \x58 \x59 ) |
| Seeing this string indicates that this is version 1 of the protocol. |
| |
| - exactly one space : " " ( \x20 ) |
| |
| - a string indicating the proxied INET protocol and family. As of version 1, |
| only "TCP4" ( \x54 \x43 \x50 \x34 ) for TCP over IPv4, and "TCP6" |
| ( \x54 \x43 \x50 \x36 ) for TCP over IPv6 are allowed. Other, unsupported, |
| or unknown protocols must be reported with the name "UNKNOWN" ( \x55 \x4E |
| \x4B \x4E \x4F \x57 \x4E ). For "UNKNOWN", the rest of the line before the |
| CRLF may be omitted by the sender, and the receiver must ignore anything |
| presented before the CRLF is found. Note that an earlier version of this |
| specification suggested to use this when sending health checks, but this |
| causes issues with servers that reject the "UNKNOWN" keyword. Thus is it |
| now recommended not to send "UNKNOWN" when the connection is expected to |
| be accepted, but only when it is not possible to correctly fill the PROXY |
| line. |
| |
| - exactly one space : " " ( \x20 ) |
| |
| - the layer 3 source address in its canonical format. IPv4 addresses must be |
| indicated as a series of exactly 4 integers in the range [0..255] inclusive |
| written in decimal representation separated by exactly one dot between each |
| other. Heading zeroes are not permitted in front of numbers in order to |
| avoid any possible confusion with octal numbers. IPv6 addresses must be |
| indicated as series of sets of 4 hexadecimal digits (upper or lower case) |
| delimited by colons between each other, with the acceptance of one double |
| colon sequence to replace the largest acceptable range of consecutive |
| zeroes. The total number of decoded bits must exactly be 128. The |
| advertised protocol family dictates what format to use. |
| |
| - exactly one space : " " ( \x20 ) |
| |
| - the layer 3 destination address in its canonical format. It is the same |
| format as the layer 3 source address and matches the same family. |
| |
| - exactly one space : " " ( \x20 ) |
| |
| - the TCP source port represented as a decimal integer in the range |
| [0..65535] inclusive. Heading zeroes are not permitted in front of numbers |
| in order to avoid any possible confusion with octal numbers. |
| |
| - exactly one space : " " ( \x20 ) |
| |
| - the TCP destination port represented as a decimal integer in the range |
| [0..65535] inclusive. Heading zeroes are not permitted in front of numbers |
| in order to avoid any possible confusion with octal numbers. |
| |
| - the CRLF sequence ( \x0D \x0A ) |
| |
| |
| The maximum line lengths the receiver must support including the CRLF are : |
| - TCP/IPv4 : |
| "PROXY TCP4 255.255.255.255 255.255.255.255 65535 65535\r\n" |
| => 5 + 1 + 4 + 1 + 15 + 1 + 15 + 1 + 5 + 1 + 5 + 2 = 56 chars |
| |
| - TCP/IPv6 : |
| "PROXY TCP6 ffff:f...f:ffff ffff:f...f:ffff 65535 65535\r\n" |
| => 5 + 1 + 4 + 1 + 39 + 1 + 39 + 1 + 5 + 1 + 5 + 2 = 104 chars |
| |
| - unknown connection (short form) : |
| "PROXY UNKNOWN\r\n" |
| => 5 + 1 + 7 + 2 = 15 chars |
| |
| - worst case (optional fields set to 0xff) : |
| "PROXY UNKNOWN ffff:f...f:ffff ffff:f...f:ffff 65535 65535\r\n" |
| => 5 + 1 + 7 + 1 + 39 + 1 + 39 + 1 + 5 + 1 + 5 + 2 = 107 chars |
| |
| So a 108-byte buffer is always enough to store all the line and a trailing zero |
| for string processing. |
| |
| The receiver must wait for the CRLF sequence before starting to decode the |
| addresses in order to ensure they are complete and properly parsed. If the CRLF |
| sequence is not found in the first 107 characters, the receiver should declare |
| the line invalid. A receiver may reject an incomplete line which does not |
| contain the CRLF sequence in the first atomic read operation. The receiver must |
| not tolerate a single CR or LF character to end the line when a complete CRLF |
| sequence is expected. |
| |
| Any sequence which does not exactly match the protocol must be discarded and |
| cause the receiver to abort the connection. It is recommended to abort the |
| connection as soon as possible so that the sender gets a chance to notice the |
| anomaly and log it. |
| |
| If the announced transport protocol is "UNKNOWN", then the receiver knows that |
| the sender speaks the correct PROXY protocol with the appropriate version, and |
| SHOULD accept the connection and use the real connection's parameters as if |
| there were no PROXY protocol header on the wire. However, senders SHOULD not |
| use the "UNKNOWN" protocol when they are the initiators of outgoing connections |
| because some receivers may reject them. When a load balancing proxy has to send |
| health checks to a server, it SHOULD build a valid PROXY line which it will |
| fill with a getsockname()/getpeername() pair indicating the addresses used. It |
| is important to understand that doing so is not appropriate when some source |
| address translation is performed between the sender and the receiver. |
| |
| An example of such a line before an HTTP request would look like this (CR |
| marked as "\r" and LF marked as "\n") : |
| |
| PROXY TCP4 192.168.0.1 192.168.0.11 56324 443\r\n |
| GET / HTTP/1.1\r\n |
| Host: 192.168.0.11\r\n |
| \r\n |
| |
| For the sender, the header line is easy to put into the output buffers once the |
| connection is established. Note that since the line is always shorter than an |
| MSS, the sender is guaranteed to always be able to emit it at once and should |
| not even bother handling partial sends. For the receiver, once the header is |
| parsed, it is easy to skip it from the input buffers. Please consult section 9 |
| for implementation suggestions. |
| |
| |
| 2.2. Binary header format (version 2) |
| |
| Producing human-readable IPv6 addresses and parsing them is very inefficient, |
| due to the multiple possible representation formats and the handling of compact |
| address format. It was also not possible to specify address families outside |
| IPv4/IPv6 nor non-TCP protocols. Another drawback of the human-readable format |
| is the fact that implementations need to parse all characters to find the |
| trailing CRLF, which makes it harder to read only the exact bytes count. Last, |
| the UNKNOWN address type has not always been accepted by servers as a valid |
| protocol because of its imprecise meaning. |
| |
| Version 2 of the protocol thus introduces a new binary format which remains |
| distinguishable from version 1 and from other commonly used protocols. It was |
| specially designed in order to be incompatible with a wide range of protocols |
| and to be rejected by a number of common implementations of these protocols |
| when unexpectedly presented (please see section 7). Also for better processing |
| efficiency, IPv4 and IPv6 addresses are respectively aligned on 4 and 16 bytes |
| boundaries. |
| |
| The binary header format starts with a constant 12 bytes block containing the |
| protocol signature : |
| |
| \x0D \x0A \x0D \x0A \x00 \x0D \x0A \x51 \x55 \x49 \x54 \x0A |
| |
| Note that this block contains a null byte at the 5th position, so it must not |
| be handled as a null-terminated string. |
| |
| The next byte (the 13th one) is the protocol version and command. |
| |
| The highest four bits contains the version. As of this specification, it must |
| always be sent as \x2 and the receiver must only accept this value. |
| |
| The lowest four bits represents the command : |
| - \x0 : LOCAL : the connection was established on purpose by the proxy |
| without being relayed. The connection endpoints are the sender and the |
| receiver. Such connections exist when the proxy sends health-checks to the |
| server. The receiver must accept this connection as valid and must use the |
| real connection endpoints and discard the protocol block including the |
| family which is ignored. |
| |
| - \x1 : PROXY : the connection was established on behalf of another node, |
| and reflects the original connection endpoints. The receiver must then use |
| the information provided in the protocol block to get original the address. |
| |
| - other values are unassigned and must not be emitted by senders. Receivers |
| must drop connections presenting unexpected values here. |
| |
| The 14th byte contains the transport protocol and address family. The highest 4 |
| bits contain the address family, the lowest 4 bits contain the protocol. |
| |
| The address family maps to the original socket family without necessarily |
| matching the values internally used by the system. It may be one of : |
| |
| - 0x0 : AF_UNSPEC : the connection is forwarded for an unknown, unspecified |
| or unsupported protocol. The sender should use this family when sending |
| LOCAL commands or when dealing with unsupported protocol families. The |
| receiver is free to accept the connection anyway and use the real endpoint |
| addresses or to reject it. The receiver should ignore address information. |
| |
| - 0x1 : AF_INET : the forwarded connection uses the AF_INET address family |
| (IPv4). The addresses are exactly 4 bytes each in network byte order, |
| followed by transport protocol information (typically ports). |
| |
| - 0x2 : AF_INET6 : the forwarded connection uses the AF_INET6 address family |
| (IPv6). The addresses are exactly 16 bytes each in network byte order, |
| followed by transport protocol information (typically ports). |
| |
| - 0x3 : AF_UNIX : the forwarded connection uses the AF_UNIX address family |
| (UNIX). The addresses are exactly 108 bytes each. |
| |
| - other values are unspecified and must not be emitted in version 2 of this |
| protocol and must be rejected as invalid by receivers. |
| |
| The transport protocol is specified in the lowest 4 bits of the 14th byte : |
| |
| - 0x0 : UNSPEC : the connection is forwarded for an unknown, unspecified |
| or unsupported protocol. The sender should use this family when sending |
| LOCAL commands or when dealing with unsupported protocol families. The |
| receiver is free to accept the connection anyway and use the real endpoint |
| addresses or to reject it. The receiver should ignore address information. |
| |
| - 0x1 : STREAM : the forwarded connection uses a SOCK_STREAM protocol (eg: |
| TCP or UNIX_STREAM). When used with AF_INET/AF_INET6 (TCP), the addresses |
| are followed by the source and destination ports represented on 2 bytes |
| each in network byte order. |
| |
| - 0x2 : DGRAM : the forwarded connection uses a SOCK_DGRAM protocol (eg: |
| UDP or UNIX_DGRAM). When used with AF_INET/AF_INET6 (UDP), the addresses |
| are followed by the source and destination ports represented on 2 bytes |
| each in network byte order. |
| |
| - other values are unspecified and must not be emitted in version 2 of this |
| protocol and must be rejected as invalid by receivers. |
| |
| In practice, the following protocol bytes are expected : |
| |
| - \x00 : UNSPEC : the connection is forwarded for an unknown, unspecified |
| or unsupported protocol. The sender should use this family when sending |
| LOCAL commands or when dealing with unsupported protocol families. When |
| used with a LOCAL command, the receiver must accept the connection and |
| ignore any address information. For other commands, the receiver is free |
| to accept the connection anyway and use the real endpoints addresses or to |
| reject the connection. The receiver should ignore address information. |
| |
| - \x11 : TCP over IPv4 : the forwarded connection uses TCP over the AF_INET |
| protocol family. Address length is 2*4 + 2*2 = 12 bytes. |
| |
| - \x12 : UDP over IPv4 : the forwarded connection uses UDP over the AF_INET |
| protocol family. Address length is 2*4 + 2*2 = 12 bytes. |
| |
| - \x21 : TCP over IPv6 : the forwarded connection uses TCP over the AF_INET6 |
| protocol family. Address length is 2*16 + 2*2 = 36 bytes. |
| |
| - \x22 : UDP over IPv6 : the forwarded connection uses UDP over the AF_INET6 |
| protocol family. Address length is 2*16 + 2*2 = 36 bytes. |
| |
| - \x31 : UNIX stream : the forwarded connection uses SOCK_STREAM over the |
| AF_UNIX protocol family. Address length is 2*108 = 216 bytes. |
| |
| - \x32 : UNIX datagram : the forwarded connection uses SOCK_DGRAM over the |
| AF_UNIX protocol family. Address length is 2*108 = 216 bytes. |
| |
| |
| Only the UNSPEC protocol byte (\x00) is mandatory to implement on the receiver. |
| A receiver is not required to implement other ones, provided that it |
| automatically falls back to the UNSPEC mode for the valid combinations above |
| that it does not support. |
| |
| The 15th and 16th bytes is the address length in bytes in network endian order. |
| It is used so that the receiver knows how many address bytes to skip even when |
| it does not implement the presented protocol. Thus the length of the protocol |
| header in bytes is always exactly 16 + this value. When a sender presents a |
| LOCAL connection, it should not present any address so it sets this field to |
| zero. Receivers MUST always consider this field to skip the appropriate number |
| of bytes and must not assume zero is presented for LOCAL connections. When a |
| receiver accepts an incoming connection showing an UNSPEC address family or |
| protocol, it may or may not decide to log the address information if present. |
| |
| So the 16-byte version 2 header can be described this way : |
| |
| struct proxy_hdr_v2 { |
| uint8_t sig[12]; /* hex 0D 0A 0D 0A 00 0D 0A 51 55 49 54 0A */ |
| uint8_t ver_cmd; /* protocol version and command */ |
| uint8_t fam; /* protocol family and address */ |
| uint16_t len; /* number of following bytes part of the header */ |
| }; |
| |
| Starting from the 17th byte, addresses are presented in network byte order. |
| The address order is always the same : |
| - source layer 3 address in network byte order |
| - destination layer 3 address in network byte order |
| - source layer 4 address if any, in network byte order (port) |
| - destination layer 4 address if any, in network byte order (port) |
| |
| The address block may directly be sent from or received into the following |
| union which makes it easy to cast from/to the relevant socket native structs |
| depending on the address type : |
| |
| union proxy_addr { |
| struct { /* for TCP/UDP over IPv4, len = 12 */ |
| uint32_t src_addr; |
| uint32_t dst_addr; |
| uint16_t src_port; |
| uint16_t dst_port; |
| } ipv4_addr; |
| struct { /* for TCP/UDP over IPv6, len = 36 */ |
| uint8_t src_addr[16]; |
| uint8_t dst_addr[16]; |
| uint16_t src_port; |
| uint16_t dst_port; |
| } ipv6_addr; |
| struct { /* for AF_UNIX sockets, len = 216 */ |
| uint8_t src_addr[108]; |
| uint8_t dst_addr[108]; |
| } unix_addr; |
| }; |
| |
| The sender must ensure that all the protocol header is sent at once. This block |
| is always smaller than an MSS, so there is no reason for it to be segmented at |
| the beginning of the connection. The receiver should also process the header |
| at once. The receiver must not start to parse an address before the whole |
| address block is received. The receiver must also reject incoming connections |
| containing partial protocol headers. |
| |
| A receiver may be configured to support both version 1 and version 2 of the |
| protocol. Identifying the protocol version is easy : |
| |
| - if the incoming byte count is 16 or above and the 13 first bytes match |
| the protocol signature block followed by the protocol version 2 : |
| |
| \x0D\x0A\x0D\x0A\x00\x0D\x0A\x51\x55\x49\x54\x0A\x20 |
| |
| - otherwise, if the incoming byte count is 8 or above, and the 5 first |
| characters match the US-ASCII representation of "PROXY" then the protocol |
| must be parsed as version 1 : |
| |
| \x50\x52\x4F\x58\x59 |
| |
| - otherwise the protocol is not covered by this specification and the |
| connection must be dropped. |
| |
| If the length specified in the PROXY protocol header indicates that additional |
| bytes are part of the header beyond the address information, a receiver may |
| choose to skip over and ignore those bytes, or attempt to interpret those |
| bytes. |
| |
| The information in those bytes will be arranged in Type-Length-Value (TLV |
| vectors) in the following format. The first byte is the Type of the vector. |
| The second two bytes represent the length in bytes of the value (not included |
| the Type and Length bytes), and following the length field is the number of |
| bytes specified by the length. |
| |
| struct pp2_tlv { |
| uint8_t type; |
| uint8_t length_hi; |
| uint8_t length_lo; |
| uint8_t value[0]; |
| }; |
| |
| A receiver may choose to skip over and ignore the TLVs it is not interested in |
| or it does not understand. Senders can generate the TLVs only for |
| the information they choose to publish. |
| |
| The following types have already been registered for the <type> field : |
| |
| #define PP2_TYPE_ALPN 0x01 |
| #define PP2_TYPE_AUTHORITY 0x02 |
| #define PP2_TYPE_CRC32C 0x03 |
| #define PP2_TYPE_NOOP 0x04 |
| #define PP2_TYPE_UNIQUE_ID 0x05 |
| #define PP2_TYPE_SSL 0x20 |
| #define PP2_SUBTYPE_SSL_VERSION 0x21 |
| #define PP2_SUBTYPE_SSL_CN 0x22 |
| #define PP2_SUBTYPE_SSL_CIPHER 0x23 |
| #define PP2_SUBTYPE_SSL_SIG_ALG 0x24 |
| #define PP2_SUBTYPE_SSL_KEY_ALG 0x25 |
| #define PP2_TYPE_NETNS 0x30 |
| |
| |
| 2.2.1 PP2_TYPE_ALPN |
| |
| Application-Layer Protocol Negotiation (ALPN). It is a byte sequence defining |
| the upper layer protocol in use over the connection. The most common use case |
| will be to pass the exact copy of the ALPN extension of the Transport Layer |
| Security (TLS) protocol as defined by RFC7301 [9]. |
| |
| |
| 2.2.2 PP2_TYPE_AUTHORITY |
| |
| Contains the host name value passed by the client, as an UTF8-encoded string. |
| In case of TLS being used on the client connection, this is the exact copy of |
| the "server_name" extension as defined by RFC3546 [10], section 3.1, often |
| referred to as "SNI". There are probably other situations where an authority |
| can be mentioned on a connection without TLS being involved at all. |
| |
| |
| 2.2.3. PP2_TYPE_CRC32C |
| |
| The value of the type PP2_TYPE_CRC32C is a 32-bit number storing the CRC32c |
| checksum of the PROXY protocol header. |
| |
| When the checksum is supported by the sender after constructing the header |
| the sender MUST: |
| |
| - initialize the checksum field to '0's. |
| |
| - calculate the CRC32c checksum of the PROXY header as described in RFC4960, |
| Appendix B [8]. |
| |
| - put the resultant value into the checksum field, and leave the rest of |
| the bits unchanged. |
| |
| If the checksum is provided as part of the PROXY header and the checksum |
| functionality is supported by the receiver, the receiver MUST: |
| |
| - store the received CRC32c checksum value aside. |
| |
| - replace the 32 bits of the checksum field in the received PROXY header with |
| all '0's and calculate a CRC32c checksum value of the whole PROXY header. |
| |
| - verify that the calculated CRC32c checksum is the same as the received |
| CRC32c checksum. If it is not, the receiver MUST treat the TCP connection |
| providing the header as invalid. |
| |
| The default procedure for handling an invalid TCP connection is to abort it. |
| |
| |
| 2.2.4. PP2_TYPE_NOOP |
| |
| The TLV of this type should be ignored when parsed. The value is zero or more |
| bytes. Can be used for data padding or alignment. Note that it can be used |
| to align only by 3 or more bytes because a TLV can not be smaller than that. |
| |
| |
| 2.2.5. PP2_TYPE_UNIQUE_ID |
| |
| The value of the type PP2_TYPE_UNIQUE_ID is an opaque byte sequence of up to |
| 128 bytes generated by the upstream proxy that uniquely identifies the |
| connection. |
| |
| The unique ID can be used to easily correlate connections across multiple |
| layers of proxies, without needing to look up IP addresses and port numbers. |
| |
| |
| 2.2.6. The PP2_TYPE_SSL type and subtypes |
| |
| For the type PP2_TYPE_SSL, the value is itself a defined like this : |
| |
| struct pp2_tlv_ssl { |
| uint8_t client; |
| uint32_t verify; |
| struct pp2_tlv sub_tlv[0]; |
| }; |
| |
| The <verify> field will be zero if the client presented a certificate |
| and it was successfully verified, and non-zero otherwise. |
| |
| The <client> field is made of a bit field from the following values, |
| indicating which element is present : |
| |
| #define PP2_CLIENT_SSL 0x01 |
| #define PP2_CLIENT_CERT_CONN 0x02 |
| #define PP2_CLIENT_CERT_SESS 0x04 |
| |
| Note, that each of these elements may lead to extra data being appended to |
| this TLV using a second level of TLV encapsulation. It is thus possible to |
| find multiple TLV values after this field. The total length of the pp2_tlv_ssl |
| TLV will reflect this. |
| |
| The PP2_CLIENT_SSL flag indicates that the client connected over SSL/TLS. When |
| this field is present, the US-ASCII string representation of the TLS version is |
| appended at the end of the field in the TLV format using the type |
| PP2_SUBTYPE_SSL_VERSION. |
| |
| PP2_CLIENT_CERT_CONN indicates that the client provided a certificate over the |
| current connection. PP2_CLIENT_CERT_SESS indicates that the client provided a |
| certificate at least once over the TLS session this connection belongs to. |
| |
| The second level TLV PP2_SUBTYPE_SSL_CIPHER provides the US-ASCII string name |
| of the used cipher, for example "ECDHE-RSA-AES128-GCM-SHA256". |
| |
| The second level TLV PP2_SUBTYPE_SSL_SIG_ALG provides the US-ASCII string 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, for example |
| "SHA256". |
| |
| The second level TLV PP2_SUBTYPE_SSL_KEY_ALG provides the US-ASCII string 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, |
| for example "RSA2048". |
| |
| In all cases, the string representation (in UTF8) of the Common Name field |
| (OID: 2.5.4.3) of the client certificate's Distinguished Name, is appended |
| using the TLV format and the type PP2_SUBTYPE_SSL_CN. E.g. "example.com". |
| |
| |
| 2.2.7. The PP2_TYPE_NETNS type |
| |
| The type PP2_TYPE_NETNS defines the value as the US-ASCII string representation |
| of the namespace's name. |
| |
| |
| 2.2.8. Reserved type ranges |
| |
| The following range of 16 type values is reserved for application-specific |
| data and will be never used by the PROXY Protocol. If you need more values |
| consider extending the range with a type field in your TLVs. |
| |
| #define PP2_TYPE_MIN_CUSTOM 0xE0 |
| #define PP2_TYPE_MAX_CUSTOM 0xEF |
| |
| This range of 8 values is reserved for temporary experimental use by |
| application developers and protocol designers. The values from the range will |
| never be used by the PROXY protocol and should not be used by production |
| functionality. |
| |
| #define PP2_TYPE_MIN_EXPERIMENT 0xF0 |
| #define PP2_TYPE_MAX_EXPERIMENT 0xF7 |
| |
| The following range of 8 values is reserved for future use, potentially to |
| extend the protocol with multibyte type values. |
| |
| #define PP2_TYPE_MIN_FUTURE 0xF8 |
| #define PP2_TYPE_MAX_FUTURE 0xFF |
| |
| |
| 3. Implementations |
| |
| HAProxy 1.5 implements version 1 of the PROXY protocol on both sides : |
| - the listening sockets accept the protocol when the "accept-proxy" setting |
| is passed to the "bind" keyword. Connections accepted on such listeners |
| will behave just as if the source really was the one advertised in the |
| protocol. This is true for logging, ACLs, content filtering, transparent |
| proxying, etc... |
| |
| - the protocol may be used to connect to servers if the "send-proxy" setting |
| is present on the "server" line. It is enabled on a per-server basis, so it |
| is possible to have it enabled for remote servers only and still have local |
| ones behave differently. If the incoming connection was accepted with the |
| "accept-proxy", then the relayed information is the one advertised in this |
| connection's PROXY line. |
| |
| - HAProxy 1.5 also implements version 2 of the PROXY protocol as a sender. In |
| addition, a TLV with limited, optional, SSL information has been added. |
| |
| Stunnel added support for version 1 of the protocol for outgoing connections in |
| version 4.45. |
| |
| Stud added support for version 1 of the protocol for outgoing connections on |
| 2011/06/29. |
| |
| Postfix added support for version 1 of the protocol for incoming connections |
| in smtpd and postscreen in version 2.10. |
| |
| A patch is available for Stud[5] to implement version 1 of the protocol on |
| incoming connections. |
| |
| Support for versions 1 and 2 of the protocol was added to Varnish 4.1 [6]. |
| |
| Exim added support for version 1 and version 2 of the protocol for incoming |
| connections on 2014/05/13, and will be released as part of version 4.83. |
| |
| Squid added support for versions 1 and 2 of the protocol in version 3.5 [7]. |
| |
| Jetty 9.3.0 supports protocol version 1. |
| |
| lighttpd added support for versions 1 and 2 of the protocol for incoming |
| connections in version 1.4.46 [11]. |
| |
| The protocol is simple enough that it is expected that other implementations |
| will appear, especially in environments such as SMTP, IMAP, FTP, RDP where the |
| client's address is an important piece of information for the server and some |
| intermediaries. In fact, several proprietary deployments have already done so |
| on FTP and SMTP servers. |
| |
| Proxy developers are encouraged to implement this protocol, because it will |
| make their products much more transparent in complex infrastructures, and will |
| get rid of a number of issues related to logging and access control. |
| |
| |
| 4. Architectural benefits |
| 4.1. Multiple layers |
| |
| Using the PROXY protocol instead of transparent proxy provides several benefits |
| in multiple-layer infrastructures. The first immediate benefit is that it |
| becomes possible to chain multiple layers of proxies and always present the |
| original IP address. for instance, let's consider the following 2-layer proxy |
| architecture : |
| |
| Internet |
| ,---. | client to PX1: |
| ( X ) | native protocol |
| `---' | |
| | V |
| +--+--+ +-----+ |
| | FW1 |------| PX1 | |
| +--+--+ +-----+ | PX1 to PX2: PROXY + native |
| | V |
| +--+--+ +-----+ |
| | FW2 |------| PX2 | |
| +--+--+ +-----+ | PX2 to SRV: PROXY + native |
| | V |
| +--+--+ |
| | SRV | |
| +-----+ |
| |
| Firewall FW1 receives traffic from internet-based clients and forwards it to |
| reverse-proxy PX1. PX1 adds a PROXY header then forwards to PX2 via FW2. PX2 |
| is configured to read the PROXY header and to emit it on output. It then joins |
| the origin server SRV and presents the original client's address there. Since |
| all TCP connections endpoints are real machines and are not spoofed, there is |
| no issue for the return traffic to pass via the firewalls and reverse proxies. |
| Using transparent proxy, this would be quite difficult because the firewalls |
| would have to deal with the client's address coming from the proxies in the DMZ |
| and would have to correctly route the return traffic there instead of using the |
| default route. |
| |
| |
| 4.2. IPv4 and IPv6 integration |
| |
| The protocol also eases IPv4 and IPv6 integration : if only the first layer |
| (FW1 and PX1) is IPv6-capable, it is still possible to present the original |
| client's IPv6 address to the target server even though the whole chain is only |
| connected via IPv4. |
| |
| |
| 4.3. Multiple return paths |
| |
| When transparent proxy is used, it is not possible to run multiple proxies |
| because the return traffic would follow the default route instead of finding |
| the proper proxy. Some tricks are sometimes possible using multiple server |
| addresses and policy routing but these are very limited. |
| |
| Using the PROXY protocol, this problem disappears as the servers don't need |
| to route to the client, just to the proxy that forwarded the connection. So |
| it is perfectly possible to run a proxy farm in front of a very large server |
| farm and have it working effortless, even when dealing with multiple sites. |
| |
| This is particularly important in Cloud-like environments where there is little |
| choice of binding to random addresses and where the lower processing power per |
| node generally requires multiple front nodes. |
| |
| The example below illustrates the following case : virtualized infrastructures |
| are deployed in 3 datacenters (DC1..DC3). Each DC uses its own VIP which is |
| handled by the hosting provider's layer 3 load balancer. This load balancer |
| routes the traffic to a farm of layer 7 SSL/cache offloaders which load balance |
| among their local servers. The VIPs are advertised by geolocalised DNS so that |
| clients generally stick to a given DC. Since clients are not guaranteed to |
| stick to one DC, the L7 load balancing proxies have to know the other DCs' |
| servers that may be reached via the hosting provider's LAN or via the internet. |
| The L7 proxies use the PROXY protocol to join the servers behind them, so that |
| even inter-DC traffic can forward the original client's address and the return |
| path is unambiguous. This would not be possible using transparent proxy because |
| most often the L7 proxies would not be able to spoof an address, and this would |
| never work between datacenters. |
| |
| Internet |
| |
| DC1 DC2 DC3 |
| ,---. ,---. ,---. |
| ( X ) ( X ) ( X ) |
| `---' `---' `---' |
| | +-------+ | +-------+ | +-------+ |
| +----| L3 LB | +----| L3 LB | +----| L3 LB | |
| | +-------+ | +-------+ | +-------+ |
| ------+------- ~ ~ ~ ------+------- ~ ~ ~ ------+------- |
| ||||| |||| ||||| |||| ||||| |||| |
| 50 SRV 4 PX 50 SRV 4 PX 50 SRV 4 PX |
| |
| |
| 5. Security considerations |
| |
| Version 1 of the protocol header (the human-readable format) was designed so as |
| to be distinguishable from HTTP. It will not parse as a valid HTTP request and |
| an HTTP request will not parse as a valid proxy request. Version 2 add to use a |
| non-parsable binary signature to make many products fail on this block. The |
| signature was designed to cause immediate failure on HTTP, SSL/TLS, SMTP, FTP, |
| and POP. It also causes aborts on LDAP and RDP servers (see section 6). That |
| makes it easier to enforce its use under certain connections and at the same |
| time, it ensures that improperly configured servers are quickly detected. |
| |
| Implementers should be very careful about not trying to automatically detect |
| whether they have to decode the header or not, but rather they must only rely |
| on a configuration parameter. Indeed, if the opportunity is left to a normal |
| client to use the protocol, it will be able to hide its activities or make them |
| appear as coming from somewhere else. However, accepting the header only from a |
| number of known sources should be safe. |
| |
| |
| 6. Validation |
| |
| The version 2 protocol signature has been sent to a wide variety of protocols |
| and implementations including old ones. The following protocol and products |
| have been tested to ensure the best possible behavior when the signature was |
| presented, even with minimal implementations : |
| |
| - HTTP : |
| - Apache 1.3.33 : connection abort => pass/optimal |
| - Nginx 0.7.69 : 400 Bad Request + abort => pass/optimal |
| - lighttpd 1.4.20 : 400 Bad Request + abort => pass/optimal |
| - thttpd 2.20c : 400 Bad Request + abort => pass/optimal |
| - mini-httpd-1.19 : 400 Bad Request + abort => pass/optimal |
| - haproxy 1.4.21 : 400 Bad Request + abort => pass/optimal |
| - Squid 3 : 400 Bad Request + abort => pass/optimal |
| - SSL : |
| - stud 0.3.47 : connection abort => pass/optimal |
| - stunnel 4.45 : connection abort => pass/optimal |
| - nginx 0.7.69 : 400 Bad Request + abort => pass/optimal |
| - FTP : |
| - Pure-ftpd 1.0.20 : 3*500 then 221 Goodbye => pass/optimal |
| - vsftpd 2.0.1 : 3*530 then 221 Goodbye => pass/optimal |
| - SMTP : |
| - postfix 2.3 : 3*500 + 221 Bye => pass/optimal |
| - exim 4.69 : 554 + connection abort => pass/optimal |
| - POP : |
| - dovecot 1.0.10 : 3*ERR + Logout => pass/optimal |
| - IMAP : |
| - dovecot 1.0.10 : 5*ERR + hang => pass/non-optimal |
| - LDAP : |
| - openldap 2.3 : abort => pass/optimal |
| - SSH : |
| - openssh 3.9p1 : abort => pass/optimal |
| - RDP : |
| - Windows XP SP3 : abort => pass/optimal |
| |
| This means that most protocols and implementations will not be confused by an |
| incoming connection exhibiting the protocol signature, which avoids issues when |
| facing misconfigurations. |
| |
| |
| 7. Future developments |
| |
| It is possible that the protocol may slightly evolve to present other |
| information such as the incoming network interface, or the origin addresses in |
| case of network address translation happening before the first proxy, but this |
| is not identified as a requirement right now. Some deep thinking has been spent |
| on this and it appears that trying to add a few more information open a Pandora |
| box with many information from MAC addresses to SSL client certificates, which |
| would make the protocol much more complex. So at this point it is not planned. |
| Suggestions on improvements are welcome. |
| |
| |
| 8. Contacts and links |
| |
| Please use w@1wt.eu to send any comments to the author. |
| |
| The following links were referenced in the document. |
| |
| [1] http://www.postfix.org/XCLIENT_README.html |
| [2] http://tools.ietf.org/html/rfc7239 |
| [3] http://www.stunnel.org/ |
| [4] https://github.com/bumptech/stud |
| [5] https://github.com/bumptech/stud/pull/81 |
| [6] https://www.varnish-cache.org/docs/trunk/phk/ssl_again.html |
| [7] http://wiki.squid-cache.org/Squid-3.5 |
| [8] https://tools.ietf.org/html/rfc4960#appendix-B |
| [9] https://tools.ietf.org/rfc/rfc7301.txt |
| [10] https://www.ietf.org/rfc/rfc3546.txt |
| [11] https://redmine.lighttpd.net/issues/2804 |
| |
| 9. Sample code |
| |
| The code below is an example of how a receiver may deal with both versions of |
| the protocol header for TCP over IPv4 or IPv6. The function is supposed to be |
| called upon a read event. Addresses may be directly copied into their final |
| memory location since they're transported in network byte order. The sending |
| side is even simpler and can easily be deduced from this sample code. |
| |
| struct sockaddr_storage from; /* already filled by accept() */ |
| struct sockaddr_storage to; /* already filled by getsockname() */ |
| const char v2sig[12] = "\x0D\x0A\x0D\x0A\x00\x0D\x0A\x51\x55\x49\x54\x0A"; |
| |
| /* returns 0 if needs to poll, <0 upon error or >0 if it did the job */ |
| int read_evt(int fd) |
| { |
| union { |
| struct { |
| char line[108]; |
| } v1; |
| struct { |
| uint8_t sig[12]; |
| uint8_t ver_cmd; |
| uint8_t fam; |
| uint16_t len; |
| union { |
| struct { /* for TCP/UDP over IPv4, len = 12 */ |
| uint32_t src_addr; |
| uint32_t dst_addr; |
| uint16_t src_port; |
| uint16_t dst_port; |
| } ip4; |
| struct { /* for TCP/UDP over IPv6, len = 36 */ |
| uint8_t src_addr[16]; |
| uint8_t dst_addr[16]; |
| uint16_t src_port; |
| uint16_t dst_port; |
| } ip6; |
| struct { /* for AF_UNIX sockets, len = 216 */ |
| uint8_t src_addr[108]; |
| uint8_t dst_addr[108]; |
| } unx; |
| } addr; |
| } v2; |
| } hdr; |
| |
| int size, ret; |
| |
| do { |
| ret = recv(fd, &hdr, sizeof(hdr), MSG_PEEK); |
| } while (ret == -1 && errno == EINTR); |
| |
| if (ret == -1) |
| return (errno == EAGAIN) ? 0 : -1; |
| |
| if (ret >= 16 && memcmp(&hdr.v2, v2sig, 12) == 0 && |
| (hdr.v2.ver_cmd & 0xF0) == 0x20) { |
| size = 16 + ntohs(hdr.v2.len); |
| if (ret < size) |
| return -1; /* truncated or too large header */ |
| |
| switch (hdr.v2.ver_cmd & 0xF) { |
| case 0x01: /* PROXY command */ |
| switch (hdr.v2.fam) { |
| case 0x11: /* TCPv4 */ |
| ((struct sockaddr_in *)&from)->sin_family = AF_INET; |
| ((struct sockaddr_in *)&from)->sin_addr.s_addr = |
| hdr.v2.addr.ip4.src_addr; |
| ((struct sockaddr_in *)&from)->sin_port = |
| hdr.v2.addr.ip4.src_port; |
| ((struct sockaddr_in *)&to)->sin_family = AF_INET; |
| ((struct sockaddr_in *)&to)->sin_addr.s_addr = |
| hdr.v2.addr.ip4.dst_addr; |
| ((struct sockaddr_in *)&to)->sin_port = |
| hdr.v2.addr.ip4.dst_port; |
| goto done; |
| case 0x21: /* TCPv6 */ |
| ((struct sockaddr_in6 *)&from)->sin6_family = AF_INET6; |
| memcpy(&((struct sockaddr_in6 *)&from)->sin6_addr, |
| hdr.v2.addr.ip6.src_addr, 16); |
| ((struct sockaddr_in6 *)&from)->sin6_port = |
| hdr.v2.addr.ip6.src_port; |
| ((struct sockaddr_in6 *)&to)->sin6_family = AF_INET6; |
| memcpy(&((struct sockaddr_in6 *)&to)->sin6_addr, |
| hdr.v2.addr.ip6.dst_addr, 16); |
| ((struct sockaddr_in6 *)&to)->sin6_port = |
| hdr.v2.addr.ip6.dst_port; |
| goto done; |
| } |
| /* unsupported protocol, keep local connection address */ |
| break; |
| case 0x00: /* LOCAL command */ |
| /* keep local connection address for LOCAL */ |
| break; |
| default: |
| return -1; /* not a supported command */ |
| } |
| } |
| else if (ret >= 8 && memcmp(hdr.v1.line, "PROXY", 5) == 0) { |
| char *end = memchr(hdr.v1.line, '\r', ret - 1); |
| if (!end || end[1] != '\n') |
| return -1; /* partial or invalid header */ |
| *end = '\0'; /* terminate the string to ease parsing */ |
| size = end + 2 - hdr.v1.line; /* skip header + CRLF */ |
| /* parse the V1 header using favorite address parsers like inet_pton. |
| * return -1 upon error, or simply fall through to accept. |
| */ |
| } |
| else { |
| /* Wrong protocol */ |
| return -1; |
| } |
| |
| done: |
| /* we need to consume the appropriate amount of data from the socket */ |
| do { |
| ret = recv(fd, &hdr, size, 0); |
| } while (ret == -1 && errno == EINTR); |
| return (ret >= 0) ? 1 : -1; |
| } |