RFC793 (TCP) [part 1 of 3]
Brian Kantor
brian at sdcc3.UUCP
Fri Jan 11 10:14:42 AEST 1985
RFC: 793
TRANSMISSION CONTROL PROTOCOL
DARPA INTERNET PROGRAM
PROTOCOL SPECIFICATION
September 1981
prepared for
Defense Advanced Research Projects Agency
Information Processing Techniques Office
1400 Wilson Boulevard
Arlington, Virginia 22209
by
Information Sciences Institute
University of Southern California
4676 Admiralty Way
Marina del Rey, California 90291
September 1981
Transmission Control Protocol
TABLE OF CONTENTS
PREFACE ........................................................ iii
1. INTRODUCTION ..................................................... 1
1.1 Motivation .................................................... 1
1.2 Scope ......................................................... 2
1.3 About This Document ........................................... 2
1.4 Interfaces .................................................... 3
1.5 Operation ..................................................... 3
2. PHILOSOPHY ....................................................... 7
2.1 Elements of the Internetwork System ........................... 7
2.2 Model of Operation ............................................ 7
2.3 The Host Environment .......................................... 8
2.4 Interfaces .................................................... 9
2.5 Relation to Other Protocols ................................... 9
2.6 Reliable Communication ........................................ 9
2.7 Connection Establishment and Clearing ........................ 10
2.8 Data Communication ........................................... 12
2.9 Precedence and Security ...................................... 13
2.10 Robustness Principle ......................................... 13
3. FUNCTIONAL SPECIFICATION ........................................ 15
3.1 Header Format ................................................ 15
3.2 Terminology .................................................. 19
3.3 Sequence Numbers ............................................. 24
3.4 Establishing a connection .................................... 30
3.5 Closing a Connection ......................................... 37
3.6 Precedence and Security ...................................... 40
3.7 Data Communication ........................................... 40
3.8 Interfaces ................................................... 44
3.9 Event Processing ............................................. 52
GLOSSARY ............................................................ 79
REFERENCES .......................................................... 85
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PREFACE
This document describes the DoD Standard Transmission Control Protocol
(TCP). There have been nine earlier editions of the ARPA TCP
specification on which this standard is based, and the present text
draws heavily from them. There have been many contributors to this work
both in terms of concepts and in terms of text. This edition clarifies
several details and removes the end-of-letter buffer-size adjustments,
and redescribes the letter mechanism as a push function.
Jon Postel
Editor
[Page iii]
RFC: 793
Replaces: RFC 761
IENs: 129, 124, 112, 81,
55, 44, 40, 27, 21, 5
TRANSMISSION CONTROL PROTOCOL
DARPA INTERNET PROGRAM
PROTOCOL SPECIFICATION
1. INTRODUCTION
The Transmission Control Protocol (TCP) is intended for use as a highly
reliable host-to-host protocol between hosts in packet-switched computer
communication networks, and in interconnected systems of such networks.
This document describes the functions to be performed by the
Transmission Control Protocol, the program that implements it, and its
interface to programs or users that require its services.
1.1. Motivation
Computer communication systems are playing an increasingly important
role in military, government, and civilian environments. This
document focuses its attention primarily on military computer
communication requirements, especially robustness in the presence of
communication unreliability and availability in the presence of
congestion, but many of these problems are found in the civilian and
government sector as well.
As strategic and tactical computer communication networks are
developed and deployed, it is essential to provide means of
interconnecting them and to provide standard interprocess
communication protocols which can support a broad range of
applications. In anticipation of the need for such standards, the
Deputy Undersecretary of Defense for Research and Engineering has
declared the Transmission Control Protocol (TCP) described herein to
be a basis for DoD-wide inter-process communication protocol
standardization.
TCP is a connection-oriented, end-to-end reliable protocol designed to
fit into a layered hierarchy of protocols which support multi-network
applications. The TCP provides for reliable inter-process
communication between pairs of processes in host computers attached to
distinct but interconnected computer communication networks. Very few
assumptions are made as to the reliability of the communication
protocols below the TCP layer. TCP assumes it can obtain a simple,
potentially unreliable datagram service from the lower level
protocols. In principle, the TCP should be able to operate above a
wide spectrum of communication systems ranging from hard-wired
connections to packet-switched or circuit-switched networks.
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Transmission Control Protocol
Introduction
TCP is based on concepts first described by Cerf and Kahn in [1]. The
TCP fits into a layered protocol architecture just above a basic
Internet Protocol [2] which provides a way for the TCP to send and
receive variable-length segments of information enclosed in internet
datagram "envelopes". The internet datagram provides a means for
addressing source and destination TCPs in different networks. The
internet protocol also deals with any fragmentation or reassembly of
the TCP segments required to achieve transport and delivery through
multiple networks and interconnecting gateways. The internet protocol
also carries information on the precedence, security classification
and compartmentation of the TCP segments, so this information can be
communicated end-to-end across multiple networks.
Protocol Layering
+---------------------+
| higher-level |
+---------------------+
| TCP |
+---------------------+
| internet protocol |
+---------------------+
|communication network|
+---------------------+
Figure 1
Much of this document is written in the context of TCP implementations
which are co-resident with higher level protocols in the host
computer. Some computer systems will be connected to networks via
front-end computers which house the TCP and internet protocol layers,
as well as network specific software. The TCP specification describes
an interface to the higher level protocols which appears to be
implementable even for the front-end case, as long as a suitable
host-to-front end protocol is implemented.
1.2. Scope
The TCP is intended to provide a reliable process-to-process
communication service in a multinetwork environment. The TCP is
intended to be a host-to-host protocol in common use in multiple
networks.
1.3. About this Document
This document represents a specification of the behavior required of
any TCP implementation, both in its interactions with higher level
protocols and in its interactions with other TCPs. The rest of this
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Introduction
section offers a very brief view of the protocol interfaces and
operation. Section 2 summarizes the philosophical basis for the TCP
design. Section 3 offers both a detailed description of the actions
required of TCP when various events occur (arrival of new segments,
user calls, errors, etc.) and the details of the formats of TCP
segments.
1.4. Interfaces
The TCP interfaces on one side to user or application processes and on
the other side to a lower level protocol such as Internet Protocol.
The interface between an application process and the TCP is
illustrated in reasonable detail. This interface consists of a set of
calls much like the calls an operating system provides to an
application process for manipulating files. For example, there are
calls to open and close connections and to send and receive data on
established connections. It is also expected that the TCP can
asynchronously communicate with application programs. Although
considerable freedom is permitted to TCP implementors to design
interfaces which are appropriate to a particular operating system
environment, a minimum functionality is required at the TCP/user
interface for any valid implementation.
The interface between TCP and lower level protocol is essentially
unspecified except that it is assumed there is a mechanism whereby the
two levels can asynchronously pass information to each other.
Typically, one expects the lower level protocol to specify this
interface. TCP is designed to work in a very general environment of
interconnected networks. The lower level protocol which is assumed
throughout this document is the Internet Protocol [2].
1.5. Operation
As noted above, the primary purpose of the TCP is to provide reliable,
securable logical circuit or connection service between pairs of
processes. To provide this service on top of a less reliable internet
communication system requires facilities in the following areas:
Basic Data Transfer
Reliability
Flow Control
Multiplexing
Connections
Precedence and Security
The basic operation of the TCP in each of these areas is described in
the following paragraphs.
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Transmission Control Protocol
Introduction
Basic Data Transfer:
The TCP is able to transfer a continuous stream of octets in each
direction between its users by packaging some number of octets into
segments for transmission through the internet system. In general,
the TCPs decide when to block and forward data at their own
convenience.
Sometimes users need to be sure that all the data they have
submitted to the TCP has been transmitted. For this purpose a push
function is defined. To assure that data submitted to a TCP is
actually transmitted the sending user indicates that it should be
pushed through to the receiving user. A push causes the TCPs to
promptly forward and deliver data up to that point to the receiver.
The exact push point might not be visible to the receiving user and
the push function does not supply a record boundary marker.
Reliability:
The TCP must recover from data that is damaged, lost, duplicated, or
delivered out of order by the internet communication system. This
is achieved by assigning a sequence number to each octet
transmitted, and requiring a positive acknowledgment (ACK) from the
receiving TCP. If the ACK is not received within a timeout
interval, the data is retransmitted. At the receiver, the sequence
numbers are used to correctly order segments that may be received
out of order and to eliminate duplicates. Damage is handled by
adding a checksum to each segment transmitted, checking it at the
receiver, and discarding damaged segments.
As long as the TCPs continue to function properly and the internet
system does not become completely partitioned, no transmission
errors will affect the correct delivery of data. TCP recovers from
internet communication system errors.
Flow Control:
TCP provides a means for the receiver to govern the amount of data
sent by the sender. This is achieved by returning a "window" with
every ACK indicating a range of acceptable sequence numbers beyond
the last segment successfully received. The window indicates an
allowed number of octets that the sender may transmit before
receiving further permission.
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Introduction
Multiplexing:
To allow for many processes within a single Host to use TCP
communication facilities simultaneously, the TCP provides a set of
addresses or ports within each host. Concatenated with the network
and host addresses from the internet communication layer, this forms
a socket. A pair of sockets uniquely identifies each connection.
That is, a socket may be simultaneously used in multiple
connections.
The binding of ports to processes is handled independently by each
Host. However, it proves useful to attach frequently used processes
(e.g., a "logger" or timesharing service) to fixed sockets which are
made known to the public. These services can then be accessed
through the known addresses. Establishing and learning the port
addresses of other processes may involve more dynamic mechanisms.
Connections:
The reliability and flow control mechanisms described above require
that TCPs initialize and maintain certain status information for
each data stream. The combination of this information, including
sockets, sequence numbers, and window sizes, is called a connection.
Each connection is uniquely specified by a pair of sockets
identifying its two sides.
When two processes wish to communicate, their TCP's must first
establish a connection (initialize the status information on each
side). When their communication is complete, the connection is
terminated or closed to free the resources for other uses.
Since connections must be established between unreliable hosts and
over the unreliable internet communication system, a handshake
mechanism with clock-based sequence numbers is used to avoid
erroneous initialization of connections.
Precedence and Security:
The users of TCP may indicate the security and precedence of their
communication. Provision is made for default values to be used when
these features are not needed.
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2. PHILOSOPHY
2.1. Elements of the Internetwork System
The internetwork environment consists of hosts connected to networks
which are in turn interconnected via gateways. It is assumed here
that the networks may be either local networks (e.g., the ETHERNET) or
large networks (e.g., the ARPANET), but in any case are based on
packet switching technology. The active agents that produce and
consume messages are processes. Various levels of protocols in the
networks, the gateways, and the hosts support an interprocess
communication system that provides two-way data flow on logical
connections between process ports.
The term packet is used generically here to mean the data of one
transaction between a host and its network. The format of data blocks
exchanged within the a network will generally not be of concern to us.
Hosts are computers attached to a network, and from the communication
network's point of view, are the sources and destinations of packets.
Processes are viewed as the active elements in host computers (in
accordance with the fairly common definition of a process as a program
in execution). Even terminals and files or other I/O devices are
viewed as communicating with each other through the use of processes.
Thus, all communication is viewed as inter-process communication.
Since a process may need to distinguish among several communication
streams between itself and another process (or processes), we imagine
that each process may have a number of ports through which it
communicates with the ports of other processes.
2.2. Model of Operation
Processes transmit data by calling on the TCP and passing buffers of
data as arguments. The TCP packages the data from these buffers into
segments and calls on the internet module to transmit each segment to
the destination TCP. The receiving TCP places the data from a segment
into the receiving user's buffer and notifies the receiving user. The
TCPs include control information in the segments which they use to
ensure reliable ordered data transmission.
The model of internet communication is that there is an internet
protocol module associated with each TCP which provides an interface
to the local network. This internet module packages TCP segments
inside internet datagrams and routes these datagrams to a destination
internet module or intermediate gateway. To transmit the datagram
through the local network, it is embedded in a local network packet.
The packet switches may perform further packaging, fragmentation, or
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other operations to achieve the delivery of the local packet to the
destination internet module.
At a gateway between networks, the internet datagram is "unwrapped"
from its local packet and examined to determine through which network
the internet datagram should travel next. The internet datagram is
then "wrapped" in a local packet suitable to the next network and
routed to the next gateway, or to the final destination.
A gateway is permitted to break up an internet datagram into smaller
internet datagram fragments if this is necessary for transmission
through the next network. To do this, the gateway produces a set of
internet datagrams; each carrying a fragment. Fragments may be
further broken into smaller fragments at subsequent gateways. The
internet datagram fragment format is designed so that the destination
internet module can reassemble fragments into internet datagrams.
A destination internet module unwraps the segment from the datagram
(after reassembling the datagram, if necessary) and passes it to the
destination TCP.
This simple model of the operation glosses over many details. One
important feature is the type of service. This provides information
to the gateway (or internet module) to guide it in selecting the
service parameters to be used in traversing the next network.
Included in the type of service information is the precedence of the
datagram. Datagrams may also carry security information to permit
host and gateways that operate in multilevel secure environments to
properly segregate datagrams for security considerations.
2.3. The Host Environment
The TCP is assumed to be a module in an operating system. The users
access the TCP much like they would access the file system. The TCP
may call on other operating system functions, for example, to manage
data structures. The actual interface to the network is assumed to be
controlled by a device driver module. The TCP does not call on the
network device driver directly, but rather calls on the internet
datagram protocol module which may in turn call on the device driver.
The mechanisms of TCP do not preclude implementation of the TCP in a
front-end processor. However, in such an implementation, a
host-to-front-end protocol must provide the functionality to support
the type of TCP-user interface described in this document.
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2.4. Interfaces
The TCP/user interface provides for calls made by the user on the TCP
to OPEN or CLOSE a connection, to SEND or RECEIVE data, or to obtain
STATUS about a connection. These calls are like other calls from user
programs on the operating system, for example, the calls to open, read
from, and close a file.
The TCP/internet interface provides calls to send and receive
datagrams addressed to TCP modules in hosts anywhere in the internet
system. These calls have parameters for passing the address, type of
service, precedence, security, and other control information.
2.5. Relation to Other Protocols
The following diagram illustrates the place of the TCP in the protocol
hierarchy:
+------+ +-----+ +-----+ +-----+
|Telnet| | FTP | |Voice| ... | | Application Level
+------+ +-----+ +-----+ +-----+
| | | |
+-----+ +-----+ +-----+
| TCP | | RTP | ... | | Host Level
+-----+ +-----+ +-----+
| | |
+-------------------------------+
| Internet Protocol & ICMP | Gateway Level
+-------------------------------+
|
+---------------------------+
| Local Network Protocol | Network Level
+---------------------------+
Protocol Relationships
Figure 2.
It is expected that the TCP will be able to support higher level
protocols efficiently. It should be easy to interface higher level
protocols like the ARPANET Telnet or AUTODIN II THP to the TCP.
2.6. Reliable Communication
A stream of data sent on a TCP connection is delivered reliably and in
order at the destination.
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Transmission is made reliable via the use of sequence numbers and
acknowledgments. Conceptually, each octet of data is assigned a
sequence number. The sequence number of the first octet of data in a
segment is transmitted with that segment and is called the segment
sequence number. Segments also carry an acknowledgment number which
is the sequence number of the next expected data octet of
transmissions in the reverse direction. When the TCP transmits a
segment containing data, it puts a copy on a retransmission queue and
starts a timer; when the acknowledgment for that data is received, the
segment is deleted from the queue. If the acknowledgment is not
received before the timer runs out, the segment is retransmitted.
An acknowledgment by TCP does not guarantee that the data has been
delivered to the end user, but only that the receiving TCP has taken
the responsibility to do so.
To govern the flow of data between TCPs, a flow control mechanism is
employed. The receiving TCP reports a "window" to the sending TCP.
This window specifies the number of octets, starting with the
acknowledgment number, that the receiving TCP is currently prepared to
receive.
2.7. Connection Establishment and Clearing
To identify the separate data streams that a TCP may handle, the TCP
provides a port identifier. Since port identifiers are selected
independently by each TCP they might not be unique. To provide for
unique addresses within each TCP, we concatenate an internet address
identifying the TCP with a port identifier to create a socket which
will be unique throughout all networks connected together.
A connection is fully specified by the pair of sockets at the ends. A
local socket may participate in many connections to different foreign
sockets. A connection can be used to carry data in both directions,
that is, it is "full duplex".
TCPs are free to associate ports with processes however they choose.
However, several basic concepts are necessary in any implementation.
There must be well-known sockets which the TCP associates only with
the "appropriate" processes by some means. We envision that processes
may "own" ports, and that processes can initiate connections only on
the ports they own. (Means for implementing ownership is a local
issue, but we envision a Request Port user command, or a method of
uniquely allocating a group of ports to a given process, e.g., by
associating the high order bits of a port name with a given process.)
A connection is specified in the OPEN call by the local port and
foreign socket arguments. In return, the TCP supplies a (short) local
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connection name by which the user refers to the connection in
subsequent calls. There are several things that must be remembered
about a connection. To store this information we imagine that there
is a data structure called a Transmission Control Block (TCB). One
implementation strategy would have the local connection name be a
pointer to the TCB for this connection. The OPEN call also specifies
whether the connection establishment is to be actively pursued, or to
be passively waited for.
A passive OPEN request means that the process wants to accept incoming
connection requests rather than attempting to initiate a connection.
Often the process requesting a passive OPEN will accept a connection
request from any caller. In this case a foreign socket of all zeros
is used to denote an unspecified socket. Unspecified foreign sockets
are allowed only on passive OPENs.
A service process that wished to provide services for unknown other
processes would issue a passive OPEN request with an unspecified
foreign socket. Then a connection could be made with any process that
requested a connection to this local socket. It would help if this
local socket were known to be associated with this service.
Well-known sockets are a convenient mechanism for a priori associating
a socket address with a standard service. For instance, the
"Telnet-Server" process is permanently assigned to a particular
socket, and other sockets are reserved for File Transfer, Remote Job
Entry, Text Generator, Echoer, and Sink processes (the last three
being for test purposes). A socket address might be reserved for
access to a "Look-Up" service which would return the specific socket
at which a newly created service would be provided. The concept of a
well-known socket is part of the TCP specification, but the assignment
of sockets to services is outside this specification. (See [4].)
Processes can issue passive OPENs and wait for matching active OPENs
from other processes and be informed by the TCP when connections have
been established. Two processes which issue active OPENs to each
other at the same time will be correctly connected. This flexibility
is critical for the support of distributed computing in which
components act asynchronously with respect to each other.
There are two principal cases for matching the sockets in the local
passive OPENs and an foreign active OPENs. In the first case, the
local passive OPENs has fully specified the foreign socket. In this
case, the match must be exact. In the second case, the local passive
OPENs has left the foreign socket unspecified. In this case, any
foreign socket is acceptable as long as the local sockets match.
Other possibilities include partially restricted matches.
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If there are several pending passive OPENs (recorded in TCBs) with the
same local socket, an foreign active OPEN will be matched to a TCB
with the specific foreign socket in the foreign active OPEN, if such a
TCB exists, before selecting a TCB with an unspecified foreign socket.
The procedures to establish connections utilize the synchronize (SYN)
control flag and involves an exchange of three messages. This
exchange has been termed a three-way hand shake [3].
A connection is initiated by the rendezvous of an arriving segment
containing a SYN and a waiting TCB entry each created by a user OPEN
command. The matching of local and foreign sockets determines when a
connection has been initiated. The connection becomes "established"
when sequence numbers have been synchronized in both directions.
The clearing of a connection also involves the exchange of segments,
in this case carrying the FIN control flag.
2.8. Data Communication
The data that flows on a connection may be thought of as a stream of
octets. The sending user indicates in each SEND call whether the data
in that call (and any preceeding calls) should be immediately pushed
through to the receiving user by the setting of the PUSH flag.
A sending TCP is allowed to collect data from the sending user and to
send that data in segments at its own convenience, until the push
function is signaled, then it must send all unsent data. When a
receiving TCP sees the PUSH flag, it must not wait for more data from
the sending TCP before passing the data to the receiving process.
There is no necessary relationship between push functions and segment
boundaries. The data in any particular segment may be the result of a
single SEND call, in whole or part, or of multiple SEND calls.
The purpose of push function and the PUSH flag is to push data through
from the sending user to the receiving user. It does not provide a
record service.
There is a coupling between the push function and the use of buffers
of data that cross the TCP/user interface. Each time a PUSH flag is
associated with data placed into the receiving user's buffer, the
buffer is returned to the user for processing even if the buffer is
not filled. If data arrives that fills the user's buffer before a
PUSH is seen, the data is passed to the user in buffer size units.
TCP also provides a means to communicate to the receiver of data that
at some point further along in the data stream than the receiver is
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currently reading there is urgent data. TCP does not attempt to
define what the user specifically does upon being notified of pending
urgent data, but the general notion is that the receiving process will
take action to process the urgent data quickly.
2.9. Precedence and Security
The TCP makes use of the internet protocol type of service field and
security option to provide precedence and security on a per connection
basis to TCP users. Not all TCP modules will necessarily function in
a multilevel secure environment; some may be limited to unclassified
use only, and others may operate at only one security level and
compartment. Consequently, some TCP implementations and services to
users may be limited to a subset of the multilevel secure case.
TCP modules which operate in a multilevel secure environment must
properly mark outgoing segments with the security, compartment, and
precedence. Such TCP modules must also provide to their users or
higher level protocols such as Telnet or THP an interface to allow
them to specify the desired security level, compartment, and
precedence of connections.
2.10. Robustness Principle
TCP implementations will follow a general principle of robustness: be
conservative in what you do, be liberal in what you accept from
others.
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3. FUNCTIONAL SPECIFICATION
3.1. Header Format
TCP segments are sent as internet datagrams. The Internet Protocol
header carries several information fields, including the source and
destination host addresses [2]. A TCP header follows the internet
header, supplying information specific to the TCP protocol. This
division allows for the existence of host level protocols other than
TCP.
TCP Header Format
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Source Port | Destination Port |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sequence Number |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Acknowledgment Number |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Data | |U|A|P|R|S|F| |
| Offset| Reserved |R|C|S|S|Y|I| Window |
| | |G|K|H|T|N|N| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Checksum | Urgent Pointer |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Options | Padding |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
TCP Header Format
Note that one tick mark represents one bit position.
Figure 3.
Source Port: 16 bits
The source port number.
Destination Port: 16 bits
The destination port number.
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Functional Specification
Sequence Number: 32 bits
The sequence number of the first data octet in this segment (except
when SYN is present). If SYN is present the sequence number is the
initial sequence number (ISN) and the first data octet is ISN+1.
Acknowledgment Number: 32 bits
If the ACK control bit is set this field contains the value of the
next sequence number the sender of the segment is expecting to
receive. Once a connection is established this is always sent.
Data Offset: 4 bits
The number of 32 bit words in the TCP Header. This indicates where
the data begins. The TCP header (even one including options) is an
integral number of 32 bits long.
Reserved: 6 bits
Reserved for future use. Must be zero.
Control Bits: 6 bits (from left to right):
URG: Urgent Pointer field significant
ACK: Acknowledgment field significant
PSH: Push Function
RST: Reset the connection
SYN: Synchronize sequence numbers
FIN: No more data from sender
Window: 16 bits
The number of data octets beginning with the one indicated in the
acknowledgment field which the sender of this segment is willing to
accept.
Checksum: 16 bits
The checksum field is the 16 bit one's complement of the one's
complement sum of all 16 bit words in the header and text. If a
segment contains an odd number of header and text octets to be
checksummed, the last octet is padded on the right with zeros to
form a 16 bit word for checksum purposes. The pad is not
transmitted as part of the segment. While computing the checksum,
the checksum field itself is replaced with zeros.
The checksum also covers a 96 bit pseudo header conceptually
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Functional Specification
prefixed to the TCP header. This pseudo header contains the Source
Address, the Destination Address, the Protocol, and TCP length.
This gives the TCP protection against misrouted segments. This
information is carried in the Internet Protocol and is transferred
across the TCP/Network interface in the arguments or results of
calls by the TCP on the IP.
+--------+--------+--------+--------+
| Source Address |
+--------+--------+--------+--------+
| Destination Address |
+--------+--------+--------+--------+
| zero | PTCL | TCP Length |
+--------+--------+--------+--------+
The TCP Length is the TCP header length plus the data length in
octets (this is not an explicitly transmitted quantity, but is
computed), and it does not count the 12 octets of the pseudo
header.
Urgent Pointer: 16 bits
This field communicates the current value of the urgent pointer as a
positive offset from the sequence number in this segment. The
urgent pointer points to the sequence number of the octet following
the urgent data. This field is only be interpreted in segments with
the URG control bit set.
Options: variable
Options may occupy space at the end of the TCP header and are a
multiple of 8 bits in length. All options are included in the
checksum. An option may begin on any octet boundary. There are two
cases for the format of an option:
Case 1: A single octet of option-kind.
Case 2: An octet of option-kind, an octet of option-length, and
the actual option-data octets.
The option-length counts the two octets of option-kind and
option-length as well as the option-data octets.
Note that the list of options may be shorter than the data offset
field might imply. The content of the header beyond the
End-of-Option option must be header padding (i.e., zero).
A TCP must implement all options.
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Transmission Control Protocol
Functional Specification
Currently defined options include (kind indicated in octal):
Kind Length Meaning
---- ------ -------
0 - End of option list.
1 - No-Operation.
2 4 Maximum Segment Size.
Specific Option Definitions
End of Option List
+--------+
|00000000|
+--------+
Kind=0
This option code indicates the end of the option list. This
might not coincide with the end of the TCP header according to
the Data Offset field. This is used at the end of all options,
not the end of each option, and need only be used if the end of
the options would not otherwise coincide with the end of the TCP
header.
No-Operation
+--------+
|00000001|
+--------+
Kind=1
This option code may be used between options, for example, to
align the beginning of a subsequent option on a word boundary.
There is no guarantee that senders will use this option, so
receivers must be prepared to process options even if they do
not begin on a word boundary.
Maximum Segment Size
+--------+--------+---------+--------+
|00000010|00000100| max seg size |
+--------+--------+---------+--------+
Kind=2 Length=4
[Page 18]
September 1981
Transmission Control Protocol
Functional Specification
Maximum Segment Size Option Data: 16 bits
If this option is present, then it communicates the maximum
receive segment size at the TCP which sends this segment.
This field must only be sent in the initial connection request
(i.e., in segments with the SYN control bit set). If this
option is not used, any segment size is allowed.
Padding: variable
The TCP header padding is used to ensure that the TCP header ends
and data begins on a 32 bit boundary. The padding is composed of
zeros.
3.2. Terminology
Before we can discuss very much about the operation of the TCP we need
to introduce some detailed terminology. The maintenance of a TCP
connection requires the remembering of several variables. We conceive
of these variables being stored in a connection record called a
Transmission Control Block or TCB. Among the variables stored in the
TCB are the local and remote socket numbers, the security and
precedence of the connection, pointers to the user's send and receive
buffers, pointers to the retransmit queue and to the current segment.
In addition several variables relating to the send and receive
sequence numbers are stored in the TCB.
Send Sequence Variables
SND.UNA - send unacknowledged
SND.NXT - send next
SND.WND - send window
SND.UP - send urgent pointer
SND.WL1 - segment sequence number used for last window update
SND.WL2 - segment acknowledgment number used for last window
update
ISS - initial send sequence number
Receive Sequence Variables
RCV.NXT - receive next
RCV.WND - receive window
RCV.UP - receive urgent pointer
IRS - initial receive sequence number
[Page 19]
September 1981
Transmission Control Protocol
Functional Specification
The following diagrams may help to relate some of these variables to
the sequence space.
Send Sequence Space
1 2 3 4
----------|----------|----------|----------
SND.UNA SND.NXT SND.UNA
+SND.WND
1 - old sequence numbers which have been acknowledged
2 - sequence numbers of unacknowledged data
3 - sequence numbers allowed for new data transmission
4 - future sequence numbers which are not yet allowed
Send Sequence Space
Figure 4.
The send window is the portion of the sequence space labeled 3 in
figure 4.
Receive Sequence Space
1 2 3
----------|----------|----------
RCV.NXT RCV.NXT
+RCV.WND
1 - old sequence numbers which have been acknowledged
2 - sequence numbers allowed for new reception
3 - future sequence numbers which are not yet allowed
Receive Sequence Space
Figure 5.
The receive window is the portion of the sequence space labeled 2 in
figure 5.
There are also some variables used frequently in the discussion that
take their values from the fields of the current segment.
[Page 20]
September 1981
Transmission Control Protocol
Functional Specification
Current Segment Variables
SEG.SEQ - segment sequence number
SEG.ACK - segment acknowledgment number
SEG.LEN - segment length
SEG.WND - segment window
SEG.UP - segment urgent pointer
SEG.PRC - segment precedence value
A connection progresses through a series of states during its
lifetime. The states are: LISTEN, SYN-SENT, SYN-RECEIVED,
ESTABLISHED, FIN-WAIT-1, FIN-WAIT-2, CLOSE-WAIT, CLOSING, LAST-ACK,
TIME-WAIT, and the fictional state CLOSED. CLOSED is fictional
because it represents the state when there is no TCB, and therefore,
no connection. Briefly the meanings of the states are:
LISTEN - represents waiting for a connection request from any remote
TCP and port.
SYN-SENT - represents waiting for a matching connection request
after having sent a connection request.
SYN-RECEIVED - represents waiting for a confirming connection
request acknowledgment after having both received and sent a
connection request.
ESTABLISHED - represents an open connection, data received can be
delivered to the user. The normal state for the data transfer phase
of the connection.
FIN-WAIT-1 - represents waiting for a connection termination request
from the remote TCP, or an acknowledgment of the connection
termination request previously sent.
FIN-WAIT-2 - represents waiting for a connection termination request
from the remote TCP.
CLOSE-WAIT - represents waiting for a connection termination request
from the local user.
CLOSING - represents waiting for a connection termination request
acknowledgment from the remote TCP.
LAST-ACK - represents waiting for an acknowledgment of the
connection termination request previously sent to the remote TCP
(which includes an acknowledgment of its connection termination
request).
[Page 21]
September 1981
Transmission Control Protocol
Functional Specification
TIME-WAIT - represents waiting for enough time to pass to be sure
the remote TCP received the acknowledgment of its connection
termination request.
CLOSED - represents no connection state at all.
A TCP connection progresses from one state to another in response to
events. The events are the user calls, OPEN, SEND, RECEIVE, CLOSE,
ABORT, and STATUS; the incoming segments, particularly those
containing the SYN, ACK, RST and FIN flags; and timeouts.
The state diagram in figure 6 illustrates only state changes, together
with the causing events and resulting actions, but addresses neither
error conditions nor actions which are not connected with state
changes. In a later section, more detail is offered with respect to
the reaction of the TCP to events.
NOTE BENE: this diagram is only a summary and must not be taken as
the total specification.
[Page 22]
September 1981
Transmission Control Protocol
Functional Specification
+---------+ ---------\ active OPEN
| CLOSED | \ -----------
+---------+<---------\ \ create TCB
| ^ \ \ snd SYN
passive OPEN | | CLOSE \ \
------------ | | ---------- \ \
create TCB | | delete TCB \ \
V | \ \
+---------+ CLOSE | \
| LISTEN | ---------- | |
+---------+ delete TCB | |
rcv SYN | | SEND | |
----------- | | ------- | V
+---------+ snd SYN,ACK / \ snd SYN +---------+
| |<----------------- ------------------>| |
| SYN | rcv SYN | SYN |
| RCVD |<-----------------------------------------------| SENT |
| | snd ACK | |
| |------------------ -------------------| |
+---------+ rcv ACK of SYN \ / rcv SYN,ACK +---------+
| -------------- | | -----------
| x | | snd ACK
| V V
| CLOSE +---------+
| ------- | ESTAB |
| snd FIN +---------+
| CLOSE | | rcv FIN
V ------- | | -------
+---------+ snd FIN / \ snd ACK +---------+
| FIN |<----------------- ------------------>| CLOSE |
| WAIT-1 |------------------ | WAIT |
+---------+ rcv FIN \ +---------+
| rcv ACK of FIN ------- | CLOSE |
| -------------- snd ACK | ------- |
V x V snd FIN V
+---------+ +---------+ +---------+
|FINWAIT-2| | CLOSING | | LAST-ACK|
+---------+ +---------+ +---------+
| rcv ACK of FIN | rcv ACK of FIN |
| rcv FIN -------------- | Timeout=2MSL -------------- |
| ------- x V ------------ x V
\ snd ACK +---------+delete TCB +---------+
------------------------>|TIME WAIT|------------------>| CLOSED |
+---------+ +---------+
TCP Connection State Diagram
Figure 6.
[Page 23]
September 1981
Transmission Control Protocol
Functional Specification
3.3. Sequence Numbers
A fundamental notion in the design is that every octet of data sent
over a TCP connection has a sequence number. Since every octet is
sequenced, each of them can be acknowledged. The acknowledgment
mechanism employed is cumulative so that an acknowledgment of sequence
number X indicates that all octets up to but not including X have been
received. This mechanism allows for straight-forward duplicate
detection in the presence of retransmission. Numbering of octets
within a segment is that the first data octet immediately following
the header is the lowest numbered, and the following octets are
numbered consecutively.
It is essential to remember that the actual sequence number space is
finite, though very large. This space ranges from 0 to 2**32 - 1.
Since the space is finite, all arithmetic dealing with sequence
numbers must be performed modulo 2**32. This unsigned arithmetic
preserves the relationship of sequence numbers as they cycle from
2**32 - 1 to 0 again. There are some subtleties to computer modulo
arithmetic, so great care should be taken in programming the
comparison of such values. The symbol "=<" means "less than or equal"
(modulo 2**32).
The typical kinds of sequence number comparisons which the TCP must
perform include:
(a) Determining that an acknowledgment refers to some sequence
number sent but not yet acknowledged.
(b) Determining that all sequence numbers occupied by a segment
have been acknowledged (e.g., to remove the segment from a
retransmission queue).
(c) Determining that an incoming segment contains sequence numbers
which are expected (i.e., that the segment "overlaps" the
receive window).
[Page 24]
September 1981
Transmission Control Protocol
Functional Specification
In response to sending data the TCP will receive acknowledgments. The
following comparisons are needed to process the acknowledgments.
SND.UNA = oldest unacknowledged sequence number
SND.NXT = next sequence number to be sent
SEG.ACK = acknowledgment from the receiving TCP (next sequence
number expected by the receiving TCP)
SEG.SEQ = first sequence number of a segment
SEG.LEN = the number of octets occupied by the data in the segment
(counting SYN and FIN)
SEG.SEQ+SEG.LEN-1 = last sequence number of a segment
A new acknowledgment (called an "acceptable ack"), is one for which
the inequality below holds:
SND.UNA < SEG.ACK =< SND.NXT
A segment on the retransmission queue is fully acknowledged if the sum
of its sequence number and length is less or equal than the
acknowledgment value in the incoming segment.
When data is received the following comparisons are needed:
RCV.NXT = next sequence number expected on an incoming segments, and
is the left or lower edge of the receive window
RCV.NXT+RCV.WND-1 = last sequence number expected on an incoming
segment, and is the right or upper edge of the receive window
SEG.SEQ = first sequence number occupied by the incoming segment
SEG.SEQ+SEG.LEN-1 = last sequence number occupied by the incoming
segment
A segment is judged to occupy a portion of valid receive sequence
space if
RCV.NXT =< SEG.SEQ < RCV.NXT+RCV.WND
or
RCV.NXT =< SEG.SEQ+SEG.LEN-1 < RCV.NXT+RCV.WND
[Page 25]
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