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/rfc48.txt | 1011 +++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1011 insertions(+) create mode 100644 doc/rfc/rfc48.txt (limited to 'doc/rfc/rfc48.txt') diff --git a/doc/rfc/rfc48.txt b/doc/rfc/rfc48.txt new file mode 100644 index 0000000..5cfecef --- /dev/null +++ b/doc/rfc/rfc48.txt @@ -0,0 +1,1011 @@ + + + + + + +Network Working Group J. Postel +Request for Comments: 48 S. Crocker + UCLA + April 21, 1970 + + + A Possible Protocol Plateau + +I. Introduction + + We have been engaged in two activities since the network meeting of + March 17, 1970 and, as promised, are reporting our results. + + First, we have considered the various modifications suggested from + all quarters and have formed preferences about each of these. In + Section II we give our preferences on each issue, together with our + reasoning. + + Second, we have tried to formalize the protocol and algorithms for + the NCP, we attempted to do this with very little specification of a + particular implementation. Our attempts to date have been seriously + incomplete but have led to a better understanding. We include here, + only a brief sketch of the structure of the NCP. Section III gives + our assumptions about the environment of the NCP and in Section IV + the components of the NCP are described. + +II. Issues and Preferences + + In this section we try to present each of the several questions which + have been raised in recent NWG/RFC's and in private conversations, + and for each issue, we suggest an answer or policy. In many cases, + good ideas are rejected because in our estimation they should be + incorporated at a different level. + + A. Double Padding + + As BBN report #1822 explains, the Imp side of the Host-to-Imp + interface concatenates a 1 followed by zero or more 0's to fill + out a message to an Imp word boundary and yet preserve the + message length. Furthermore, the Host side of the Imp-to-Host + interface extends a message with 0's to fill out the message to + a Host word boundary. + + BBN's mechanism works fine if the sending Host wants to send an + integral number of words, or if the sending Host's hardware is + capable of sending partial words. However, in the event that + + + + + +Postel & Crocker [Page 1] + +RFC 48 A Possible Protocol Plateau April 1970 + + + the sending Host wants to send an irregular length message and + its hardware is only capable of sending word-multiple messages, + some additional convention is needed. + + One of the simplest solutions is to modify the Imp side of the + Host-to-Imp interface so that it appends only 0's. This would + mean that the Host software would have to supply the trailing + 1. BBN rejected the change because of an understandably strong + bias against hardware changes. It was also suggested that a + five instruction patch to the Imp program would remove the + interface supplied 1, but this was also rejected on the new + grounds that it seemed more secure to depend only upon the Host + hardware to signal message end, and not to depend upon the Host + software at all. + + Two other solutions are also available. One is to have "double + padding", whereby the sending Host supplies 10* and the network + also supplies 10*. Upon input, a receiving Host then strips + the trailing 10* 10*. The other solution is to make use of the + marking. Marking is a string of the form 0*1 inserted between + the leader and the text of a message. The original intent of + marking was to extend the leader so that the sending Host could + _begin_ its text on a word boundary. It is also possible to + use the marking to expand a message so that it _ends_ on a word + boundary. + + Notice that double padding could replace marking altogether by + abutting the text beginning against the leader. For 32 bit + machines, this is convenient and marking is not, while for + other lengths, particularly 36 bit machines, marking is much + more convenient than double padding. + + We have no strong preference, partially because we can send + word fragments. Shoshani, et al in NWG/RFC #44 claim that + adjusting the marking does not cause them any problems, and + they have a 32 bit machine. Since the idea of marking has been + accepted for some time, we suggest that double padding not be + used and that marking be used to adjust the length of a + message. We note that if BBN ever does remove the 1 from the + hardware padding, only minimal change to Host software is + needed on the send side. + + A much prettier (and more expensive) arrangement was suggested + by W. Sutherland. He suggested that the Host/Imp interfaces be + smart enough to strip padding or marking and might even parse + the message upon input. + + + + + +Postel & Crocker [Page 2] + +RFC 48 A Possible Protocol Plateau April 1970 + + + B. Reconnection + + A very large population of networkers has beat upon us for + including dynamic reconnection in the protocol. We felt it + might be of interest to relate how it came to be included. + + After considering connections and their uses for a while, we + wondered how the mechanism of connections compared to existing + forms of intra-Host interprocess communication. Two aspects + are of interest, what formalisms have been presented in the + literature, and what mechanisms are in use. The formalisms are + interesting because they lead to uniform implementations and + parsimonious design. The existing mechanisms are interesting + because they point out which problems need solving and + sometimes indicate what an appropriate formalism might be. In + particular, we have noticed that the mechanisms for connecting + a console to the logger upon dial in, the mechanisms for + creating a job, and the mechanisms for passing a console around + to various processes within a job tend to be highly + idiosyncratic and distinct from all other structures and + mechanisms within an operating system. + + With respect to the literature, it appears there is only one + idea with several variations, viz processes should share a + portion of their address spaces and cooperatively wake up each + other. Semaphores and event channels are handy extensions of + wake up signals, but the intent is basically the same. (Event + channels could probably function as connections, but it seems + not to be within their intended use. In small systems, the + efficiency and capacity of event channels are inversely + related.) + + With respect to existing implementations, we note that several + systems allow a process to appear to be a file to another + process. Some systems, e.g. the SDS-940 at SRI impose a + master/slave relationship between two processes so connected, + but other systems provide for a coequal relationship e.g. the + AI group's PDP-6 system at MAC. The PDP-6 system also has a + feature whereby a superior process can "surround" an inferior + process with a mapping from device and file names to other + device and file names. Consoles have nearly the same semantics + as files, so it is quite reasonable for an inferior process to + believe it is communicating with the console but in fact be + communicating with another process. + + The similarity between network connections and existing + sequential interprocess connections supports our belief that + network connections are probably the correct structure for + + + +Postel & Crocker [Page 3] + +RFC 48 A Possible Protocol Plateau April 1970 + + + using the network. Moreover, the structure is clean enough and + compatible with enough machines to pass as a formalism or + theory, at least to the extent of the other forms of + interprocess communication presented in the literature. + + Any new formalism, we believe, must meet at least the following + two tests: + + 1. What outstanding problems does it solve? + 2. Is it closed under all operations? + + In the case of network connections, the candidates for the + first are the ones given above, i.e. all operations involving + connecting a console to a job or a process. Also of interest + are the modelling of sequential devices such as tape drives, + printers and card readers, and the modeling of their buffering + (spooling, symbiont) systems. + + The second question mentions closure. In applying the + connection formalism to the dial-in and login procedures, we + felt the need to include some sort of switching or + reconnection, and an extremely mild form is presented in an + SJCC paper, which is also NWG/RFC #33. This mild form permits + only the substitution of AEN's, and even then only at the time + of connection establishment. However, it is a common experience + that if an operation has a natural definition on an extended + domain, it eventually becomes necessary or at least desirable + to extend its definition. Therefore, we considered the + following extensions: + + 1. Switching to any other socket, possibly in another Host. + 2. Switching even after data flow has started. + + There is even some precedent for feeling these extensions might + be useful. In one view of an operating system, we see all + available phone lines as belonging to a live process known as + the logger. The logger answers calls, screens users, and + creates jobs and processes. One of the features of most + telephone answering equipment is that many phone lines may + serve the same phone number by using a block of sequential + numbers and a rotary answering system. In our quest for + accurate models of practical systems, we wanted to be able to + provide equivalent service to network users, i.e. they should + be able to call a single advertised number and get connected to + the logger. Thus a prima facie case for switching is + established. + + + + + +Postel & Crocker [Page 4] + +RFC 48 A Possible Protocol Plateau April 1970 + + + Next we see that after the logger interrogates a prospective + user, it must connect the user to a newly created job. Data + flow between the user and the logger has already commenced, so + flow control has to be meshed with switching if it is desired + not to lose or garble data in transit. + + With respect to inter-Host switching, we find it easy to + imagine a utility service which is distributed throughout the + network and which passes connections from one socket to another + without the knowledge of the user. Also, it is similar to the + more sophisticated telephone systems, to standard facilities of + telephone company operators, and to distributed private + systems. + + These considerations led us to investigate the possibility of + finding one type of reconnection which provided a basis for all + known models. The algorithm did not come easily, probably + because of inexperience with finite state automata theory, but + eventually we produced the algorithm presented in NWG/RFC #36. + A short time later, Bill Crowther produced an equivalent + algorithm which takes an alternate approach to race conditions. + + Networkers seem to have one of two reactions. Either it was + pretty and (perhaps ipso facto) useful, or it was complex and + (again perhaps ipso facto) unnecessary. The latter group was + far more evident to us, and we were put into the defensive + position of admitting that dynamic reconnection was only + + 1. pretty + 2. useful for login and console passing + + In response to persistent criticism, we have made the following + change in the protocol. Instead of calling socket to + login, sockets of the form and are the input + and output sockets respectively of a copy of the logger or, if + a job has been stared with user id U, these sockets are the + console sockets. The protocol for login is thus to initiate a + connection to and . If user U is not in use, a + copy of the logger will respond and interrogate the caller. If + user id U is in use, the call will be refused. This + modification was suggested by Barry Wessler recently. (Others + also suggested this change much earlier; but we rejected it + then.) + + The logger may demand that the caller be from the same virtual + net, i.e. the caller may have user id U in some other Host, or + it may demand that the user supply a password matched to user + + + + +Postel & Crocker [Page 5] + +RFC 48 A Possible Protocol Plateau April 1970 + + + id U, or it may demand both. Some systems may even choose to + permit anybody to login to any user id. + + After login, AEN's 0 and 1 remain the console AEN's. Each + system presumably has mechanisms for passing the console, and + these would be extended to know about AEN's 0 and 1 for network + users. Passing the console is thus a matter of reconnecting + sockets to ports, and happens within the Host and without the + network. + + In conversations with Meyer and Skinner after NWG/RFC #46 was + received, they suggested a login scheme different from both + Meyer's and ours in section above. Their new scheme seemed a + little better and we look forward to their next note. + + It is generally agreed that login should be "third-level", that + is, above the NCP level. We are beginning to be indifferent + about particular logins schemes; all seem ok and none impress + us greatly. We suggest that several be tried. It is some + burden, of course, to modify the local login procedure, but we + believe it imposes no extra hardship to deal with diverse login + procedures. This is because the text sequences and interrupt + conventions are so heterogenous that the additional burden of + following, say, our scheme on our system and Meyer's on Multics + is minimal. + + We are agreed that reconnection should not be required in the + initial protocol, and we will offer it later as an optional and + experimental tool. In addition, we would like to be on record + as predicting that general reconnection facilities will become + useful and will provide a unifying framework for currently ad + hoc operating system structures. + + C. Decoupling Connections and Links + + Bill Crowther (BBN) and Steve Wolfe (UCLA) independently have + suggested that links not be assigned to particular connections. + Instead, they suggest, include the destination socket as part + of the text of the message and then send messages over any + unblocked link. + + We discussed this question a little in NWG/RFC #37, and feel + there is yet an argument for either case. With the current + emphasis on simplicity, speed and small core requirements, it + seems more efficient to leave links and connections coupled. + We, therefore, recommend this. + + + + + +Postel & Crocker [Page 6] + +RFC 48 A Possible Protocol Plateau April 1970 + + + D. Error Reporting + + As mentioned by J. Heafner and E. Harslem of RAND, it is + important to treat errors which might occur. A good philosophy + is to guard against any input which destroys the consistency of + the NCP's data base. + + The specific formulation of the error command given by Heafner + and Harslem in NWG/RFC #40 and by Meyer in NWG/RFC #46 seems + reasonable and we recommend its adoption. Some comments are in + order, however. + + A distinction should be made between resource errors and other + types of errors. Resource errors are just the detection of + overload conditions. Overload conditions are well-defined and + valid, although perhaps undesirable. Other types of errors + reflect errant software or hardware. We feel that resource + errors should not be handled with error mechanisms, but with + mechanisms specific to the problem. Thus the command may + be issued when there is no more room to save waiting 's. + Flow control protocol is designed solely to handle buffering + overload. + + With respect to true errors, we are not certain what the value + of the command is to the recipient. Presumably his NCP + is broken, and it may only aggravate the problem to bombard it + with error commands. We therefore, recommend that error + generation be optional, that all errors be logged locally in a + chronological file and that commands received likewise be + logged in a chronological file. No corrective action is + specified at this time. + + In the short time the network has been up at UCLA, we have + become convinced that the network itself will generate very few + errors. We have watched the BBN staff debug and test the IMP + program, and it seemed that most of the errors affected timing + and throughput rather than validity. Hence most errors will + probably arise from broken Hosts and/or buggy NCP's. + + E. Status Testing and Reporting + + A valuable debugging aid is to be able to get information about + what a foreign NCP thinks is happening. A convenient way to do + this is to permit NCP's to send status whenever they wish, but + to always have them do it whenever they receive a request. + + + + + + +Postel & Crocker [Page 7] + +RFC 48 A Possible Protocol Plateau April 1970 + + + Since we view this feature as primarily a debugging tool, we + suggest that a distinct link, like 255, be used. The intent is + that processing of status requests and generating of status + messages should use as little of the normal machinery as + possible. Thus we suggest that link 255 be used to send + "request status" and "status is" commands. The form follows + the suggestion on page 2 of NWG/RFC #40. + + Meyer's command is easily implemented and serves the more + basic function of testing whether a foreign NCP is alive. We + suggest that the length of the command be variable, as + there seems to be no significance in this context to 48 bits. + Also, the value of a (presumably) 8 bit binary switch is + unclear, so we recommend a pair of commands: + + + and + + where + is 8 bits. + + Upon receipt of an command the NCP would echo with the + command. + + F. Expansion and Experimentation + + As Meyer correctly points out in NWG/RFC #46, network protocol + is a layered affair. Three levels are apparent so far. + + 1. IMP Network Protocol + 2. Network Control Program Protocol + 3. Special user level or Subsystem Level Protocol + + This last level should remain idiosyncratic to each Host (or + even each user). The first level is well-specified by BBN, and + our focus here is on level 2. We would like to keep level 2 as + neutral and simple as possible, and in particular we agree that + login protocol should be as much on level 3 as possible. + + Simplicity and foresight notwithstanding, there will arise + occasions when the level 2 protocol should change or be + experimented with. In order to provide for experimentation and + change, we recommend that only link numbers 2 through 31 be + assigned to regular connections, with the remaining link + numbers, 32 to 255, used experimentally. We have already + suggested that link 255 be used for status requests and + replies, and this is in consonance with our view of the + experimental aspects of that feature. + + + +Postel & Crocker [Page 8] + +RFC 48 A Possible Protocol Plateau April 1970 + + + We also recommend that control command prefixes from 255 + downward be used for experimentation. + + These two conventions are sufficient, we feel to permit + convenient experimentation with new protocol among any subset + of the sites. We thus do not favor inclusion of Ancona's + suggestion in NWG/RFC #42 for a message data type code as the + first eight bits of the text of a message. + + G. Multiplexing Ports to Sockets + + Wolfe in NWG/RFC #38 and Shoshani et al in NWG/RFC #44 suggest + that it should be possible to attach more than one port to a + socket. While all of our diagrams and prototypical system + calls have shown a one-to-one correspondence between sockets + and ports, it is strictly a matter of local implementation. We + note that sockets form a network-wide name space whose sole + purpose is to interface between the idiosyncratic structures + peculiar to each operating system. Our references to ports are + intended to be suggestive only, and should be ignored if no + internal structures corresponds to them. Most systems do have + such structures, however, so we shall continue to use them for + illustration. + + H. Echoing, Interrupts and Code Conversion + + 1. Interrupts + + We had been under the impression that all operating systems + scanned for a reserved character from the keyboard to + interpret it as an interrupt signal. Tom Skinner and Ed + Meyer of MIT inform us that model 37 TTY's and IBM 2741 + generate a "long space" of 200-500 milliseconds which is + detected by the I/O channel hardware and passed to the + operating system as an interrupt. The "long space" is not a + character -- it has no ASCII code and cannot be program + generated. + + Well over a year ago, we considered the problem of + simulating console interrupts and rejected the type + command because it didn't correctly model any system we + knew. We now reverse our position and recommend the + implementation of an INTERRUPT system call and an + control command as suggested by Meyer in NWG/RFC #46. + + + + + + + +Postel & Crocker [Page 9] + +RFC 48 A Possible Protocol Plateau April 1970 + + + Two restrictions of the interrupt facility should be + observed. First, when communicating with systems which scan + for interrupt characters, this feature should not be used. + Second, non-console-like connections probably should not + have interrupts. We recommend that systems follow their own + conventions, and if an arrives for a connection on + which it shouldn't the should be discarded and + optionally returned as an error. + + 2. Echoing and Code Conversion + + We believe that each site should continue its current + echoing policy and that code conversion should be done by + the using process. Standardization in this area should + await further development. + + Ancona's suggestion of a table-driven front-end transducer + seems like the right thing, but we believe that such + techniques are part of a larger discussion involving + higher-level languages for the network. + + I. Broadcast Facilities + + Heafner and Harslem suggest in NWG/RFC #39 a broadcast + facility, i.e. and . We do not fully understand the + value of this facility and are thus disposed against it. We + suspect that we would understand its value better if we had + more experience with OS/360. It is probably true in general + that sites running OS/360 or similar systems will find less + relevance in our suggestions for network protocol than sites + running time-sharing systems. We would appreciate any cogent + statement on the relationship between OS/360 and the concepts + and assumptions underlying the network protocol. + + J. Instance Numbers + + Meyer in NWG/RFC #46 suggests extending a socket to include an + _instance_ code which identifies the process attached to the + socket. We carefully arranged matters so that processes would + be indistinguishable. We did this with the belief that both as + a formal and as a practical matter it is of concern only within + a Host whether a computation is performed by one or many + processes. Thus we believe that all processes within a job + should cooperate in allocating AEN's. If an operating system + has facilities for passing a console from process to process + within a job, these facilities mesh nicely with the current + network protocol, even within reconnection protocol; but + instance numbers interfere with such a procedure. + + + +Postel & Crocker [Page 10] + +RFC 48 A Possible Protocol Plateau April 1970 + + + We suggest this matter be discussed fully because it relates to + the basic philosophy of sockets and connections. Presently we + recommend 40 bit socket numbers without instance codes. + + K. AEN's + + Nobody, including us, is particularly happy with our name AEN + for the low order 8 bits of the socket. We rejected _socket_ + number_, and are similarly unhappy with Meyer's _socket_code_. + The word socket should not be used as part of the field name, + and we solicit suggestions. + +III. Environment + + We assume that the typical host will have a time-sharing operating + system in which the cpu is shared by processes. + + Processes + + We envision that each process is tagged with a _user_number_. There + may be more than one process with the same user number, and if so, + they should all be cooperating with respect to using the network. + + We envision that each process contains a set of _ports_ which are + unique to the process. These ports are used for input to or output + from the process, from or to files, devices or other processes. + + We also envision that each process has an event channel over which it + can receive very short messages (several bits). We will use this + mechanism to notify a process that some action external to the + process has occurred. + + To engage in network activity, a process _attaches_ a _local_socket_ + to one of its ports. Sockets are identified by user number, host and + AEN, and a socket is local to a process if their user numbers match + and they are in the same host. A process need only specify an AEN + when it is referring to a local socket. + + Each port has a status which is modified by system calls and by + concurrent events outside the process. Whenever the status of a port + is changed, the process is sent an event over its event channel which + specifies which port's status has changed. The process may then look + at a port's status. + + These assumptions are used descriptive material which follows. + However, these assumptions are not imposed by the network protocol + and the implementation suggested by section IV is in no way binding. + + + + +Postel & Crocker [Page 11] + +RFC 48 A Possible Protocol Plateau April 1970 + + + We wish to make very clear that this material is offered only to + provide clues as to what the implementation difficulties might be and + not to impose any particular discipline. + + For example, we treat 's which arrive for unattached local + sockets as valid and queue them. If desired, an NCP may reject them, + as Meyer suggests, or it might hold them for awhile and reject them + if they're not soon satisfied. The offered protocol supports all + these options. + + Another local option is the one mentioned before of attaching + multiple ports to a socket. We have shown one-one correspondence but + this may be ignored. Similarly, the system calls are merely + suggestive. + + System Calls + + These are typical system calls which a user process might execute. + We show these only for completeness; each site will undoubtedly + implement whatever equivalent set is convenient. + + We use the notation + + Syscall ( arg , arg ...; val ... ) + 1 2 1 + where + Syscall is the system call + arg etc. are the parameters supplied with the call, and + 1 + val etc. are any values returned by the system call. + 1 + + Init (P,AEN,FS,Bsiz;C) + + P Specifies a port of the process. + AEN Specifies a local socket. The user number of this + process and host number of this host are implicit. + FS Specifies a socket with any user number in any host, + with any AEN. + Bsiz Specified the amount of storage in bits the user wants + to devote to buffering messages. + C The condition code returned. + + Init attempts to attach the local socket specified by AEN to the port + P and to initiate a connection with socket FS. Possible returned + values of C are + + + + + +Postel & Crocker [Page 12] + +RFC 48 A Possible Protocol Plateau April 1970 + + + C = ok The Init was legal and the socket FS is being + contacted. When the connection is established or + when FS refuses, the process will receive an event. + + C = busy The local socket was in use by a port on this or + some other process with the same user number. No + action was taken. + + C = homosex The AEN and FS were either both send or both receive + sockets. + + C = nohost The host designated within FS isn't known. + + C = bufbig Bsiz is too large. + + Listen (P,AEN,Bsize;C) + + P Specifies a port of the process. + AEN Specifies a local socket. + Bsiz Specified a buffer size. + C The returned legality code. + + Codes for C are + + C = ok + C = busy + C = bufbig + + The local socket specifies by AEN is attached to P. If there is a + waiting call, it is processed; otherwise no action is taken. When a + call comes in, a connection will be established and the process + notified via an event. + + Close (P) + + P Specifies a port of the process. + + Any activity is stopped, and the port becomes free for other use. + + Transmit (P,M,L1;L2,C) + + P Specifies port with an open connection. + M The text to be transmitted. + L1 Specifies the length of the text. + L2 The length actually transmitted. + C The error code. + + + + + +Postel & Crocker [Page 13] + +RFC 48 A Possible Protocol Plateau April 1970 + + + Transmission between the processes on either side of the port takes + place. + + Codes for C are + + C = ok + or + C = not open if no connection is currently open and + otherwise uninhibited + Status (P;C) + + The status of port P is returned as C. + +IV. The NCP + + We view the NCP as having five component programs, three associative + tables, some queues and buffers, and a link assignment table. Each + site will of course, vary this design to meet its needs, so our + design is only illustrative. + + The Component Programs + + 1. The Input Handler + + This is an interrupt driven input routine. It initiates Imp- + to-Host transmission into a resident buffer and wakes up the + Input Interpreter when transmission is complete. + + 2. The Output Handler + + This is an interrupt driven output routine. It initiates + Host-to-Imp transmission out of a resident buffer and wakes up + the Output Scheduler when transmission is complete. + + 3. The Input Interpreter + + This program decides whether the input is a regular message + intended for a user, a control message, an Imp-to-Host message, + or an error. For each class of message, this program takes the + appropriate action. + + 4. The Output Scheduler + + Three classes of message are sent to the Imp + + (a) Host-to-Imp messages + (b) Control messages + (c) Regular messages + + + +Postel & Crocker [Page 14] + +RFC 48 A Possible Protocol Plateau April 1970 + + + We believe that a priority should be imposed among these + classes. The priority we suggest is the ordering above. The + Output Scheduler selects the highest priority message and + gives it to the Output Handler. + + 5. The System Call Interpreter + + This program interprets requests from the user. + + The two interesting components are the Input Interpreter and the + System Call Interpreter. These are similar in that the Input + Interpreter services foreign requests and the System Call Interpreter + services local requests. + + Associative Tables + + We envision that the bulk of the NCP's data base is in three + associative tables. By "associative", we mean that there is some + lookup routine which is presented with a key and either returns + successfully with a pointer to the corresponding entry, or fails if + no entry corresponds to the key. + + 1. The Rendezvous Table + + "Requests-for-connection" and other attributes of a + connection are held in this table. This table is accessed by + local socket, but other tables have pointers to existing + entries. + + The components of an entry are: + + (a) local socket (key) + (b) foreign socket + (c) link + (d) queue of callers + (e) text queue + (f) connection state + (g) flow state + (h) pointer to attached port + + An entry is created when a user executes either an Init or a + Listen system call or when a is received. Some fields + are unused until the connection is established, e.g. the + foreign socket is not known until a arrives if the + user did a Listen. + + + + + + +Postel & Crocker [Page 15] + +RFC 48 A Possible Protocol Plateau April 1970 + + + 2. The Input Link Table + + The Input Interpreter uses the foreign host and link as a + key to get a pointer to the entry in the rendezvous table + for the connection using the incoming link. + + 3. The Output Link Table + + In order to interpret RFNM's, the Input Interpreter needs a + table in the same form as the Input Link Table but using + outgoing links. + + Link Assignment Table + + This is a very simple structure which keeps track of which links are + in use for each host. One word per host probably suffices. + + The following diagram is our conception of the Network Control + Program. Boxes represent tables and Buffers, boxes with angled + corners and a double bottom represent Queues, and jagged boxes + represent component programs, the arrows represent data paths. + + The abbreviated names have the following meanings. + + ILT - Input Link Table + + OLT - Output Link Table + + LAT - Link Assignment Table + + RT - Rendezvous Table + + HIQ - Host to Imp Queue + + OCCQ - Output Control Command Queue + + ORMQ - Output Regular Message Queue + + IHBuf - Buffer filled by the Input Handler from the IMP and + emptied by the Input Interpreter + + OHBuf - Buffer of outgoing messages filled from the Queues + by the Output Scheduler and emptied by the Output + Handler. + + + + + + + +Postel & Crocker [Page 16] + +RFC 48 A Possible Protocol Plateau April 1970 + + + +---------+ + | I M P | + +---------+ + v ^ + | | + +---------------------------|-----|------------------------------+ + | | | | + | /\/\/\/\/\/\/\ | | /\/\/\/\/\/\/\ | + | \ / <--------+ +---< \ / | + | / Input \ / Output \ | + | \ Handler / \ Handler / <----+ | + | / \ >------+ / \ | | + | \/\/\/\/\/\/\/ | \/\/\/\/\/\/\/ ^ | + | v +-----+ | + | +-----+ | OH | | + | | IM | | Buf | | + | | Buf | +-----+ | + | +-----+ /\/\/\/\/\/\/\/\ ^ | + | /\/\/\/\/\/\/\/\ v +----> \ / | | + | \ / | | / Output \ >--+ | + | / \ <------+ ^ \ / | + | \ Input / /-----\ / Scheduler \ | + | / \ >-------->| HIQ | \ / | + | \ Interpreter / |_____| / \ | + | / \ >----+ \_____/ \/\/\/\/\/\/\/\/ | + | \/\/\/\/\/\/\/\/ | ^ v ^ | + | ^ ^ ^ \ | /-----\ | | | /-----\ | + | | \ \ \ | | O | | | | | O | | + | | \ \ \ +--->| C |>----+ | +---<| R | | + | v v v \ | C | | | M | | + | +---+ +---+ +---+ \ | Q | v | Q | | + | | | | | | | \ |_____| +---------+ |_____| | + | |ILT| |LAT| |OLT| \ \_____/ | | \_____/ | + | | | | | | | \ ^ | R T | ^ | + | +---+ +---+ +---+ +------|-------->| | | | + | v | +---------+ | | + | | ^ ^ | | + | | /\/\/\/\/\/\/\/\ | | | + | | \ / | | | + | +----------->/ System \<-------+ | | + | \ Call / | | + | / Interpreter \>--------------------+ | + | \ / | + | +-->/ \>--+ | + | | \/\/\/\/\/\/\/\/ | | + +------------------|----------------------|----------------------+ + | | + +---< system calls <---+ + + + +Postel & Crocker [Page 17] + +RFC 48 A Possible Protocol Plateau April 1970 + + + [ This RFC was put into machine readable form for entry ] + [ into the online RFC archives by Donald and Jill Eastlake 1999 ] + +[Editor's note: The original hand-drawn diagram represented +Queues by cylinders and component programs by "squishy ameoba +like things".] + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Postel & Crocker [Page 18] + -- cgit v1.2.3