一篇讲memcached的文章

 

Protocol

--------

Clients of memcached communicate with server through TCP connections.

(A UDP interface is also available; details are below under "UDP

protocol.") A given running memcached server listens on some

(configurable) port; clients connect to that port, send commands to

the server, read responses, and eventually close the connection.

There is no need to send any command to end the session. A client may

just close the connection at any moment it no longer needs it. Note,

however, that clients are encouraged to cache their connections rather

than reopen them every time they need to store or retrieve data. This

is because memcached is especially designed to work very efficiently

with a very large number (many hundreds, more than a thousand if

necessary) of open connections. Caching connections will eliminate the

overhead associated with establishing a TCP connection (the overhead

of preparing for a new connection on the server side is insignificant

compared to this).

There are two kinds of data sent in the memcache protocol: text lines

and unstructured data. Text lines are used for commands from clients

and responses from servers. Unstructured data is sent when a client

wants to store or retrieve data. The server will transmit back

unstructured data in exactly the same way it received it, as a byte

stream. The server doesn't care about byte order issues in

unstructured data and isn't aware of them. There are no limitations on

characters that may appear in unstructured data; however, the reader

of such data (either a client or a server) will always know, from a

preceding text line, the exact length of the data block being

transmitted.

Text lines are always terminated by \r\n. Unstructured data is _also_

terminated by \r\n, even though \r, \n or any other 8-bit characters

may also appear inside the data. Therefore, when a client retrieves

data from a server, it must use the length of the data block (which it

will be provided with) to determine where the data block ends, and not

the fact that \r\n follows the end of the data block, even though it

does.

Keys

----

Data stored by memcached is identified with the help of a key. A key

is a text string which should uniquely identify the data for clients

that are interested in storing and retrieving it. Currently the

length limit of a key is set at 250 characters (of course, normally

clients wouldn't need to use such long keys); the key must not include

control characters or whitespace.

Commands

--------

There are three types of commands.

Storage commands (there are six: "set", "add", "replace", "append"

"prepend" and "cas") ask the server to store some data identified by a key. The

client sends a command line, and then a data block; after that the

client expects one line of response, which will indicate success or

faulure.

Retrieval commands (there are two: "get" and "gets") ask the server to

retrieve data corresponding to a set of keys (one or more keys in one

request). The client sends a command line, which includes all the

requested keys; after that for each item the server finds it sends to

the client one response line with information about the item, and one

data block with the item's data; this continues until the server

finished with the "END" response line.

All other commands don't involve unstructured data. In all of them,

the client sends one command line, and expects (depending on the

command) either one line of response, or several lines of response

ending with "END" on the last line.

A command line always starts with the name of the command, followed by

parameters (if any) delimited by whitespace. Command names are

lower-case and are case-sensitive.

Expiration times

----------------

Some commands involve a client sending some kind of expiration time

(relative to an item or to an operation requested by the client) to

the server. In all such cases, the actual value sent may either be

Unix time (number of seconds since January 1, 1970, as a 32-bit

value), or a number of seconds starting from current time. In the

latter case, this number of seconds may not exceed 60*60*24*30 (number

of seconds in 30 days); if the number sent by a client is larger than

that, the server will consider it to be real Unix time value rather

than an offset from current time.

Error strings

-------------

Each command sent by a client may be answered with an error string

from the server. These error strings come in three types:

- "ERROR\r\n"

means the client sent a nonexistent command name.

- "CLIENT_ERROR <error>\r\n"

means some sort of client error in the input line, i.e. the input

doesn't conform to the protocol in some way. <error> is a

human-readable error string.

- "SERVER_ERROR <error>\r\n"

means some sort of server error prevents the server from carrying

out the command. <error> is a human-readable error string. In cases

of severe server errors, which make it impossible to continue

serving the client (this shouldn't normally happen), the server will

close the connection after sending the error line. This is the only

case in which the server closes a connection to a client.

In the descriptions of individual commands below, these error lines

are not again specifically mentioned, but clients must allow for their

possibility.

Storage commands

----------------

First, the client sends a command line which looks like this:

<command name> <key> <flags> <exptime> <bytes> [noreply]\r\n

cas <key> <flags> <exptime> <bytes> <cas unqiue> [noreply]\r\n

- <command name> is "set", "add", "replace", "append" or "prepend"

"set" means "store this data".

"add" means "store this data, but only if the server *doesn't* already

hold data for this key".

"replace" means "store this data, but only if the server *does*

already hold data for this key".

"append" means "add this data to an existing key after existing data".

"prepend" means "add this data to an existing key before existing data".

The append and prepend commands do not accept flags or exptime.

They update existing data portions, and ignore new flag and exptime

settings.

"cas" is a check and set operation which means "store this data but

only if no one else has updated since I last fetched it."

- <key> is the key under which the client asks to store the data

- <flags> is an arbitrary 16-bit unsigned integer (written out in

decimal) that the server stores along with the data and sends back

when the item is retrieved. Clients may use this as a bit field to

store data-specific information; this field is opaque to the server.

Note that in memcached 1.2.1 and higher, flags may be 32-bits, instead

of 16, but you might want to restrict yourself to 16 bits for

compatibility with older versions.

- <exptime> is expiration time. If it's 0, the item never expires

(although it may be deleted from the cache to make place for other

items). If it's non-zero (either Unix time or offset in seconds from

current time), it is guaranteed that clients will not be able to

retrieve this item after the expiration time arrives (measured by

server time).

- <bytes> is the number of bytes in the data block to follow, *not*

including the delimiting \r\n. <bytes> may be zero (in which case

it's followed by an empty data block).

- <cas unique> is a unique 64-bit value of an existing entry.

Clients should use the value returned from the "gets" command

when issuing "cas" updates.

- "noreply" optional parameter instructs the server to not send the

reply. NOTE: if the request line is malformed, the server can't

parse "noreply" option reliably. In this case it may send the error

to the client, and not reading it on the client side will break

things. Client should construct only valid requests.

After this line, the client sends the data block:

<data block>\r\n

- <data block> is a chunk of arbitrary 8-bit data of length <bytes>

from the previous line.

After sending the command line and the data blockm the client awaits

the reply, which may be:

- "STORED\r\n", to indicate success.

- "NOT_STORED\r\n" to indicate the data was not stored, but not

because of an error. This normally means that either that the

condition for an "add" or a "replace" command wasn't met, or that the

item is in a delete queue (see the "delete" command below).

- "EXISTS\r\n" to indicate that the item you are trying to store with

a "cas" command has been modified since you last fetched it.

- "NOT_FOUND\r\n" to indicate that the item you are trying to store

with a "cas" command did not exist or has been deleted.

Retrieval command:

------------------

The retrieval commands "get" and "gets" operates like this:

get <key>*\r\n

gets <key>*\r\n

- <key>* means one or more key strings separated by whitespace.

After this command, the client expects zero or more items, each of

which is received as a text line followed by a data block. After all

the items have been transmitted, the server sends the string

"END\r\n"

to indicate the end of response.

Each item sent by the server looks like this:

VALUE <key> <flags> <bytes> [<cas unique>]\r\n

<data block>\r\n

- <key> is the key for the item being sent

- <flags> is the flags value set by the storage command

- <bytes> is the length of the data block to follow, *not* including

its delimiting \r\n

- <cas unique> is a unique 64-bit integer that uniquely identifies

this specific item.

- <data block> is the data for this item.

If some of the keys appearing in a retrieval request are not sent back

by the server in the item list this means that the server does not

hold items with such keys (because they were never stored, or stored

but deleted to make space for more items, or expired, or explicitly

deleted by a client).

Deletion

--------

The command "delete" allows for explicit deletion of items:

delete <key> [<time>] [noreply]\r\n

- <key> is the key of the item the client wishes the server to delete

- <time> is the amount of time in seconds (or Unix time until which)

the client wishes the server to refuse "add" and "replace" commands

with this key. For this amount of item, the item is put into a

delete queue, which means that it won't possible to retrieve it by

the "get" command, but "add" and "replace" command with this key

will also fail (the "set" command will succeed, however). After the

time passes, the item is finally deleted from server memory.

The parameter <time> is optional, and, if absent, defaults to 0

(which means that the item will be deleted immediately and further

storage commands with this key will succeed).

- "noreply" optional parameter instructs the server to not send the

reply. See the note in Storage commands regarding malformed

requests.

The response line to this command can be one of:

- "DELETED\r\n" to indicate success

- "NOT_FOUND\r\n" to indicate that the item with this key was not

found.

See the "flush_all" command below for immediate invalidation

of all existing items.

Increment/Decrement

-------------------

Commands "incr" and "decr" are used to change data for some item

in-place, incrementing or decrementing it. The data for the item is

treated as decimal representation of a 64-bit unsigned integer. If the

current data value does not conform to such a representation, the

commands behave as if the value were 0. Also, the item must already

exist for incr/decr to work; these commands won't pretend that a

non-existent key exists with value 0; instead, they will fail.

The client sends the command line:

incr <key> <value> [noreply]\r\n

or

decr <key> <value> [noreply]\r\n

- <key> is the key of the item the client wishes to change

- <value> is the amount by which the client wants to increase/decrease

the item. It is a decimal representation of a 64-bit unsigned integer.

- "noreply" optional parameter instructs the server to not send the

reply. See the note in Storage commands regarding malformed

requests.

The response will be one of:

- "NOT_FOUND\r\n" to indicate the item with this value was not found

- <value>\r\n , where <value> is the new value of the item's data,

after the increment/decrement operation was carried out.

Note that underflow in the "decr" command is caught: if a client tries

to decrease the value below 0, the new value will be 0. Overflow in

the "incr" command will wrap around the 64 bit mark.

Note also that decrementing a number such that it loses length isn't

guaranteed to decrement its returned length. The number MAY be

space-padded at the end, but this is purely an implementation

optimization, so you also shouldn't rely on that.

Statistics

----------

The command "stats" is used to query the server about statistics it

maintains and other internal data. It has two forms. Without

arguments:

stats\r\n

it causes the server to output general-purpose statistics and

settings, documented below. In the other form it has some arguments:

stats <args>\r\n

Depending on <args>, various internal data is sent by the server. The

kinds of arguments and the data sent are not documented in this vesion

of the protocol, and are subject to change for the convenience of

memcache developers.

General-purpose statistics

--------------------------

Upon receiving the "stats" command without arguments, the server sents

a number of lines which look like this:

STAT <name> <value>\r\n

The server terminates this list with the line

END\r\n

In each line of statistics, <name> is the name of this statistic, and

<value> is the data. The following is the list of all names sent in

response to the "stats" command, together with the type of the value

sent for this name, and the meaning of the value.

In the type column below, "32u" means a 32-bit unsigned integer, "64u"

means a 64-bit unsigner integer. '32u:32u' means two 32-but unsigned

integers separated by a colon.

Name Type Meaning

----------------------------------

pid 32u Process id of this server process

uptime 32u Number of seconds this server has been running

time 32u current UNIX time according to the server

version string Version string of this server

pointer_size 32 Default size of pointers on the host OS

(generally 32 or 64)

rusage_user 32u:32u Accumulated user time for this process

(seconds:microseconds)

rusage_system 32u:32u Accumulated system time for this process

(seconds:microseconds)

curr_items 32u Current number of items stored by the server

total_items 32u Total number of items stored by this server

ever since it started

bytes 64u Current number of bytes used by this server

to store items

curr_connections 32u Number of open connections

total_connections 32u Total number of connections opened since

the server started running

connection_structures 32u Number of connection structures allocated

by the server

cmd_get 64u Cumulative number of retrieval requests

cmd_set 64u Cumulative number of storage requests

get_hits 64u Number of keys that have been requested and

found present

get_misses 64u Number of items that have been requested

and not found

evictions 64u Number of valid items removed from cache

to free memory for new items

bytes_read 64u Total number of bytes read by this server

from network

bytes_written 64u Total number of bytes sent by this server to

network

limit_maxbytes 32u Number of bytes this server is allowed to

use for storage.

threads 32u Number of worker threads requested.

(see doc/threads.txt)

Item statistics

---------------

CAVEAT: This section describes statistics which are subject to change in the

future.

The "stats" command with the argument of "items" returns information about

item storage per slab class. The data is returned in the format:

STAT items:<slabclass>:<stat> <value>\r\n

The server terminates this list with the line

END\r\n

The slabclass aligns with class ids used by the "stats slabs" command. Where

"stats slabs" describes size and memory usage, "stats items" shows higher

level information.

The following item values are defined as of writing.

Name Meaning

------------------------------

number Number of items presently stored in this class. Expired

items are not automatically excluded.

age Age of the oldest item in the LRU.

evicted Number of times an item had to be evicted from the LRU

before it expired.

outofmemory Number of times the underlying slab class was unable to

store a new item. This means you are running with -M or

an eviction failed.

Note this will only display information about slabs which exist, so an empty

cache will return an empty set.

Item size statistics

--------------------

CAVEAT: This section describes statistics which are subject to change in the

future.

The "stats" command with the argument of "sizes" returns information about the

general size and count of all items stored in the cache.

WARNING: This command WILL lock up your cache! It iterates over *every item*

and examines the size. While the operation is fast, if you have many items

you could prevent memcached from serving requests for several seconds.

The data is returned in the following format:

<size> <count>\r\n

The server terminates this list with the line

END\r\n

'size' is an approximate size of the item, within 32 bytes.

'count' is the amount of items that exist within that 32-byte range.

This is essentially a display of all of your items if there was a slab class

for every 32 bytes. You can use this to determine if adjusting the slab growth

factor would save memory overhead. For example: generating more classes in the

lower range could allow items to fit more snugly into their slab classes, if

most of your items are less than 200 bytes in size.

Slab statistics

---------------

CAVEAT: This section describes statistics which are subject to change in the

future.

The "stats" command with the argument of "slabs" returns information about

each of the slabs created by memcached during runtime. This includes per-slab

information along with some totals. The data is returned in the format:

STAT <slabclass>:<stat> <value>\r\n

STAT <stat> <value>\r\n

The server terminates this list with the line

END\r\n

Name Meaning

------------------------------

chunk_size The amount of space each chunk uses. One item will use

one chunk of the appropriate size.

chunks_per_page How many chunks exist within one page. A page by

default is one megabyte in size. Slabs are allocated per

page, then broken into chunks.

total_pages Total number of pages allocated to the slab class.

total_chunks Total number of chunks allocated to the slab class.

used_chunks How many chunks have been allocated to items.

free_chunks Chunks not yet allocated to items, or freed via delete.

free_chunks_end Number of free chunks at the end of the last allocated

page.

active_slabs Total number of slab classes allocated.

total_malloced Total amount of memory allocated to slab pages.

Other commands

--------------

"flush_all" is a command with an optional numeric argument. It always

succeeds, and the server sends "OK\r\n" in response (unless "noreply"

is given as the last parameter). Its effect is to invalidate all

existing items immediately (by default) or after the expiration

specified. After invalidation none of the items will be returned in

response to a retrieval command (unless it's stored again under the

same key *after* flush_all has invalidated the items). flush_all

doesn't actually free all the memory taken up by existing items; that

will happen gradually as new items are stored. The most precise

definition of what flush_all does is the following: it causes all

items whose update time is earlier than the time at which flush_all

was set to be executed to be ignored for retrieval purposes.

The intent of flush_all with a delay, was that in a setting where you

have a pool of memcached servers, and you need to flush all content,

you have the option of not resetting all memcached servers at the

same time (which could e.g. cause a spike in database load with all

clients suddenly needing to recreate content that would otherwise

have been found in the memcached daemon).

The delay option allows you to have them reset in e.g. 10 second

intervals (by passing 0 to the first, 10 to the second, 20 to the

third, etc. etc.).

"version" is a command with no arguments:

version\r\n

In response, the server sends

"VERSION <version>\r\n", where <version> is the version string for the

server.

"verbosity" is a command with a numeric argument. It always succeeds,

and the server sends "OK\r\n" in response (unless "noreply" is given

as the last parameter). Its effect is to set the verbosity level of

the logging output.

"quit" is a command with no arguments:

quit\r\n

Upon receiving this command, the server closes the

connection. However, the client may also simply close the connection

when it no longer needs it, without issuing this command.

UDP protocol

------------

For very large installations where the number of clients is high enough

that the number of TCP connections causes scaling difficulties, there is

also a UDP-based interface. The UDP interface does not provide guaranteed

delivery, so should only be used for operations that aren't required to

succeed; typically it is used for "get" requests where a missing or

incomplete response can simply be treated as a cache miss.

Each UDP datagram contains a simple frame header, followed by data in the

same format as the TCP protocol described above. In the current

implementation, requests must be contained in a single UDP datagram, but

responses may span several datagrams. (The only common requests that would

span multiple datagrams are huge multi-key "get" requests and "set"

requests, both of which are more suitable to TCP transport for reliability

reasons anyway.)

The frame header is 8 bytes long, as follows (all values are 16-bit integers

in network byte order, high byte first):

0-1 Request ID

2-3 Sequence number

4-5 Total number of datagrams in this message

6-7 Reserved for future use; must be 0

The request ID is supplied by the client. Typically it will be a

monotonically increasing value starting from a random seed, but the client

is free to use whatever request IDs it likes. The server's response will

contain the same ID as the incoming request. The client uses the request ID

to differentiate between responses to outstanding requests if there are

several pending from the same server; any datagrams with an unknown request

ID are probably delayed responses to an earlier request and should be

discarded.

The sequence number ranges from 0 to n-1, where n is the total number of

datagrams in the message. The client should concatenate the payloads of the

datagrams for a given response in sequence number order; the resulting byte

stream will contain a complete response in the same format as the TCP

protocol (including terminating \r\n sequences).