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/rfc59.txt | 437 ++++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 437 insertions(+) create mode 100644 doc/rfc/rfc59.txt (limited to 'doc/rfc/rfc59.txt') diff --git a/doc/rfc/rfc59.txt b/doc/rfc/rfc59.txt new file mode 100644 index 0000000..3f7122d --- /dev/null +++ b/doc/rfc/rfc59.txt @@ -0,0 +1,437 @@ + + + + + + + Edwin W. Meyer, Jr. + MIT Project MAC + 27 June 1970 + + +The method of flow control described in RFC 54, prior allocation of +buffer space by the use of ALL network commands, has one particular +advantage. If no more than 100% of an NCP's buffer space is allocated, +the situation in which more messages are presented to a HOST then it can +handle will never arise. + +However, this scheme has very serious disadvantages: + + +(i) chronic underutilization of resources, + +(ii) highly restricted bandwidth, + +(iii)considerable overhead under normal operation, + +(iv) insufficient flexibility under conditions of increasing load, + +(v) it optimizes for the wrong set of conditions, and + +(vi) the scheme breaks down because of message length indeterminacy. + +Several people from Project MAC and Lincoln Laboratories have discussed +this topic, and we feel that the "cease on link" flow control scheme +proposed in RFC 35 by UCLA is greatly preferable to this new plan for +flow control. + +The method of flow control proposed in RFC 46, using BLK and RSM control +messages, has been abandoned because it can not guarantee to quench flow +within a limited number of messages. + + +The advantages of "cease on link" to the fixed allocation proposal are +that: + +(i) it permits greater utilization of resources, + +(ii) does not arbitrarily limit transmission bandwidth, + +(iii)is highly flexible under conditions of changing load, + +(iv) imposes no overhead on normal operation, and + +(v) optimizes for the situations that most often occur. + +Its single disadvantage is that under rare circumstances an NCP's input +buffers can become temporarily overloaded. This should not be a serious +drawback for network operation. + +The "cease on link" method of flow control operates in the following + + + + [Page 1] + +NWG/RFC 59 Flow Control - Fixed Versus Demand Allocation + + +manner. IMP messages for a particular "receive" link may be coming in +to the destination HOST faster than the attached process is reading them +out of the NCP's buffers. At some point the NCP will decide that the +input queue for that link is too large in relation to the total amount +of free NCP buffer space remaining. At this time the NCP initiates +quenching by sending a "cease on link" IMP message to its IMP. This does +nothing until the next message for that link comes in to the destination +IMP. The message still gets transmitted to the receiving HOST. However, +the RFNM returned to the transmitting HOST has a special bit set. This +indicates to the originating NCP that it should stop sending over that +link. As a way of confirming the suspension, the NCP sends an SPD +"suspended" NCP control message to the receiving HOST, telling it that +it indeed has stopped transmitting. At a future time the receiving pro- +cess will have cut the input queue for the link down to reasonable size, +and the NCP tells the sending NCP to begin sending messages by issuing a +RSM "resume" NCP control message. + +The flow control argument is based on the following premises: + + +(1) Most network transmission falls into two categories: + Type 1 - short messages (<500 bits) at intervals of several seconds + or more. (console communication) + Type 2 - a limited number (10 - 100) of full messages (8000 bits) + in rapid succession. (file transmission) + + +(2) Most processes are ready to accept transmitted data when it arrives + at the destination and will pick it up within a few seconds (longer + for large files). Thus, at any particular instant the great major- + ity of read links have no data buffered at the destination HOST. + This assumes a sensible software system at both ends. + + +(3) Flow control need be imposed only rarely on links transmitting Type + 1 messages, somewhat more frequently for Type 2 messages. + + +(4) Both the total network load and that over a single connection fluc- + tuate and can not be adequately predicted by either the NCP or the + process attached to an individual connection. + + +(5) Assuming adequate control of wide bandwidth transmission (Type 2), + the probability that an NCP will be unable to accept messages from + the IMP due to full buffers is quite small, even if the simultane- + ous receipt of moderately small messages over all active links + would more than fill the NCP's input buffers. + + +(6) In the event that an NCP's buffers do fill completely, it may + refuse to accept any transmission from the IMP for up to a minute + without utter catastrophe. + + + + + [Page 2] + +NWG/RFC 59 Flow Control - Fixed Versus Demand Allocation + + +(7) Under cases of extreme input load, if an NCP has large amounts of + data buffered for input to a local process, AND that process has + not read data over that connection for more than a minute, the NCP + may delete that data to make space for messages from the IMP. This + is expected to happen extremely rarely, except in cases where the + process is the main contributor to the overload by maintaining + several high volume connections which it is not reading. + + + +Based on the preceding premises, I see the following disadvantages in +the flow control proposed in RFC 54: + + +(1) Chronic Underutilization of Resources - A fixed allocation of + buffer space dedicated to a single Type 1 connection will go + perhaps 90% unused if we actually achieve responsive console + interaction through the network. This is because it is empty most + of the time and is very seldom more than partially filled. Stated + conversely, a scheme of demand allocation might be expected to han- + dle several times as many console connections using the same buffer + resources. (It has been suggested that this problem of underutili- + zation could be alleviated by allocating more than 100% of the + available buffer space. This is in fact no solution at all, because + it defeats the basic premise underlying this method of flow con- + trol: guaranteed receptivity. True, it might fail in less than one + case in 1000, but that is exactly the case for which flow control + exists.) + + +(2) Highly Restricted Bandwidth - At the same time that all that buffer + space dedicated to low volume connections is being wasted (and it + can't be deallocated - see below), high volume communication is + unnecessarily slowed because of inadequate buffer allocation. + (Because of the inability to deallocate, it is unwise to give a + large allocation.) Data is sent down the connection to the alloca- + tion limit, then stops. Several seconds later, after the receiving + process picks up some of the data, a new allocation is made, and + another parcel of data is sent. It seems clear that even under only + moderately favorable conditions, a demand allocation scheme will + allow several times the bandwidth that this one does. + + +(3) Considerable Overhead During Normal Operation - It can be seen that + flow control actually need be imposed relatively rarely. However, + this plan imposes a constant overhead for all connections due to + the continuing need to send new allocations. Under demand alloca- + tion, only two RFC's, two CLS's, and perhaps a couple of SPD and + RSM control messages need be transmitted for a single connection. + Under this plan, a large fraction of the NCP control messages will + be ALL allocation requests. There will probably be several times as + many control messages to be processed by both the sending and + receiving NCP's, as under a demand allocation scheme. + + + + + [Page 3] + +NWG/RFC 59 Flow Control - Fixed Versus Demand Allocation + + +(4) Inflexibility Under Increasing Load Conditions - Not only is this + plan inflexible as to different kinds of load conditions on a sin- + gle link, there is potential inflexibility under increasing total + load. The key problem here is that an allocation can not be arbi- + trarily revoked. It can be taken back only if it is used. As an + example of the problem that can be caused, assume the case of a + connection made at 9 AM. The HOST controlling the receiving socket + senses light load, and gives the connection a moderately large + allocation. However, the process attached to the send socket + intends to use it only to report certain special events, and + doesn't normally intend to send much at all down this connection. + Comes 12 noon, and this connection still has 90% of its original + allocation left. Many other processes are now using the network, + and the NCP would dearly love to reduce its allocation, if only it + could. Of course it can't. If the NCP is to keep its part of the + flow control bargain, it must keep that space empty waiting for the + data it has agreed to receive. + + This problem can't really be solved by basing future allocations on + past use of the connection, because future use may not correlate + with past use. Also, the introduction of a deallocation command + would cause synchrony problems. + + The real implication of this problem is that an NCP must base its + allocation to a link on conditions of heavy load, even if there is + currently only light network traffic. + + +(5) Wrong Type of Optimization - This type of flow control optimizes + for the case where every connection starts sending large amounts of + data almost simultaneously, exactly the case that just about never + occurs. As a result the NCP operates almost as slowly under light + load as it does under heavy load. + + +(6) Loss of Allocation Synchrony Due to Message Length Indeterminacy - + If this plan is to be workable, the allocation must apply to the + entire message, including header, padding, text, and marking, oth- + erwise, a plethora of small messages could overflow the buffers, + even though the text allocation had not been exceeded. Thomas Bar- + kalow of Lincoln Laboratories has pointed out that this also fails, + because the sending HOST can not know how many bits of padding that + the receiving HOST's system will add to the message. After several + messages, the allocation counters of the sending and receiving + HOSTs will get seriously out of synchrony. This will have serious + consequences. + + It has been argued that the allocation need apply only to the text + portion, because the header, padding, and marking are deleted soon + after receipt of the message. This imposes an implementation res- + triction on the NCP, that it must delete all but the text part of + the message just as soon as it gets it from the IMP. In both the + TX2 and Multics implementations it is planned to keep most of the + message in the buffers until it is read by the receiving process. + + + + [Page 4] + +NWG/RFC 59 Flow Control - Fixed Versus Demand Allocation + + +The advantages of demand allocation using the "cease on link" flow con- +trol method are pretty much the converse of the disadvantages of fixed +allocation. There is much greater resource utilization, flexibility, +bandwidth, and less overhead, primarily because flow control restric- +tions are imposed only when needed, not on normal flow. + + +One would expect very good performance under light and moderate load, +and I won't belabor this point. + + +The real test is what happens under heavy load conditions. The chief +disadvantage of this demand allocation scheme is that the "cease on +link" IMP message can not quench flow over a link soon enough to prevent +an NCP's buffers from filling completely under extreme overload. + +This is true. However, it is not a critical disadvantage for three rea- +sons: + + +(i) An overload that would fill an NCP's buffers is expected to occur + at infrequent intervals. + + +(ii) When it does occur, the situation is generally self-correcting and + lasts for only a few seconds. Flow over individual connections may + be temporarily delayed, but this is unlikely to be serious. + + +(iv) In a few of these situations radical action by the NCP may be + needed to unblock the logjam. However, this will have serious + consequences only for those connections directly responsible for + the tie-up. + +Let's examine the operation of an NCP employing demand allocation and +using "cease on link" for flow control. The following discussion is +based on a flow control algorithm in which the maximum permissible queue +length (MQL) is calculated to be a certain fraction (say 10%) of the +total empty buffer space currently available. The NCP will block a con- +nection if the input queue length exceeds the MQL. This can happen +either due to new input to the queue or a new calculation of the MQL at +a lower value. Under light load conditions, the MQL is reasonably high, +and relatively long input queues can be maintained without the connec- +tion being blocked. + +As load increases, the remaining available buffer space goes down, and +the MQL is constantly recalculated at a lower value. This hardly affects +console communications with short queues, but more queues for high +volume connections are going above the MQL. As they do, "cease on link" +messages are being sent out for these connections. + +If the flow control algorithm constants are set properly, there is a +high probability that flow over the quenched links will indeed cease +before the scarcity of buffer space reaches critical proportions. + + + + [Page 5] + +NWG/RFC 59 Flow Control - Fixed Versus Demand Allocation + + +However, there is a finite probability that the data still coming in +over the quenched links will fill the buffers. This is most likely under +already heavy load conditions when previously inactive links start +transmitting at at once at high volume. + +Once the NCP's buffers are filled it must stop taking all messages from +its IMP. This is serious because now the NCP can no longer receive con- +trol messages sent by other NCP's, and because the IMP may soon be +forced to stop accepting messages from the NCP. (Fortunately, the NCP +already has sent out "cease on link" messages for virtually all of the +high volume connections before it stopped taking data from the IMP.) + +In most cases input from the IMP remains stopped for only a few seconds. +After a very short interval, some process with data queued for input is +likely to come in and pick it up from the NCP's buffers. The NCP immedi- +ately starts taking data from the IMP again. The IMP output may stop and +start several times as the buffers are opened and then refilled. How- +ever, more processes are now reading data queued for their receive sock- +ets, and the NCP's buffers are emptying at an accelerating rate. Soon +the reading processes make enough buffer space to take in all the mes- +sages still pending for blocked links, and normal IMP communications +resume. + +As the reading processes catch up with the sudden burst of data, the MQL +becomes lower, and more and more links become unblocked. The crisis can +not immediately reappear, because each link generally becomes unblocked +at a different time. If new data suddenly shoots through, the link +immediately goes blocked again. The MQL goes up, with the result that +other links do not become unblocked. + +The worst case appears at a HOST with relatively small total buffer +space (less than 8000 bits per active receive link) under heavy load +conditions. Suppose that high volume transmission suddenly comes in over +more than a half-dozen links simultaneously, and the processes attached +to the receive links take little or none of the input. The input buffers +may completely fill, and the NCP must stop all input from the IMP. If +some processes are reading links, buffer space soon opens up. Shortly it +is filled again, this time with messages over links which are not being +read. At this point the NCP is blocked, and could remain so indefin- +itely. The NCP waits for a time, hoping that some process starts reading +data. If this happens, the crisis may soon ease. + +If buffer space does not open up of its own accord, after a limited +interval the NCP must take drastic action to get back into communication +with its IMP. It selects the worst offending link on the basis of amount +of data queued and interval since data was last read by this process, +and totally deletes the input queue for this link. This should break the +logjam and start communications again. + +This type of situation is expected to occur most often when a process +deliberately tries to block an NCP in this manner. The solution has +serious consequences only for "bad" processes: those that flood the net- +work with high volume transmission over multiple links which are not +being read by the receiving processes. + + + + [Page 6] + +NWG/RFC 59 Flow Control - Fixed Versus Demand Allocation + + +Because of the infrequency and tolerability of this situation, the +overall performance of the network using this scheme of demand alloca- +tion should still be much superior to that of a network employing a +fixed allocation scheme. + + [ This RFC was put into machine readable form for entry ] + [ into the online RFC archives by William Lewis 6/97 ] + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + [Page 7] + -- cgit v1.2.3