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A sliding window protocol is a feature of packet-based
data transmission Data transmission and data reception or, more broadly, data communication or digital communications is the transfer and reception of data in the form of a digital bitstream or a digitized analog signal transmitted over a point-to-point o ...
protocol Protocol may refer to: Sociology and politics * Protocol (politics), a formal agreement between nation states * Protocol (diplomacy), the etiquette of diplomacy and affairs of state * Etiquette, a code of personal behavior Science and technolog ...
s. Sliding window protocols are used where reliable in-order delivery of packets is required, such as in the
data link layer The data link layer, or layer 2, is the second layer of the seven-layer OSI model of computer networking. This layer is the protocol layer that transfers data between nodes on a network segment across the physical layer. The data link layer ...
(
OSI layer 2 The data link layer, or layer 2, is the second layer of the seven-layer OSI model of computer networking. This layer is the protocol layer that transfers data between nodes on a network segment across the physical layer. The data link layer p ...
) as well as in the
Transmission Control Protocol The Transmission Control Protocol (TCP) is one of the main protocols of the Internet protocol suite. It originated in the initial network implementation in which it complemented the Internet Protocol (IP). Therefore, the entire suite is common ...
(TCP). They are also used to improve efficiency when the channel may include high latency. Packet-based systems are based on the idea of sending a batch of data, the ''packet'', along with additional data that allows the receiver to ensure it was received correctly, perhaps a
checksum A checksum is a small-sized block of data derived from another block of digital data for the purpose of detecting errors that may have been introduced during its transmission or storage. By themselves, checksums are often used to verify data ...
. The paradigm is similar to a window sliding sideways to allow entry of fresh packets and reject the ones that have already been acknowledged. When the receiver verifies the data, it sends an acknowledgment signal, or "ACK", back to the sender to indicate it can send the next packet. In a simple
automatic repeat request Automatic repeat request (ARQ), also known as automatic repeat query, is an error-control method for data transmission that uses acknowledgements (messages sent by the receiver indicating that it has correctly received a packet) and timeouts ...
protocol (ARQ), the sender stops after every packet and waits for the receiver to ACK. This ensures packets arrive in the correct order, as only one may be sent at a time. The time that it takes for the ACK signal to be received may represent a significant amount of time compared to the time needed to send the packet. In this case, the overall
throughput Network throughput (or just throughput, when in context) refers to the rate of message delivery over a communication channel, such as Ethernet or packet radio, in a communication network. The data that these messages contain may be delivered ove ...
may be much lower than theoretically possible. To address this, sliding window protocols allow a selected number of packets, the ''window'', to be sent without having to wait for an ACK. Each packet receives a sequence number, and the ACKs send back that number. The protocol keeps track of which packets have been ACKed, and when they are received, sends more packets. In this way, the window ''slides'' along the stream of packets making up the transfer. Sliding windows are a key part of many protocols. It is a key part of the TCP protocol, which inherently allows packets to arrive out of order, and is also found in many
file transfer protocol The File Transfer Protocol (FTP) is a standard communication protocol used for the transfer of computer files from a server to a client on a computer network. FTP is built on a client–server model architecture using separate control and dat ...
s like UUCP-g and
ZMODEM ZMODEM is an inline file transfer protocol developed by Chuck Forsberg in 1986, in a project funded by Telenet in order to improve file transfers on their X.25 network. In addition to dramatically improved performance compared to older protocol ...
as a way of improving efficiency compared to non-windowed protocols like XMODEM. See also
SEAlink Sealink was a ferry company based in the United Kingdom from 1970 to 1984, operating services to France, Belgium, the Netherlands, Isle of Man, Channel Islands, Isle of Wight and Ireland. Ports served by the company included: Dover, Folkesto ...
.


Basic concept

Conceptually, each portion of the transmission (packets in most data link layers, but bytes in TCP) is assigned a unique consecutive sequence number, and the receiver uses the numbers to place received packets in the correct order, discarding duplicate packets and identifying missing ones. The problem with this is that there is no limit on the size of the sequence number that can be required. By placing limits on the number of packets that can be transmitted or received at any given time, a sliding window protocol allows an unlimited number of packets to be communicated using fixed-size sequence numbers. The term "window" on the transmitter side represents the logical boundary of the total number of packets yet to be acknowledged by the receiver. The receiver informs the transmitter in each acknowledgment packet the current maximum receiver buffer size (window boundary). The TCP header uses a 16 bit field to report the receiver window size to the sender. Therefore, the largest window that can be used is 216 = 64 kilobytes. In slow-start mode, the transmitter starts with low packet count and increases the number of packets in each transmission after receiving acknowledgment packets from receiver. For every ack packet received, the window slides by one packet (logically) to transmit one new packet. When the window threshold is reached, the transmitter sends one packet for one ack packet received. If the window limit is 10 packets then in slow start mode the transmitter may start transmitting one packet followed by two packets (before transmitting two packets, one packet ack has to be received), followed by three packets and so on until 10 packets. But after reaching 10 packets, further transmissions are restricted to one packet transmitted for one ack packet received. In a simulation this appears as if the window is moving by one packet distance for every ack packet received. On the receiver side also the window moves one packet for every packet received. The sliding window method ensures that traffic congestion on the network is avoided. The application layer will still be offering data for transmission to TCP without worrying about the network traffic congestion issues as the TCP on sender and receiver side implement sliding windows of packet buffer. The window size may vary dynamically depending on network traffic. For the highest possible
throughput Network throughput (or just throughput, when in context) refers to the rate of message delivery over a communication channel, such as Ethernet or packet radio, in a communication network. The data that these messages contain may be delivered ove ...
, it is important that the transmitter is not forced to stop sending by the sliding window protocol earlier than one
round-trip delay time In telecommunications, round-trip delay (RTD) or round-trip time (RTT) is the amount of time it takes for a signal to be sent ''plus'' the amount of time it takes for acknowledgement of that signal having been received. This time delay includes pr ...
(RTT). The limit on the amount of data that it can send before stopping to wait for an acknowledgment should be larger than the
bandwidth-delay product In data communications, the bandwidth-delay product is the product of a data link's capacity (in bits per second) and its round-trip delay time (in seconds). The result, an amount of data measured in bits (or bytes), is equivalent to the maxim ...
of the communications link. If it is not, the protocol will limit the effective
bandwidth Bandwidth commonly refers to: * Bandwidth (signal processing) or ''analog bandwidth'', ''frequency bandwidth'', or ''radio bandwidth'', a measure of the width of a frequency range * Bandwidth (computing), the rate of data transfer, bit rate or thr ...
of the link.


Motivation

In any communication protocol based on
automatic repeat request Automatic repeat request (ARQ), also known as automatic repeat query, is an error-control method for data transmission that uses acknowledgements (messages sent by the receiver indicating that it has correctly received a packet) and timeouts ...
for
error control In information theory and coding theory with applications in computer science and telecommunication, error detection and correction (EDAC) or error control are techniques that enable reliable delivery of digital data over unreliable communica ...
, the receiver must acknowledge received packets. If the transmitter does not receive an acknowledgment within a reasonable time, it re-sends the data. A transmitter that does not get an acknowledgment cannot know if the receiver actually received the packet; it may be that it was lost or damaged in transmission. If the
error detection In information theory and coding theory with applications in computer science and telecommunication, error detection and correction (EDAC) or error control are techniques that enable reliable delivery of digital data over unreliable communi ...
mechanism reveals corruption, the packet will be ignored by the receiver and a negative or duplicate acknowledgement will be sent by the receiver. The receiver may also be configured to not send any acknowledgement at all. Similarly, the receiver is usually uncertain about whether its acknowledgements are being received. It may be that an acknowledgment was sent, but was lost or corrupted in the transmission medium. In this case, the receiver must acknowledge the retransmission to prevent the data being continually resent, but must otherwise ignore it.


Protocol operation

The transmitter and receiver each have a current sequence number ''nt'' and ''nr'', respectively. They each also have a window size ''wt'' and ''wr''. The window sizes may vary, but in simpler implementations they are fixed. The window size must be greater than zero for any progress to be made. As typically implemented, ''nt'' is the next packet to be transmitted, i.e. the sequence number of the first packet not yet transmitted. Likewise, ''nr'' is the first packet not yet received. Both numbers are
monotonically increasing In mathematics, a monotonic function (or monotone function) is a function between ordered sets that preserves or reverses the given order. This concept first arose in calculus, and was later generalized to the more abstract setting of orde ...
with time; they only ever increase. The receiver may also keep track of the highest sequence number yet received; the variable ''ns'' is one more than the sequence number of the highest sequence number received. For simple receivers that only accept packets in order (''wr'' = 1), this is the same as ''nr'', but can be greater if ''wr'' > 1. Note the distinction: all packets below ''nr'' have been received, no packets above ''ns'' have been received, and between ''nr'' and ''ns'', some packets have been received. When the receiver receives a packet, it updates its variables appropriately and transmits an acknowledgment with the new ''nr''. The transmitter keeps track of the highest acknowledgment it has received ''na''. The transmitter knows that all packets up to, but not including ''na'' have been received, but is uncertain about packets between ''na'' and ''ns''; i.e. ''na'' ≤ ''nr'' ≤ ''ns''. The sequence numbers always obey the rule that ''na'' ≤ ''nr'' ≤ ''ns'' ≤ ''nt'' ≤ ''na'' + ''wt''. That is: * ''na'' ≤ ''nr'': The highest acknowledgement received by the transmitter cannot be higher than the highest ''nr'' acknowledged by the receiver. * ''nr'' ≤ ''ns'': The span of fully received packets cannot extend beyond the end of the partially received packets. * ''ns'' ≤ ''nt'': The highest packet received cannot be higher than the highest packet sent. * ''nt'' ≤ ''na'' + ''wt'': The highest packet sent is limited by the highest acknowledgement received and the transmit window size.


Transmitter operation

Whenever the transmitter has data to send, it may transmit up to ''wt'' packets ahead of the latest acknowledgment ''na''. That is, it may transmit packet number ''nt'' as long as ''nt'' < ''na''+''wt''. In the absence of a communication error, the transmitter soon receives an acknowledgment for all the packets it has sent, leaving ''na'' equal to ''nt''. If this does not happen after a reasonable delay, the transmitter must retransmit the packets between ''na'' and ''nt''. Techniques for defining "reasonable delay" can be extremely elaborate, but they only affect efficiency; the basic reliability of the sliding window protocol does not depend on the details.


Receiver operation

Every time a packet numbered ''x'' is received, the receiver checks to see if it falls in the receive window, ''nr'' ≤ ''x'' < ''nr''+''wr''. (The simplest receivers only have to keep track of one value ''nr''=''ns''.) If it falls within the window, the receiver accepts it. If it is numbered ''nr'', the receive sequence number is increased by 1, and possibly more if further consecutive packets were previously received and stored. If ''x'' > ''nr'', the packet is stored until all preceding packets have been received.Peterson, Larry L. & Davie, Bruce S.

, Morgan Kaufmann, 2000.
If ''x''≥''ns'', the latter is updated to ''ns''=''x''+1. If the packet's number is not within the receive window, the receiver discards it and does not modify ''nr'' or ''ns''. Whether the packet was accepted or not, the receiver transmits an acknowledgment containing the current ''nr''. (The acknowledgment may also include information about additional packets received between ''nr'' and ''ns'', but that only helps efficiency.) Note that there is no point having the receive window ''wr'' larger than the transmit window ''wt'', because there is no need to worry about receiving a packet that will never be transmitted; the useful range is 1 ≤ ''wr'' ≤ ''wt''.


Sequence number range required

So far, the protocol has been described as if sequence numbers are of unlimited size, ever-increasing. However, rather than transmitting the full sequence number ''x'' in messages, it is possible to transmit only ''x'' mod ''N'', for some finite ''N''. (''N'' is usually a
power of 2 A power of two is a number of the form where is an integer, that is, the result of exponentiation with number two as the base and integer  as the exponent. In a context where only integers are considered, is restricted to non-negative ...
.) For example, the transmitter will only receive acknowledgments in the range ''na'' to ''nt'', inclusive. Since it guarantees that ''nt''−''na'' ≤ ''wt'', there are at most ''wt''+1 possible sequence numbers that could arrive at any given time. Thus, the transmitter can unambiguously decode the sequence number as long as ''N'' > ''wt''. A stronger constraint is imposed by the receiver. The operation of the protocol depends on the receiver being able to reliably distinguish new packets (which should be accepted and processed) from retransmissions of old packets (which should be discarded, and the last acknowledgment retransmitted). This can be done given knowledge of the transmitter's window size. After receiving a packet numbered ''x'', the receiver knows that ''x'' < ''na''+''wt'', so ''na'' > ''x''−''wt''. Thus, packets numbered ''x''−''wt'' will never again be retransmitted. The lowest sequence number we will ever receive in future is ''ns''−''wt'' The receiver also knows that the transmitter's ''na'' cannot be higher than the highest acknowledgment ever sent, which is ''nr''. So the highest sequence number we could possibly see is ''nr''+''wt'' ≤ ''ns''+''wt''. Thus, there are 2''wt'' different sequence numbers that the receiver can receive at any one time. It might therefore seem that we must have ''N'' ≥ 2''wt''. However, the actual limit is lower. The additional insight is that the receiver does not need to distinguish between sequence numbers that are too low (less than ''nr'') or that are too high (greater than or equal to ''ns''+''wr''). In either case, the receiver ignores the packet except to retransmit an acknowledgment. Thus, it is only necessary that ''N'' ≥ ''wt''+''wr''. As it is common to have ''wr''<''wt'' (e.g. see Go-Back-N below), this can permit larger ''wt'' within a fixed ''N''.


Examples


The simplest sliding window: stop-and-wait

Although commonly distinguished from the sliding-window protocol, the
stop-and-wait ARQ Stop-and-wait ARQ, also referred to as alternating bit protocol, is a method in telecommunications to send information between two connected devices. It ensures that information is not lost due to dropped packets and that packets are received ...
protocol is actually the simplest possible implementation of it. The transmit window is 1 packet, and the receive window is 1 packet. Thus, ''N'' = 2 possible sequence numbers (conveniently represented by a single
bit The bit is the most basic unit of information in computing and digital communications. The name is a portmanteau of binary digit. The bit represents a logical state with one of two possible values. These values are most commonly represente ...
) are required.


Ambiguity example

The transmitter alternately sends packets marked "odd" and "even". The acknowledgments likewise say "odd" and "even". Suppose that the transmitter, having sent an odd packet, did not wait for an odd acknowledgment, and instead immediately sent the following even packet. It might then receive an acknowledgment saying "expecting an odd packet next". This would leave the transmitter in a quandary: has the receiver received both of the packets, or neither?


Go-Back-N

Go-Back-N ARQ Go-Back-''N'' ARQ is a specific instance of the automatic repeat request (ARQ) protocol, in which the sending process continues to send a number of frames specified by a ''window size'' even without receiving an acknowledgement (ACK) packet fr ...
is the sliding window protocol with ''wt''>1, but a fixed ''wr''=1. The receiver refuses to accept any packet but the next one in sequence. If a packet is lost in transit, following packets are ignored until the missing packet is retransmitted, a minimum loss of one
round-trip time In telecommunications, round-trip delay (RTD) or round-trip time (RTT) is the amount of time it takes for a signal to be sent ''plus'' the amount of time it takes for acknowledgement of that signal having been received. This time delay includes pr ...
. For this reason, it is inefficient on links that suffer frequent packet loss.


Ambiguity example

Suppose that we are using a 3-bit sequence number, such as is typical for
HDLC High-Level Data Link Control (HDLC) is a bit-oriented code-transparent synchronous data link layer protocol developed by the International Organization for Standardization (ISO). The standard for HDLC is ISO/IEC 13239:2002. HDLC provides both ...
. This gives ''N''=23=8. Since ''wr''=1, we must limit ''wt''≤7. This is because, after transmitting 7 packets, there are 8 possible results: Anywhere from 0 to 7 packets could have been received successfully. This is 8 possibilities, and the transmitter needs enough information in the acknowledgment to distinguish them all. If the transmitter sent 8 packets without waiting for acknowledgment, it could find itself in a quandary similar to the stop-and-wait case: does the acknowledgment mean that all 8 packets were received successfully, or none of them?


Selective repeat

The most general case of the sliding window protocol is
Selective Repeat ARQ Selective Repeat ARQ/Selective Reject ARQ is a specific instance of the automatic repeat request (ARQ) protocol used to manage sequence numbers and retransmissions in reliable communications. Summary Selective Repeat is part of the automatic ...
. This requires a much more capable receiver, which can accept packets with sequence numbers higher than the current ''nr'' and store them until the gap is filled in. The advantage, however, is that it is not necessary to discard following correct data for one round-trip time before the transmitter can be informed that a retransmission is required. This is therefore preferred for links with low reliability and/or a high bandwidth-delay product. The window size ''wr'' need only be larger than the number of ''consecutive'' lost packets that can be tolerated. Thus, small values are popular; ''wr''=2 is common.


Ambiguity example

The extremely popular HDLC protocol uses a 3-bit sequence number, and has optional provision for selective repeat. However, if selective repeat is to be used, the requirement that ''nt''+''nr'' ≤ 8 must be maintained; if ''wr'' is increased to 2, ''wt'' must be decreased to 6. Suppose that ''wr'' =2, but an unmodified transmitter is used with ''wt'' =7, as is typically used with the go-back-N variant of HDLC. Further suppose that the receiver begins with ''nr'' =''ns'' =0. Now suppose that the receiver sees the following series of packets (all modulo 8): : 0 1 2 3 4 5 6 ''(pause)'' 0 Because ''wr'' =2, the receiver will accept and store the final packet 0 (thinking it is packet 8 in the series), while requesting a retransmission of packet 7. However, it is also possible that the transmitter failed to receive any acknowledgments and has retransmitted packet 0. In this latter case, the receiver would accept the wrong packet as packet 8. The solution is for the transmitter to limit ''wt'' ≤6. With this restriction, the receiver knows that if all acknowledgments were lost, the transmitter would have stopped after packet 5. When it receives packet 6, the receiver can infer that the transmitter received the acknowledgment for packet 0 (the transmitter's ''na'' ≥1), and thus the following packet numbered 0 must be packet 8.


Extensions

There are many ways that the protocol can be extended: * The above examples assumed that packets are never reordered in transmission; they may be lost in transit (
error detection In information theory and coding theory with applications in computer science and telecommunication, error detection and correction (EDAC) or error control are techniques that enable reliable delivery of digital data over unreliable communi ...
makes corruption equivalent to loss), but will never appear out of order. The protocol can be extended to support packet reordering, as long as the distance can be bounded; the sequence number modulus ''N'' must be expanded by the maximum misordering distance. * It is possible to not acknowledge every packet, as long as an acknowledgment is sent eventually if there is a pause. For example, TCP normally acknowledges every second packet. ** It is common to inform the transmitter immediately if a gap in the packet sequence is detected. HDLC has a special REJ (reject) packet for this. * The transmit and receive window sizes may be changed during communication, as long as their sum remains within the limit of ''N''. Normally, they are each assigned maximum values that respect that limit, but the working value at any given time may be less than the maximum. In particular: ** It is common to reduce the transmit window size to slow down transmission to match the link's speed, avoiding
saturation Saturation, saturated, unsaturation or unsaturated may refer to: Chemistry * Saturation, a property of organic compounds referring to carbon-carbon bonds **Saturated and unsaturated compounds ** Degree of unsaturation **Saturated fat or fatty aci ...
or congestion. ** One common simplification of selective-repeat is so called SREJ-REJ ARQ. This operates with ''wr''=2 and buffers packets following a gap, but only allows a single lost packet; while waiting for that packet, ''wr''=1 and if a second packet is lost, no more packets are buffered. This gives most of the performance benefit of the full selective-repeat protocol, with a simpler implementation.


See also

*
Federal Standard 1037C Federal Standard 1037C, titled Telecommunications: Glossary of Telecommunication Terms, is a United States Federal Standard issued by the General Services Administration pursuant to the Federal Property and Administrative Services Act of 1949, a ...
*
Compound TCP Compound TCP (CTCP) is a Microsoft algorithm that was introduced as part of the Windows Vista and Window Server 2008 TCP stack. It is designed to aggressively adjust the sender's congestion window to optimise TCP for connections with large ban ...
* Serial number arithmetic *
TCP Fast Open In computer networking, TCP Fast Open (TFO) is an extension to speed up the opening of successive Transmission Control Protocol (TCP) connections between two endpoints. It works by using a ''TFO cookie'' (a TCP option), which is a cryptographic co ...


References

*Comer, Douglas E. "Internetworking with TCP/IP, Volume 1: Principles, Protocols, and Architecture", Prentice Hall, 1995. {{ISBN, 0-13-216987-8


External links

* RFC 1323 - TCP Extensions for High Performance
TCP window scaling and broken routers
2004 Communication Data transmission