From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc663.txt | 1254 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1254 insertions(+) create mode 100644 doc/rfc/rfc663.txt (limited to 'doc/rfc/rfc663.txt') diff --git a/doc/rfc/rfc663.txt b/doc/rfc/rfc663.txt new file mode 100644 index 0000000..3116b44 --- /dev/null +++ b/doc/rfc/rfc663.txt @@ -0,0 +1,1254 @@ + + + + +Network Working Group Rajendra K. Kanodia +Request for Comments #663 MIT, Project MAC +NIC #31387 November 29, 1974 + + + + A LOST MESSAGE DETECTION AND RECOVERY PROTOCOL + + +1.0 INTRODUCTION + + +The current Host-to-Host protocol does not provide for the +following three aspects of network communication: + + 1. detection of messages lost in the transmission path + 2. detection of errors in the data + 3. procedures for recovery in the event of lost messages or + data errors. + + +In this memo we propose an extension to the Host-to-Host protocol +that will allow detection of lost messages and an orderly +recovery from this situation. If Host-to-Host protocol were to +be amended to allow for detection of errors in the data, it is +expected that the recovery procedures proposed here will apply. + + +With the present protocol, it may some times be possible to +detect loss of messages in the transmission path. However, often +a lost message (especially one on a control link) simply results +in an inconsistent state of a network connection. One frequent +(and frustrating) symptom of a message loss on a control link has +been the "lost allocate" problem which results in a "paralyzed" +connection. The NCP (Network Control Program) at the receiving +site believes that sender has sufficient allocation for a +connection, whereas the NCP of the sending host believes that it +has no allocation (due to either loss of or error in a message +that contained the allocate command). The result is that the +sending site can not transmit any more messages over the +connection. This problem was reported in the NWG-RFC #467 by +Burchfiel and Tomlinson. They also proposed an extension to the +Host-to-Host protocol which allows for resynchronization of the +connection status. Their proposed solution was opposed by Edwin +Meyer (NWG-RFC #492) and Wayne Hathaway (NWG-RFC #512) on the +grounds that it tended to mask the basic problem of loss of +messages and they suggested that the fundamental problem of +message loss should be solved rather than its symptoms. As an +alternative to the solution proposed in NWG-RFC #467, Wayne +Hathaway suggested that Host-to-Host protocol header could be +extended to include a "Sequence Control Byte" to allow detection +of lost messages. At about the same time Jon Postel suggested a +similar scheme using message numbers (NWG-RFC #516). A little +later David Walden proposed that four unused bits of the message +sequence number (in the IMP leader) be utilized for sequencing + + + - 1 - + + + + + + + + + + +messages (NWG-RFC #534). His scheme is similar to those proposed +by Postel and Hathaway; however it has the advantage that +Host-to-Host protocol mechanisms can be tied into the IMP-to-Host +protocol mechanisms. + + +The protocol extension proposed here uses the four bits of the +message sequence number in the message leader for detection of +lost messages. However, to facilitate recovery, it uses another +eight bit field (presently unused) in the 72 bit header of the +regular messages. In the next section of this paper we discuss +some of the basic ideas underlying our protocol. In section 3, +we provide a description of the protocol. It is our intention +that section 3 be a self-contained and complete description of +the protocol. + + + +2.0 BASIC IDEAS + + +The purpose of this section is to provide a gentle introduction +to the central ideas on which this protocol is based. Roughly +speaking, our protocol can be divided into three major +components. First is the mechanism for detecting loss of +messages. Second is the exchange of information between the +sender and the receiver in the event of a message loss. For +reasons that will soon become obvious, we have termed this area +as "Exchange of Control Messages". The third component of our +protocol is the method of retransmission of lost messages. In +this section, we have reversed the order of discussion for the +second and third components, because the mechanisms for exchange +of control messages depend heavily upon the retransmission +methods. + + +A careful reader will find that several minor issues have been +left unresolved in this section. He (or she) should remember +that this section is not intended to be a complete description of +the protocol. Hopefully, we have resolved most of these issues +in the formal description of the protocol provided in the section +3. + + +2.1 DETECTION OF LOSS OF MESSAGES + + +The 32 bit Host-to-IMP and IMP-to-Host leaders contain a 12 bit +message-id in bit positions 17 to 28 (BBN Report #1822). The +Host-to-Host protocol (NIC 8246) uses 8 bits of the message-id +(bit positions 17 to 24) as a link number. The remaining 4 bits +of the message-id (bits 25 to 28) are presently unused. For the +purposes of the protocol to be presented here, we define these + + + - 2 - + + + + + + + + + + +four bits to be the message sequence number (MSN in short) +associated with the link. Thus message-id consists of an eight +bit link number and a four bit message sequence number. The four +bit MSN provides a sixteen element sequence number for each link. +A network connection has a sending host (referred to as "sender" +henceforth), a receiving host (referred to as receiver +henceforth), and a link on which messages are transmitted. In +our protocol the sender starts communication with the value of +MSN set to one (i.e. the first message on any link has one in its +MSN field.) For the next message on the same link the value of +MSN is increased by one. When the value of MSN becomes 15 the +next value chosen is one. This results in the following sequence +1, 2, ...., 13, 14, 15, 1, 2, ...., etc. The receiver can detect +loss of messages by examining this sequence. Each hole +corresponds to a lost message. Notice that the detection +mechanism will fail if a sequence of exactly 15 messages were to +be lost. For the time being, we shall assume that the +probability of loosing a sequence of exactly 15 messages is +negligible. However, we shall later provide a status exchange +mechanism (Section 2.6) that can be used to prevent this failure. + + +Notice that in the sequence described above we have omitted the +value zero. Following a suggestion made by Hathaway (NWG-RFC +#512) and Walden (NWG-RFC #534) the new protocol uses the value +zero to indicate to the receiving host that the sending host is +not using message sequence numbers. We, in fact, extend the +meaning associated with the MSN value zero to imply that the +sending host has not implemented the detection and error recovery +protocol being proposed here. + + + +2.2 COMPATIBILITY + + +The discussion above brings us to the issue of compatibility +between the present and the new protocols. Let us define the +hosts with the present protocol to be type A and the hosts with +the new protocol to be type B. We have three situations: + + 1. Type A communicating with type A: there is no + difference from the present situation. + 2. Type A communicating with type B: from the zero value + MSNs in messages sent by the type A host, the type B + host can detect the fact that the other host is a type A + host. Therefore the type B host can simulate the + behaviour of a type A host in its communication with the + other host, and the type A host will not be confused. + As we will see later that this simulation is really + simple and can be easily applied selectively. + 3. Type B host communicating with type B: Both hosts can + detect the fact that the other host is a type B host and + + + - 3 - + + + + + + + + + + + use the message detection and error recovery protocol. + + +There is one difficulty here that we have not yet resolved. When +starting communication how does a type B host know whether the +other host is type A or type B? This difficulty can be resolved +by assuming that a type A host will not be confused by a non-zero +MSN in the messages that it receives. This assumption is not +unreasonable because a type A host can easily meet this +requirement by making a very simple change to its NCP (the +Network Control Program), if it does not already satisfy this +requirement. Another assumption that is crucial to our protocol, +is that the type A hosts always set the MSN field of messages +(they send out) to zero. As of this writing, the author believes +that no hosts are using the MSN field and therefore no +compatibility problem should arise. + + +2.3 RETRANSMISSION OF MESSAGES + + +Before getting down to the details of the actual protocol, we +will attempt here to explain the essential ideas underlying this +protocol by considering a somewhat simplified situation. +Consider a logical communication channel X, which has at its +disposal an inexhaustible supply of physical communication +channels C(1), C(2), C(3), ........, etc. (See footnote #1) +Channel X is to be used for transmission of messages. In +addition to carrying the data, these messages contain (1) the +channel name X, and (2) a Message Sequence Number (MSN). Let us +denote the sender on this channel by S and the receiver by R. +Let us also assume that at the start of the communication, R and +S are synchronized such that R is prepared to receive messages +for logical channel X on the physical channel C(1) and S is +prepared for sending these messages on C(1). S starts by pumping +a sequence of messages M(1), M(2), M(3), ........, M(n) into +channel C(1). Since these messages contain sequence numbers, R +is able to detect loss of messages on the channel C(1). Suppose +now that R discovers that message number K (where K R.MSN then a message has been lost and the +synch-state R(X', CN, MSN) changes to R(X', CN+1, MSN). Notice +that we have not yet said anything about the situation M.CN > +R.CN. We will later describe a scheme for using this case to +provide for error correction on the control channel itself. + + + +2.4 EXCHANGE OF CONTROL INFORMATION + + +So far we have discussed two schemes for the detection and +retransmission aspects of the lost-message problem. In this + + + - 6 - + + + + + + + + + + +section, we discuss methods by which the receiver communicates to +the sender the fact of loss of messages. + + +We continue with the scenario developed in the above section with +a small change. For the purposes of the discussion that is about +to follow we shall assume that there are actually two perfect +channels available for exchange of control messages. One channel +from S to R named S->R, and the other from R to S named R->S. +The purpose of S->R will become clear in a moment. In order to +let R communicate the fact of loss of messages to S, We provide a +control message called L__o_s_t__M_e_s_s_a_g_e__f_r_o_m__R_e_c_e_i_v_e_r (LMR) which is +of the following form: LMR(X, CN, MSN), where X is the name of +the channel, CN is the new C-channel number, and MSN is the +message sequence number of the lost message. If more than one +message has been lost, then R uses the MSN of the first message +only. When S receives this message, it can restart communication +at the point where the break occurred using the C-channel +specified by the LMR message. This will restore the +communication path X. What happens if S can not restore +communication at the break point because it does not have the +relevant messages any more? This issue can be solved in one of +the two ways: either let the protocol specify a fixed rule that S +will be required to close the connection, or the protocol could +allow S and R (and may be the users on whose behalf S and R are +communicating on X) to negotiate the action to be taken. For the +protocol to be presented here, we have taken the approach that S +may, at its option, either close the connection or negotiate with +R. What action a specific host takes can either be built into +its NCP or determined dynamically. Those hosts that do not have +very powerful machines will probably chose the static option of +closing the connection; other hosts may make the decision +depending upon the circumstances. For example, a host may decide +that loss of messages is not acceptable during file transfers +whereas loss of a single message can be ignored for terminal +output to interactive users. A host might even let the user +processes decide the course of action to be taken. If S +determines that it can not retransmit lost messages, it may want +to let R decide what action is to be taken. If S so decides, +then it may communicate this fact to R by transmitting a +_L_o_s_t__M_e_s_s_a_g_e__f_r_o_m__S_e_n_d_e_r (LMS) control message to R on the +channel S->R. An LMS message is of the following form: LMS(X, +CN, MSN, COUNT), where X is the name of the channel, CN is the +name of the C-channel obtained from the LMR message, MSN is the +message sequence number of the first message in the sequence of +lost messages, and COUNT is the number of messages in the +sequence. S resets its own synch-state for connection X to S(X, +CN, MSN+COUNT). When S has informed R of its inability to +retransmit lost messages, the burden of the decision falls on R, +and S simply awaits R's reply before taking any action for the +channel X. When R receives the LMS, it may either decide that +loss is unacceptable and close the connection, or it may decide +to let S continue. In the later case R informs S of its decision + + + - 7 - + + + + + + + + + + +to continue by transmitting a L__o_s_s__o_f__M_e_s_s_a_g_e__A_c_c_e_p_t_a_b_l_e (LMA) +control message to S. Upon receiving the LMA control message, S +resumes transmission on X. To avoid the possibility of errors in +exchange of control messages, the LMA control message is +specified to be an exact replica of the LMS control message, +except for the message code which determines whether a control +message is LMA or LMS or something else. + + +In general, a sending host has only a limited amount of memory +available for storing messages for possible retransmission later. +In section 2.6 we provide a status exchange mechanism that can be +used to determine when to discard these messages. + + + +2.5 RECOVERY ON CONTROL LINKS + + +We continue our discussion with the scenario developed in the +previous section. The receiver R may detect loss of messages on +control channels by examining the message sequence numbers on the +messages. When R detects that a message has been lost on the +channel S->R, it (R) may transmit an LMR to S on R->S +communicating the fact of loss of messages. When S receives the +LMR for the control link, it must either retransmit the lost +messages, or "close" the connection. (In the context of +Host-to-Host protocol, closing the network connection for control +link implies exchange of reset commands, which has the effect of +reinitializing all communication between R and S.) For control +links, S does not have the option of sending an LMS to the +receiver. If S can not retransmit the lost messages then it +aborts the output queue (if any) for the channel S->R, and +inserts a Reset command at the break point. Essentially, we are +specifying that if S can not retransmit lost control messages +then the error would be considered irrecoverable and fatal. All +user communication between S and R is broken and must be +restarted from the beginning. + + +In the above paragraph, we considered the situation in which R +was able to detect the loss of messages. It is however possible +that it is the last message transmitted on S->R that is lost. In +this case, R will not be aware of the loss. In this situation, +recovery can be initiated only if S can either positively +determine or simply suspect that a message has been lost. In +general, after having transmitted a control message, S would be +expecting some sort of response from R. For example, if S +transmits a Request-for-Connection (RFC) control message to R, S +expects R to reply either with a Close (CLS) command or another +RFC. If, after an appropriate time interval has elapsed and S +has received no reply from R, our protocol specifies that S may +retransmit the control message. In retransmitting, S must use + + + - 8 - + + + + + + + + + + +the same C-channel and MSN values that were used for the original +message. Since R can, now, receive duplicate copies, we +stipulate that if R receives a duplicate of the message that it +has already received, it may simply ignore the duplicate. + + + +2.6 SOME OTHER PROBLEMS + + +There are two problems that have not yet been solved. First, a +sending host will usually have only a limited amount of buffer +space in which it can save messages for possible later +retransmission. So far, we have not provided any method by which +a host may positively determine whether the receiver has +correctly received a certain message or not. Thus it has no firm +basis on which it may decide to release the space used up by +messages that have been already transmitted. The second problem +is created by our recycling the message sequence numbers. For +the MSN mechanism to work correctly, it is essential that at any +given instant of time there be no more than 15 messages in the +transmission path. If there were more than 15 messages, some of +these messages would have same MSN and LRN, and if one of these +messages were to be lost, it would be impossible to identify the +lost message. However, the second problem should not arise in +the ARPA Network, since the IMP sub-network will not allow more +than eight outstanding messages between any host pair (NWG-RFC +#660). + + +We can solve both these problems by a simple yet highly flexible +scheme. In this scheme, there are two new control messages. One +of these, called R__e_q_u_e_s_t S__t_a_t_u_s _f_r_o_m S__e_n_d_e_r (RSS), can be used by +the sending host to query the receiver regarding the receiver's +synch-state. The receiver can supply its copies of C-channel +number and MSN for a transmission path by sending a S__t_a_t_u_s _f_r_o_m +R__e_c_e_i_v_e_r (SFR) control message over the control channel. An SFR +provides positive acknowledgement; differing with the usual +acknowledgement schemes in only that here acknowledgement is +provided only upon demand. Upon receiving SFR, the sender knows +exactly which messages have been properly delivered, and it may +free the buffer space used by these messages. The RSS and SFR +scheme can also be used to ensure that there are no more than +fifteen messages in the transmission path at any given time. + + + + + + + + + + + + - 9 - + + + + + + + + + + +3.0 LOST MESSAGE DETECTION AND RECOVERY PROTOCOL + + +This protocol is proposed as an amendment to the Host-to-Host +Protocol for the purpose of letting hosts detect the loss of +messages in the network. It also provides recovery procedures +from such losses. This protocol is divided into two parts. Part +1 states the compatibility requirements. Part 2 states the new +protocol and must be implemented by hosts that desire to have the +ability to recover from loss of messages in the network. The +reader will find many comments interspersed throughout the +description of this protocol. These comments are not part of the +protocol and are provided solely for the purpose of improving the +reader's understanding of this protocol. + + +The terminology used in this protocol is similar to that used in +the Host-to-Host protocol. We speak of a "network connection" +between a pair of hosts, called the "receiver" and the "sender." +A network connection is described by a pair of socket numbers, +and once established, a network connection is associated with a +link (which is described by a link number.) A network connection +is a logical communication path and the link assigned to it is a +physical communication path. In addition to links associated +with the network connections, there are "control-links" for the +transmission of "control commands." When we use the term +"connection" it may refer to either a network connection or the +link assigned to it; the context decides which one. The term +"links" encompasses the connection-associated-links as well as +control-links. Notice that a receiver of a connection may +transmit control commands regarding this connection. + + +3.1 DEFINTIONS + + +3.1.1 HOST TYPE "A" + + +Those hosts that have not adopted the part 2 of this protocol +amendment will be known as type A hosts. + +(Comment: All existing hosts are type A hosts.) + + +3.1.2 HOST TYPE "B" + + +Those hosts, that adopt the part 2 of this protocol amendment +will be known as type B hosts. + + + + + + - 10 - + + + + + + + + + + +3.1.3 MESSAGE SEQUENCE NUMBER (MSN) + + +A four bit number associated with regular messages and contained +in the bits 25 through 28 of the Host-to-IMP and IMP-to-Host +leaders for regular messages [BBN Report No. 1822]. This number +is used by the type B hosts to detect loss of messages on a +given link. Type A hosts always set the MSN (for the messages +they send out) to zero. When in use by a type B host, the first +message on a link (after the connection has been established) has +the MSN value of one. For each successive message on this link, +the MSN value is increased by one until it reaches a value of 15. +The next message has the MSN value of one. + + +(Comments: Type B hosts will use the MSN mechanism only when +communicating with other type B hosts. If a type B host is +communicating with a type A host, the type B host will +essentially simulate the behaviour of a type A host and use zero +MSN values for this communication.) + + +3.1.4 LINK RESYNCH NUMBER (LRN) + + +The Link Resynch Number is an eight bit number associated with a +link and used for resynchronizing the communication. For links +associated with a network connection (i.e. user links), it is +intially set to zero. For control links, it is set to zero at +the time of the Network Control Program (NCP) initialization. +For a given link, its current LRN value is copied into the LRN +field of all messages sent out on the link. The LRN values may +be manipulated by type B hosts in accordance with the protocol +described later. + + +(Comments: Our protocol specifies that for all communication +involving a type A host, the LRN value will never change from +zero. Since the LRN field is presently unused, all hosts set it +to zero even though they do not explicitly recognize this field +as an LRN field. This guarantees compatibility.) + + +3.1.5 LRN FIELD + + +An eight bit field in the bits 33 through 40 of the Host-to-Host +message header. + + + + + + + + - 11 - + + + + + + + + + + +3.2 NEW CONTROL COMMANDS + + +3.2.1 LMR - LOST MESSAGE FROM RECEIVER + + +___8______8_______8_______8____ +| I I I I +I LMR | link | LRN | MSN I +I______I_______I_______I______I_ + + +The LMR command is sent by a receiving host to let the sending +host know that one or more messages have been lost. The MSN +field specifies the message sequence number of the first message +lost. The LRN field specifies the new LRN value that must be +used if and when communication is restored. + +(Comments: As will be seen later, the LMR command also has the +effect of resetting the bit and message allocation in the sending +host to zero. In order to permit a sender to restore +communication, an LMR command will be usually accompanied with an +allocate command. However notice that these comments do not +apply to the control links because there is no allocation +mechanism for the control links.) + + +3.2.2 LMS - LOST MESSAGE FROM SENDER + + +____8_________8________8__________8_________8_____ +I I I I I I +I LMS I Link I LRN I MSN I COUNT I +I__________I________I_________I__________I________I_ + + +This command is sent by a sender host in reply to an LMR command +if it (the sender) can not retransmit the lost messages specified +by the LMR command. The purpose of this command is to query the +receiver whether or not the loss of messages is acceptable. +After sending this command, the sender waits for a reply before +transmitting any messages over the link involved. This command +may not be sent for control links. The LRN and MSN values are +same as those specified by the LMR command. COUNT specifies the +number of messages lost. + + + +3.2.3 LMA - LOSS OF MESSAGES ACCEPTABLE + + +This command is identical to the LMS command accept for the +command code. Upon receipt of an LMS command, a receiver may + + + - 12 - + + + + + + + + + + +send this command to the sender to let the sender know that loss +of messages is acceptable. All fields in this command are set to +corresponding values in the LMS command. + + + +3.2.4 CLS2 - CLOSE2 + + +____8___________3_2_______________3_2_____________8_______8______ +I I I I I I +I CLS2 I my socket I your socket I LRN I MSN I +I________I_______________I__________________I________I_______I_ + + +The CLS2 command is similar to the current CLS command except for +the LRN and MSN fields included in the new command. Both the +receiving and sending hosts copy their values of LRN and MSN into +the CLS2 command. Upon receiving a CLS2 command, a host compares +the LRN and MSN values contained in the CLS2 command with its own +values for the connection involved. If these values do not +match, then an error has occurred and a host may initiate +recovery procedures. + +(Comments: The purpose of this command is to ensure that the +last message transmitted on a connection has been received +succesfully.) + + + +3.2.5 ECLS - ERROR CLOSE + + +_____8___________3_2___________3_2_________ +I I I I +I ECLS I my socket I your socketI +I_________I______________I______________I_ + + +The ECLS command is similar to the current CLS command. It is +used for closing connections which have sufferred an +irrecoverable loss of messages. + +(Comments: A connection may be closed in any one of the following +three ways: + + 1. A connection which has not yet been opened succesfully +may be closed by the CLS command. All connections +involving type A hosts must be closed using the CLS +command. + 2. Connections between type B hosts may be closed using +CLS2 command. A connection is considered closed only +if matching CLS2 commands have been exchanged between + + + - 13 - + + + + + + + + + + +the sender and the receiver. + 3. Those connections between type B hosts, that have +sufferred an irrecoverable loss of messages, must be +closed by the ECLS command.) + + + +3.2.6 RSS - REQUEST STATUS FROM SENDER + + +____8_______8______ +I I I +I RSS I LINK I +I_______I_________I_ + + +A sending host may issue an RSS command to find out about the +status of transmission on a particular connection or the control +link. + + + +3.2.7 RSR - REQUEST STATUS FROM RECEIVER + + +____8_________8_____ +I I I +I RSR I LINK | +I________I_________I_ + + +A receiver can issue an RSR command to find out about the status +of transmission on a particular connection or the control link. + + + +3.2.8 SFR - STATUS FROM RECEIVER + + +____8_________8_________8_________8____ +I I I I I +I SFR I LINK I LRN I MSN I +I_________I_________I_________I________I_ + + +A receiving host may issue this command to inform the sender +about the state of a particular connection or the control link. + + + +3.2.9 SFS - STATUS FROM SENDER + + + + + - 14 - + + + + + + + + + + +____8_________8_________8_________8____ +I I I I I +I SFS I LINK I LRN I MSN I +I_________I_________I_________I________I_ + + +A sending host may issue this command to inform the receiver +about the state of a particular connection or the control link. + + + +3.3 THE PROTOCOL + + +3.3.1 PART ONE + + +All type A hosts must use zero MSN and LRN values on the messages +sent out by them. When communicating with a host of type A, a +type B host must simulate the behaviour of type A host. + +(Comments: Notice that this simulation is not complicated at +all. All that is required is that hosts that adopt this +protocol must not use it when communicating with the hosts that +have not adopted it.) + + +3.3.2 PART TWO + + +This part of the protocol is stated as a set of rules which must +be observed by all type B hosts when communicating with other +type B hosts. + + +3.3.2.1 RESPONSIBILITIES OF HOSTS AS SENDERS + + + (1). A type B sending host must use message sequence numbers +on all regular messages that it sends to other type B +hosts as specified in the definition of the message +sequence numbers (Section 3.1.3). + (2). A type B sending host must use link resynch numbers on +all regular messages that it sends to other type B +hosts as specified in the definition of link resynch +number (Section 3.1.4). + (3). A sending host may retransmit a message if it suspects +that the message may have been lost in the network +during previous transmission. + (4). A sending host may issue an RSS command to the receiver +to determine the state of transmission on any link. + (5). A sending host must use the ECLS command to close a +connection, if the connection is being closed due to an + + + - 15 - + + + + + + + + + + +irrecoverable transmission error. Otherwise, it must +the CLS2 command. + + + +3.3.2.2 RESPONSIBILITIES OF HOSTS AS RECEIVERS + + + (1). A receiver host will maintain LRN and MSN values for +each link on which it receives messages. Initial value +of LRN will be zero, and initial value of MSN will be +one. For each receive link, the host should be +prepared to receive a message with LRN and MSN values +specified by its tables. When the host has received +the expected message on a given link, it will change +its table MSN value as specified in the definition of +MSN. + (2). On a given link, if a host receives a message with an +LRN value smaller than the one in use, it will ignore +the message. + (3). If a host receives a duplicate message (same LRN and +MSN values), it will ignore the duplicate. + (4). A host will examine the MSN values on all regular +messages that it receives to detect loss of messages. +If on any link, one or more messages are found missing, +it will concern itself with only the first message lost +and take the following series of action: + + 1. Increase its own LRN value for this link by + one. + 2. Send an LMR command to the sending host with + LRN field set to the new value and MSN field + set to the sequence number of the first + message lost. + 3. Realizing that LMR command will cause the + allocation to be reset to zero, it will send + more allocation. This is not applicable to + the control links. + +However, if a host does not want to initiate the +recovery procedures, it may simply close the connection +by an ECLS command. + (5). A receiver host may issue the RSR command to determine +the state of transmission on any link. + (6). If a connection is being closed due to an irrecoverable +error, a receiving host must use the ECLS command. +Otherwise it must use the CLS2 command. + + + + + + + + + - 16 - + + + + + + + + + + +3.3.2.3 SENDING HOST'S RESPONSE TO CONTROL MESSAGES + + + (1). RSR command: the sender must transmit a SFS command to +the receiver for the link involved. + (2). ECLS command: The sender must cease transmission, if it +has not already done so, and issue an ECLS command if +it has not already issues either a ECLS or CLS2 +command. + (3) CLS2 command: The sender must compare the LRN and MSN +values of the CLS2 command with its own values of the +LRN and MSN for the connection involved. If an error +is indicated, it may either close the connection with +an ECLS, or initiate recovery action as specified in +the section 3.3.2.1. + (4). LMR command for a connection (i.e., not a control +link): The sender may follow any one of the following +three courses of action: + + 1. Close the connection with an ECLS command. + 2. Set the allocations for the link involved to + zero, set LRN to that specified in the LMR + command, and restart communication at the + point of break. + 3. Set the allocations for the link involved to + zero, set the LRN to that specified in the + LMR command, and send an LMS command to the + receiver host informing him that one or more + of the lost messages can not be + retransmitted. After sending an LMS command, + a sending host must not transmit any more + messages on the link involved until and + unless it receives an LMA command from the + receiver host. + +(Comments: As we have mentioned before (Section 2.3), the +decision regarding which course of action to follow depends upon +a number of factors. For example, if a host has implemented only +the detection of lost messages aspect of our protocol (and no +recovery), then it will chose the first option of closing the +connection.) + + (5). LMR for a control link: The sender may take one of the +following two actions: + + 1. Set the LRN to that specified in the LMR + command and begin retransmission of lost + messages + 2. Set the LRN to that specified by the LMR + command, and insert a Reset command at the + break point. + + + + + - 17 - + + + + + + + + + + +(Comment: If a sending host can not retransmit messages lost on +a control link, then this protocol requires that all +communication between the two host be broken, and reinitialized. +We do not explicitly specify the actions that are associated with +the exchange of Reset commands. These actions are specified by +the Host-to-Host protocol.) + + (6). LMA command: When a sending host receives an LMA +command matching an LMS command previously issued by +it, it may resume transmission. + +(Comments: The protocol does not require the sending host to take +any specific action with regard to a SFR. However, a sending host +may use the information contained in the SFR command regarding +the state of transmission. From a SFR command a sender host may +determine what messages have been received properly. The sender +may use this information to cleanup its buffer space or +retransmit messages that it might suspect are lost.) + + + +3.3.2.4 RECEIVING HOST'S RESPONSE TO CONTROL MESSAGES + + + (1). RSS command: A receiver is obligated to transmit a SFR +to the sender for the link involved. + + (2). ECLS command: The receiver must close the connection +by issuing an ECLS command if it has not already done +so. + + (3). CLS2 command: A receiver must compare the LRN and MSN +values of the command with its own values for the +connection involved. If an error is indicated, it may +either close the connection by an ECLS command or +initiate recovery procedures as specified in section +3.3.2.2. + + (4). LMS command: The receiver may take one of the following +two courses of action: + + (1). Close the connection specified by the LMS + command, by issuing an ECLS command. + (2). Set the link involved to be prepared to + receive messages starting with the sequence + number MSN + COUNT, where MSN and COUNT are + those specified by the LMS command. + (Comment: This action implies that receiver + is willing to accept the loss of messages + specified by the LMS command.) + +(Comments: The protocol does not require the receiver to take any +specific action with regard to a SFS command. However a receiver + + + - 18 - + + + + + + + + + + +host may use the information contained in it.) + + + + +4.0 CONCLUDING REMARKS + + +The design of this protocol has been governed by three major +principles. First, we believe that to be useful within the ARPA +Network, any new protocol must be compatible with the existing +protocols, so that each host can make the transition to the new +protocol at its own pace and without large investment. Secondly, +the protocol should tie into the recovery mechanism of the +IMP-to-Host Protocol. The price we pay for this is the small MSN +field and a message oriented protocol rather than a byte stream +oriented protocol. The third consideration has been flexibility. +While this protocol guarantees detection of lost messages, the +philosophy behind the recovery procedures is that a host should +have several options, each option providing a different degree of +sophistication. A host can implement a recovery procedure that +is most suitable for its needs and the capabilities of its +machine. Even though two hosts may have implemented different +recovery procedures, they can communicate with each other in a +compatible way. In a network of independent machines of widely +varying capabilities and requirements, this seems to be the only +way of implementing such a protocol. Even though this protocol +provides a variety of options in a given error situation, the +choice of a specific action must be consistent with the basic +requirements of the communication path. For example, partial +recovery is not acceptable during file transfers. We fully +expect the File Transfer Protocol to specify that if an +irrecoverable error occurs, the file transfer must be aborted. + + + + + + + + + + + + + + + + + + + + + + + - 19 - + + + + -- cgit v1.2.3