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6778b27542
Implement exactly the same code as this has been done for "gpc0" and "gpc0_rate" counters.
289 lines
8.5 KiB
Plaintext
289 lines
8.5 KiB
Plaintext
Haproxy's peers v2.0 protocol 08/18/2016
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Author: Emeric Brun ebrun@haproxy.com
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I) Encoded Integer and Bitfield.
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0 <= X < 240 : 1 byte (7.875 bits) [ XXXX XXXX ]
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240 <= X < 2288 : 2 bytes (11 bits) [ 1111 XXXX ] [ 0XXX XXXX ]
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2288 <= X < 264432 : 3 bytes (18 bits) [ 1111 XXXX ] [ 1XXX XXXX ] [ 0XXX XXXX ]
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264432 <= X < 33818864 : 4 bytes (25 bits) [ 1111 XXXX ] [ 1XXX XXXX ]*2 [ 0XXX XXXX ]
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33818864 <= X < 4328786160 : 5 bytes (32 bits) [ 1111 XXXX ] [ 1XXX XXXX ]*3 [ 0XXX XXXX ]
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I) Handshake
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Each peer try to connect to each others, and each peer is listening
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for a connect from other peers.
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Client Server
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Hello Message
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------------------------>
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Status Message
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<------------------------
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1) Hello Message
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Hello message is composed of 3 lines:
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<protocol> <version>
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<remotepeerid>
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<localpeerid> <processpid> <relativepid>
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protocol: current value is "HaproxyS"
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version: current value is "2.0"
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remotepeerid: is the name of the target peer as defined in the configuration peers section.
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localpeerid: is the name of the local peer as defined on cmdline or using hostname.
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processid: is the system process id of the local process.
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relativepid: is the haproxy's relative pid (0 if nbproc == 1)
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2) Status Message
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Status message is a code followed by a LF.
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200: Handshake succeeded
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300: Try again later
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501: Protocol error
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502: Bad version
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503: Local peer name mismatch
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504: Remote peer name mismatch
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IV) Messages
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Messages:
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0 - - - - - - - 8 - - - - - - - 16
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Message Class| Message Type
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if Message Type >= 128
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0 - - - - - - - 8 - - - - - - - 16 .....
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Message Class| Message Type | encoded data length | data
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Message Classes:
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0: control
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1: error
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10: related to stick table updates
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255: reserved
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1) Control Messages Class
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Available message Types for class control:
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0: resync request
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1: resync finished
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2: resync partial
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3: resync confirm
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a) Resync Request Message
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This message is used to request a full resync from a peer
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b) Resync Finished Message
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This message is used to signal remote peer that locally known updates have been pushed, and local peer was considered up to date.
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c) Resync Partial Message
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This message is used to signal remote peer that locally known updates have been pushed, and but the local peer is not considered up to date.
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d) Resync Confirm Message
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This message is an ack for Resync Partial or Finished Messages.
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It's allow the remote peer to go back to "on the fly" update process.
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2) Messages Class
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Available message Types for this class are:
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0: protocol error
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1: size limit reached
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a) Protocol Message
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To signal that a protocol error occured. Connection will be shutdown just after sending this message.
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b) Size Limit Error Message
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To signal that a message is outsized and can not be correctly handled. Connection will be broken.
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3) Stick Table Updates Messages Class
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Available message Types for this class are:
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0: Entry update
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1: Incremental entry update
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2: table definition
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3: table switch
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4: updates ack message.
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a) Update Message
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0 - - - - - - - 8 - - - - - - - 16 .....
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Message class | Message Type | encoded data length | data
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data is composed like this
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0 - - - - - - - 32 .............................
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Local Update ID | Key value | data values ....
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Update ID in a 32bits identifier of the local update.
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Key value format depends of the table key type:
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- for keytype string
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0 .................................
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encoded string length | string value
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- for keytype integer
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0 - - - - - - - - - - 32
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encoded integer value |
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- for other key type
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The value length is annonced in table definition message
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0 ....................
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value
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b) Incremental Update Message
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Same format than update message except the Update ID is not present, the receiver should
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consider that the update ID is an increment of 1 of the previous considered update message (partial or not)
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c) Table Definition Message
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This message is used by the receiver to identify the stick table concerned by next update messages and
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to know which data is pushed in these updates.
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0 - - - - - - - 8 - - - - - - - 16 .....
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Message class | Message Type | encoded data length | data
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data is composed like this
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0 ...................................................................
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Encoded Sender Table Id | Encoded Local Table Name Length | Table Name | Encoded Table Type | Encoded Table Keylen | Encoded Table Data Types Bitfield
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Encoded Sender Table ID present a the id numerical ID affected to that table by the sender
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It will be used by "Updates Aknowlegement Messages" and "Table Switch Messages".
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Encoded Local Table Name Length present the length to read the table name.
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"Table Name" is the shared identifier of the table (name of the current table in the configuration)
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It permits the receiver to identify the concerned table. The receiver should keep in memory the matching
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between the "Sender Table ID" to identify it directly in case of "Table Switch Message".
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Table Type present the numeric type of key used to store stick table entries:
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integer
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0: signed integer
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1: IPv4 address
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2: IPv6 address
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3: string
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4: binary
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Table Keylen present the key length or max length in case of strings or binary (padded with 0).
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Data Types Bitfield present the types of data linearly pushed in next updates message (they will be linearly pushed in the update message)
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Known types are
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bit
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0: server id
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1: gpt0
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2: gpc0
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3: gpc0 rate
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4: connections counter
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5: connection rate
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6: number of current connections
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7: sessions counter
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8: session rate
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9: http requests counter
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10: http requests rate
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11: errors counter
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12: errors rate
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13: bytes in counter
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14: bytes in rate
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15: bytes out rate
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16: bytes out rate
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17: gpc1
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18: gpc1 rate
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d) Table Switch Message
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After a Table Message Define, this message can be used by the receiver to identify the stick table concerned by next update messages.
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0 - - - - - - - 8 - - - - - - - 16 .....
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Message class | Message Type | encoded data length | data
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data is composed like this
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0 .....................
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encoded Sender Table Id
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c) Update Ack Message
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0 - - - - - - - 8 - - - - - - - 16 .....
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Message class | Message Type | encoded data length | data
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data is composed like this
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0 ....................... - - - - - - - - 32
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Encoded Remote Table Id | Update Id
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Remote Table Id is the numeric identifier of the table on the remote side.
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Update Id is the id of the last update locally commited.
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If a re-connection occured, the sender should know he will have to restart the push of updates from this point.
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III) Initial full resync process.
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a) Resync from local old process
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An old soft-stopped process will close all established sessions with remote peers and will try to connect to a new
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local process to push all known ending with a Resync Finished Message or a Resync Partial Message (if it it does not consider itself as full updated).
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A new process will wait for a an incoming connection from a local process during 5 seconds. It will learn the updates from this
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process until he will receive a Resync Finished Message or a Resync Partial Message. If it receive a Resync Finished Message it will consider itself
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as fully updated and stops to ask for resync. If it receive a Resync Partial Message it will wait once again for 5 seconds for an other incoming connection from a local process.
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Same thing if the session was broken before receiving any "Resync Partial Message" or "Resync Finished Message".
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If one of these 5 seconds timeout expire, the process will try to request resync from a remote connected peer (see b). The process will wait until 5seconds
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if no available remote peers are found.
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If the timeout expire, the process will consider itself ass fully updated
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b) Resync from remote peers
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The process will randomly choose a remote connected peer and ask for a full resync using a Resync Request Message. The process will wait until 5seconds
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if no available remote peers are found.
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The chosen remote peer will push its all known data ending with a Resync Finished Message or a Resync Partial Message (if it it does not consider itself as full updated).
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If it receive a Resync Finished Message it will consider itself as fully updated and stops to ask for resync.
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If it receive a Resync Partial Message, the current peer will be flagged to anymore be requested and any other connected peer will be randomly chosen for a resync request (5s).
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If the session is broken before receiving any ot these messages any other connected peer will be randomly chosen for a resync request (5s).
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If the timeout expire, the process will consider itself as fully updated
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