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RFC928 - Introduction to proposed DoD standard H-FP

王朝other·作者佚名  2008-05-31
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Network Working Group M. A. Padlipsky

Request for Comments: 928 Mitre Corp.

December 1984

INTRODUCTION TO PROPOSED DOD STANDARD H-FP

Status Of This Memo

This RFCsuggests a proposed protocol for the ARPA-Internet

community, and requests discussion and suggestions for improvements.

Distribution of this memo is unlimited.

Important Prefatory Note

The broad outline of the Host-Front End Protocol introduced here and

described in RFC929 is the result of the deliberations of a number

of eXPerienced H-FP designers, who sat as a committee of the DoD

Protocol Standards Technical Panel under the author's chairmanship.

The particular protocol to be described is, however, the result of

the deliberations of a small, ad hoc group, who sat as a de facto

subcommittee of the H-FP committee, also under the author's

chairmanship. The protocol, then, follows the consensus of the full

group as to what the new H-FP should "look like," but has not

benefitted from painstaking study by a large number of experienced

H-FP designers and implementers. (It has been looked at before

release as an RFCby several of them, though.) Even if that were not

the case, it would still be the intent of the designers that the

protocol be subjected to multiple test implementations and probable

iteration before being agreed upon as any sort of "standard".

Therefore, the first order of business is to declare that THIS IS A

PROPOSAL, NOT A FINAL STANDARD, and the second order of business is

to request that any readers of these documents who are able to do

test implementations (a) do so and (b) coordinate their efforts with

the author (617-271-2978 or Padlipsky@USC-ISI.ARPA.).

Historical/Philosophical Context

Late in May of 1971, the author was presenting a status report on

whether the Multics ARPANET implementation would be ready by the

July 1 deadline declared by the sponsor earlier that month. Some

controversy developed over the fact that the Multics "NCP" (Network

Control Program--actually a blanket term covering the Host-Host and

Host-IMP protocol interpreters) did not queue requests for

connections. As the specification explicitly declared the topic to

be one of implementors' choice, the author attempted to avoid the

argument by aSKINg the interrogator what he was up to these days.

The answer was, "Oh, I'm working on the High-Speed Modular IMP now"

(later the Pluribus IMP). And the proverbial coin dropped: The

author replied, "I've got a great idea. Now that we've got some

space to program in the IMP, why don't we separate out most of the

RFC928 December 1984

Introduction to H-FP

NCP and do it outboard: the only thing that really matters in the

Host is associating sockets with processes, and if we had common

implementations of all the bit-diddling stuff in the IMPs, we

wouldn't have disputes over the interpretation of the spec and we'd

also save a lot of Host CPU cycles!"

As far as the author knows, that incident was the beginning of what

came to be called "Network Front-Ends" and, more recently, "Outboard

Processing Environments." (The name change, by the way, was

motivated by a desire to prevent further confusion between NETWORK

Front Ends--always conceived of as distributed processing mechanisms

for the offloading of intercomputer networking protocols from

Hosts--and traditional communications front-ends, which have no

connotation of bearing protocol interpreters invokable by Host-side

programs.) At least, the idea was original to him and he later was a

principal designer and the primary author of the first Host-Front End

Protocol. So, on the one hand, the present document might be marred

for some readers by undertones of parental pride, but on the other

hand, if you like primary sources....

The evolution of the outboard processing idea has been dealt with

elsewhere [1]. For present purposes, it should suffice to observe

that some half-a-dozen implementors of "NFE's" of various sorts are

known to the author to have met with success. The topic of why use

an explicit protocol in the first place (as opposed to emulating a

device, or devices, already known to the Host/operating system)

deserves a Word or two here, however. ([2] deals with it in more

general terms.) The crucial consideration is that in the general

case you wind up "not doing real networking" if you attach a Host to

a network by known device emulation, where real networking is taken

to mean what has been called "resource sharing" in the ARPANET

literature, and what appears to be dubbed "open system

interconnection" in the ISO literature: Operating systems' built-in

assumptions about known devices--whether terminals, terminal

controllers, or RJE stations--tend to get in the way of the sort of

process-process and eventually procedure-procedure communications

that serve as the basis for applications more interesting than simple

remote login. To those unfamiliar with the outboard processing

approach, the premise that the way to attach is via an explicit

protocol may be difficult to accept, but to those who have done it,

it makes almost perfect sense.

To those, by the way, who have worked in intercomputer networking

from the perspective of inboard (Host-side) implementations of

protocol suites, the outboard processing idea often seems to lead to

less than optimal results, especially as to maximizing throughput.

And it is difficult to argue that if a given Host were well and truly

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Introduction to H-FP

fine-tuned to "do networking" the insertion of an extra processor

could somehow lead to better networking. However, for Hosts where

conservation of CPU cycles is an issue, or even where memory is

scarce (i.e., where it's desirable to conserve the resources being

shared), outboarding is clearly the way to go. For that matter,

viewing outboard processing aright (as a form of distributed

processing) it can be argued that even for extremely powerful

"intelligent work stations"/"personal computers" which have the

resources to spare it still makes sense to outboard in order not to

have to do new implementations of entire protocol suites for each new

such system--always assuming, of course, that the Host-Front End

protocol in play is noticeably less complex than the offloaded

protocols.

None of this is meant to imply that outboard processing is the ONLY

way to do intercomputer networking, of course. It is, however, meant

to suggest that outboard processing can be advantageous in a number

of contexts. Indeed, given the joint advents of microprocessors and

Local Area Networks, a generic bus interface unit which also plays

the role of a NFE (that is, is an Outboard Processing Environment)

even allows for the original intent of "offloading to the IMP" to be

realized, so that a free-standing, possibly fairly expensive NFE need

not be interposed between Host and net. Note, by the way, that

nothing in the OPE approach requires that ALL Hosts employ OPEs. That

is, the only protocols "seen" beyond the Comm Subnet Processor are

the common intercomputer networking protocols (e.g., all DDN IMPs see

and read IP datagrams). H-FP is strictly a matter between a Host and

its OPE.

It is also important to be aware that, given the advent of several

different suites of protocols in the networking world, it might well

be the case that the only reasonable way to achieve

"interoperability" might well be to use a suitable H-FP (such as the

one to be presented in the companion RFC) and an Outboard Processing

Environment which is capable of parallel invocation of protcol suites

(with the choice of suite for a given connection being dependent, of

course, on the native suite of the desired target Host and/or

application).

The unquestionable advantages, then, of the approach, based on ten or

more years of experience and analysis, would seem to be as

follows--always recalling the assumption that the work to implement

and execute the H-FP in play is small compared to the full protocol

suite in question: As noted, common implementation of a protocol

suite has the automatic advantage of mutual consistency; further,

particularly in the DOD context, it's far easier to procure common

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Introduction to H-FP

implementations of standard protocols than to procure different ones

on a per-Host type basis. Also as noted, if the resources to be

shared are viewed as being the participating Hosts'

CPU cycles and memories, these resources are conserved by doing as

much as possible of the networking protocols in an OPE rather than in

the mainframe. Another, less evident advantage is that having an OPE

effectively insulates a Host against changes in the

outboarded/offloaded protocols--or even changes of the protocols,

should the nascent international protocol standards ever mature

sufficiently to supplant the in-place DOD standards. (That is, given

an abstract enough interface--in the spirit of the Principle of

Layering--a Host could, for example, go from doing TCP as its

"Host-Host" protocol to, say, ECMA Class 4 as its "Transport"

protocol without taking any particular cognizance of the change,

however unattractive such a change would be to advocates of the

APRANET Reference Model such as the author. See [3] for more on the

implied "Reference Model" issues.) Finally, although a few rather

specialized points could also be adduced, it should be noted that for

network security architectures which are predicated on the ability to

control all means of egress from and ingress to "the net", uniform

use of OPEs is clearly desirable.

If we can stipulate that an OPE is/can be a good thing, then the

remaining problem is just what the protocol interpreted by a Host and

its OPE ought to be, once it's observed that a standard protocol is

desirable in order to allow for as much commonality as possible among

Host-side interpreters of the protocol. That is, we envision the

evolution of paradigmatic H-FP PIs which can more or less

straightforwardly be integrated with various operating systems, on

the one hand, and the ability simply to transplant an H-FP PI from

one instance of a given operating system to other instances of the

same system, much as is currently being attempted in the DODIIS NFE

program. Again, the major motivation in the DOD context is the

minimizing of procurement problems.

Technical Context

As noted, some half-a-dozen Host-Front End protocols have been seen

by the author. Indeed, in December of 1982, a meeting was convened

to allow the developers of those H-FPs to compare their experiences,

with an eye to coming up with a proposal for a DOD standard H-FP;

this paper is a direct result of that meeting. In the current

section, we present the consensus of the meeting as to the broad

outline of the protocol; in the accompanying document, the current

version of the proposed protocol will be presented, as detailed by

the author and Richard Mandell and Joel Lilienkamp (both of SDC).

RFC928 December 1984

Introduction to H-FP

Note, by the way, that in some sense we should probably have changed

the name from H-FP to H-OPEP (or something), but the habit of saying

"H-FP" seems too deeply engrained, despite the fact that it does seem

worthwhile to stop saying "NFE" and start saying "OPE." (Besides,

H-OPEP looks rather silly.)

A final preliminary: all the designers and implementors of H-FPs

present at the December meeting concurred that the true test of any

protocol is how well it implements. Therefore, until several

implementations of the "new" protocol have been performed and

assessed, it must be understood that the proposed protocol is

precisely that: a proposal, not a standard.

Not too surprisingly, the first point on which consensus was reached

is that there are three separable ASPects (or "layers") to an H-FP:

At bottom, there must be some physical means for conveying bits from

Host to OPE and from OPE to Host. As it has always been a premise of

outboard processing that the Host's convenience is paramount, just

what this physical layer is can vary: typically, a bit-serial

interface is customary, but parallel/DMA interfaces, if available for

the Host and interfaceable to a given OPE, are fair game. (So would

teleporting the bits be, for that matter.)

In the middle, there must be a layer to manage the multiplexing of

network "connections" and the control of the flow between Host and

OPE. If we agree to call the lowest layer the Link and the middle

layer the Channel, one thing which must be noted is that between the

two of them, the Link and Channel layers must be responsible for

reliably conveying the bits between Host and OPE. After all, an OPE'd

Host should not be "weaker" than one with an inboard implementation

of a robust Host-Host protocol such as TCP. It should be noted that

any Host which "comes with" a suitable implementation of the X.25

interface protocol (where the definition of "suitable" is rather too

complex to deal with here) could, given an OPE conditioned to accept

it, quite cheerfully satisfy the requirements of the lower two

layers. This is not to say that X.25 "is" the mechanization of H-FP's

Link and Channel layers, however; merely that it could be used. The

protocol spec itself will detail an alternative, less cumbersome

channel layer for Hosts which don't have or want X.25.

The top layer of H-FP is the most important: we refer to it as the

Command layer. Here is where the peer H-FP modules in a given Host

and OPE communicate with each other. Indeed, the segregation of JUST

multiplexing and flow control (plus reliability) into the Channel

Layer is done--in addition to making it easier for Hosts that possess

preexisting software/hardware which could be turned to the

purpose--so as to clarify "what the H-FP is": it's the commands and

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Introduction to H-FP

responses of the Command layer wherewith the Host's processes are

able to manipulate the outboard implementations of the members of a

protocol suite. The use of the phrase "commands and responses" is

rather significant, as it happens. For in the protocol to be proposed

for DOD standardization, unlike all but one of its predecessors,

binary encoded "headers" are not employed; rather, the H-FP commands

are indeed ASCII strings, and the responses (following the practice

of ARPANET FTP) ASCII-encoded numbers.

There are various reasons for this departure, which initially stemmed

from a desire to have the same NFE be usable for terminal traffic as

well as Host offloading, but the one that seemed to dominate when

consensus was arrived on it as the basis for the new standard is that

it is very much in the original spirit of H-FP. That is, if you want

to "make things as easy as possible for the Host", it makes a great

deal of sense to offload in a fashion that only requires some sort of

scenario or script ("exec-com"/"command file"/"shell command" are

approximations on some systems) in the Host, rather than requiring a

program, possibly of more complexity than we would like. This is not

to say that we envision all--or even most--Hosts will take the

scenario approach to H-FP mechanization, but rather that the command

orientation chosen allows for the possibility. (It would be useful to

recall that the Channel layer does all the necessary

multiplexing/demultiplexing, so that each channel's metaphorical

state machine--at least on the Host side--really has very little to

worry about other than "doing its thing.")

It should be noted that the proposed protocol provides a mechanism

for offloading "all" protocols. That is, although most "first

generation NFEs" only handled ARPANET Reference Model Layers II and I

(Host-Host and Network Interface--approximately ISO levels 4-1, with

some of L5's functionality included when it comes to service

identifications being handled via Well-Known Sockets in L II), it is

assumed that OPEs will be evolved to handle L III offloading as well

(ISO 5-7). Indeed, it should also be noted that what is being

addressed here is "the protocol", not "the" OPE. More will be said

on this topic below, and in the protocol spec itself, but it is

important to realize from the outset that the H-FP being proposed is

intended to be implementable by any number of OPE suppliers/vendors,

so "an" OPE may or may not choose to implement, say, a given file

transfer protocol, but provided it says so in proper H-FP terms and

does offload some other protocols it's still an OPE in our sense of

the term. (Cf. "Issues" and "Non-Issues", below.)

RFC928 December 1984

Introduction to H-FP

Issues

The following items are either in some sense still open issues or

bear special emphasis:

Command Approach

The most striking feature of the new H-FP, especially to those who

have seen older H-FPs, is the decision to employ

character-oriented commands rather than the more conventional

binary-oriented headers at the Command Layer. As noted, the

primary motivation was the report that the approach worked well

when it was employed in an H-FP for the Platform Network called

NAP (Network Access Protocol) [4]. In discussions with NAP's

originator, Gerry Bailey, the author was convinced of the

fundamental reasonableness of the approach, but of course that

doesn't have to convince others. Additional rationales emerged in

discussions with Gary Grossman, the originator of the DCA/DTI

H-FP [5], which is probably the best-known current H-FP and which

furnished the default Channel Layer for the new one: In the first

place, the text approach makes parsing for the ends of

variable-length parameters easier. In the second place, it allows

for the possibility of creating a terminal-supporting OPE in a

very straightforward fashion should any OPE developer elect to do

so. (See below for more on the distinction between OPE developers

and H-FP implementors.) Finally, there's nothing sacred about

binary headers anyway, and just because the text approach is

different doesn't make it "wrong". So, although it's not out of

the question that the new protocol should back off from the text

approach if reviewers and/or implementors come up with compelling

reasons for doing so, the already frequently encountered reaction

of "it feels funny" isn't compelling. (It was, indeed, the

author's own initial reaction.) Besides, "nobody" (not even Gary)

really liked the top layer of the DCA/DTI H-FP.

X.25 Appropriateness

Of more concern than how text "feels" is whether X.25 "works".

That is, we understand that many system proprietors would greatly

prefer being able to use "off-the-shelf" software and hardware to

the greatest extent feasible and still be able to do intercomputer

networking according to DOD Standards, which is a major reason why

we decided to take the H-FP commands out of the Channel Layer of

the DCA/DTI H-FP even before we decided to encode them as text.

However, it is by no means clear that any old vendor supplied

"X.25" will automatically be usable as a new H-FP Channel and Link

layer mechanization. As noted, it all depends upon how Host

RFC928 December 1984

Introduction to H-FP

programs (the Command Layer/H-FP Protocol Interpreter in

particular) are able to invoke X.25 on particular systems. Also,

there might be peculiarities in the handling of some constructs

(the Group and Member fields--or whatever they're called--are a

strong candidate) which could militate against getting JUST

demultiplexing and flow control out of X.25-as-Channel

Link/Layers. For that matter, it's conceivable that on some

systems only one process can "own" the presumed DCE, but there's

no interprocess communication available between it and the

processes that want to use H-FP. What that all amounts to, then,

is that we don't pretend to be sufficiently versed in the vagaries

of vendor-idiosyncratic X.25 implementations to claim more than

that we THINK the new H-FP Command Layer should fit "on top of"

X.25 in a Host such that a suitably crafted OPE could look like a

DCE to the low-level Host software and still be an OPE in our

sense of the term. Finally, some reports on bit-transfer rates

attainable through typical X.25 interfaces give rise to concern as

to whether such a lash-up would be "good" even if it were

feasible.

DCA/DTI Channel Layer Appropriateness

The Channel Layer of the DCA/DTI H-FP has been implemented for a

few Host types already, and is being implemented for others (in

particular, as part of the DODIIS NFE project). A delicate

decision is whether to alter the header structure (e.g.--and

perhaps i.e.--to remove the now-superfluous command and response

fields). On the "con" side are the considerations that

implementations DO exist, and that it's well specified. On the

"pro" side are that keeping the header as it is is in some sense

"wasteful" and that somebody's going to have to go over the spec

again anyway, to remove that which no longer applies. (It should

be noted that Gary Grossman was initially tempted to scuttle the

Group and Member trick, but the presence of a similar

dichotomizing in X.25 seems to rule that out.) One of the

interesting issues during the review phase of the new H-FP, then,

will be the decision about which way to go on the Channel Layer

header in its non-X.25 version. (NOBODY considers going X.25

only, be it noted.) By the time the protocol is finalized, it

will, of course, be made clear in the protocol spec, but I'll

probably leave this in the final version of the Introduction just

for historical interest anyway.

Syntax

Another point which probably needs close scrutiny during the

review process is the "syntax" of the command lines. Basically,

RFC928 December 1984

Introduction to H-FP

we just took our best shot, but without any claims that it's the

best possible way to express things. So comments and/or

alternatives are earnestly solicited on this one.

L III Offloading

Contrary to the expectations of some, we are allowing for the

offloading of Process/Applications Layer (ARPANET Reference Model

L III) protocols. Both Bailey and Grossman reported favorably on

the feasibility of this. Two points should be made, however: It's

perfectly fair for a GIVEN OPE implementation not to offload a

given L III protocol, although it would presumably not sell as

well as ones which did. That is, we're not claiming that by

inventing a mechanization of the feature in the spec we levy a

constraint on everybody who implements "the protocol", (Cf.

Fabrication under Non-Issues, below). Just as we were feeling our

way on syntax in general, we're really feeling our way when it

comes to the L III stuff. (I'm not even sure I managed to convey

what I meant for "mediation level" to Joel and Dick.) Again,

suggestions are solicited.

Security

During the detailed design pass, we had an intensive discussion

with some of the Blacker design team on the interplay between the

new H-FP and a meant-to-be multilevel-secure OPE such as Blacker.

The conclusion was that by and large "Security" is to be an aspect

of an enhanced H-FP, rather than the standard one. The reasoning

was rather involved, but seems to amount to the following: Hosts

that are NOT MLS (or "Compartmented") have two significant

properties in our context: They're in the vast majority of

present-day systems. They have no legitimate need even to tell

their OPEs what they "think" their current System High or

Dedicated Mode level is; that information should be furnished by

some trusted portion of a network security architecture (e.g., a

security enhanced OPE, or a table in a "secure" comm subnet

processor).

Thus, even having the optional security label/level field in the

Begin command is in some sense overkill, because we're not sure of

any sensible circumstances in which it would be useful, but we put

it in "just in case". On the other hand, Hosts that ARE

MLS/Compartmented by definition can be permitted to assert what

the level of a given transmission (or perhaps of a given

connection) should be, and their OPEs need to have a mechanism for

learning this. But it is by no means clear that a given Host (or

even a given OPE) will be so structured as to make the H-FP PI,

RFC928 December 1984

Introduction to H-FP

the Channel PI, and the Link PI ALL trustworthy--as they'd have to

be if the security labeling were part of H-FP. So, we envision

the labeling's being handled by trusted code in both Host and OPE

that will be inserted into the normal processing route at the

appropriate point for the given architecture (presumably "at the

very bottom" of the Host, and "the very top" of the OPE), and that

will place the label in a convenient, known position in the

Host-OPE transmission "chunk" (block/packet/data unit) as the

circumstances dictate. (It's likely--but we wouldn't swear to

it--that a good place would be just before the H-FP command, and

if that's the case then semi-clearly the security enhanced H-FP

PIs would have to "make room" for it in the sense of handing the

Channel Layer a suitably lengthened "chunk".)

The Host and its OPE should be viewed as a single entity with

regard to labeling requirements in the non-MLS/C case, and either

the OPE will be conditioned to emit the right label or the CSNP

will "know" anyway; in the MLS/C Host and OPE case (and it should

be noted that it's just about impossible to envision a MLS/C Host

which IS outboarded which DOESN'T have a MLS/C OPE) it will depend

on the given security architectures as to whether each "chunk"

needs labeling (i.e., there COULD be trusted H-FP, Channel, and

Link PIs, so that only at channel establishment time does the

label need to be passed), but it seems likely each "chunk" would

need labeling, and we can see how that would happen (as sketched

above).

This is all, of course, subject to reappraisal when the full-time

Security folks get in the act, but for now, H-FP per se is viewed

as playing no direct role in "Security"--except indirectly, as

noted below under the Symmetric Begins Non-Issue. (In case

anybody's worrying about the case where the OPE is physically

remote from its Host, by the way, that line would have to be

protected anyway, so the Host/OPE-asa-single-unit view should hold

up.)

How It Implements

The final issue to take note of is that one of the central

premises of the Outboard Processing approach has always been that

H-FPs can be invented which implement more compactly on the Host

side than the code they're allowing to be offloaded. We certainly

think the new H-FP will fulfill that condition, but we'd certainly

like to hear of any evidence to the contrary.

RFC928 December 1984

Introduction to H-FP

Non-Issues

The following items are declared to be non-issues, in the sense that

even though some people have expressed concern over them we believe

that they are either "not part of the protocol" or resolved already

for reasons that were overlooked by those worried about them:

Fabrication

Who builds OPEs isn't within our purview, except to the extent of

hoping a few volunteers come forward to do testcase

implementations of what is, at present, only a paper protocol.

However, beyond agreeing that a few points should be marked as

"Notes to Entrepreneurs" in the spec, we didn't attempt to dictate

how an OPE vendor would behave, beyond the explicit and implicit

dictates of the protocol per se. For example, if a given OPE

doesn't offload SMTP, it jolly well ought to respond with the

appropriate "Function not implemented" code, and if a vendor

claims to accept X.25 for Channel and Link disagreements over what

X.25 "is" are the province of the vendor and the customer, not of

the H-FP spec. As OPE'S are supposed to be offloading COMMON

protocols in a COMMON fashion, a given OPE should be able to

interoperate with another Host irrespective of whether that Host

even has an OPE, much less whose OPE it is if it's there. Thus,

for example, even though you'd expect to find OPEs that "come

with" their own LANs as a fairly frequent product, we don't appeal

to the notion in the conceptual model; nor do we attempt to

dictate "chunk" sizes at the Channel level. A protocol spec isn't

an implementation spec.

Symmetric Begins

For almost as long as there have been H-FPs, there has been

disagreement over whether only the Host can begin a connection or

if the OPE can also take the initiative. I am delighted to be

able to resolve this one finally: It turns out there IS a

compelling reason for insisting that THE PROTOCOL include

provision for OPE --> Host Begins, so it's "in" the protocol--but

any Host that doesn't need to deal with them doesn't have to (just

"spell" the "Function not implemented" response code correctly).

(In case anybody cares, the compelling reason is that if you HAD

an MLS OPE which happened to use a security kernel and a process

per level, you'd need IT to be listening for incoming connection

requests "from the net" rather than having the Host tell it to do

so, for various esoteric reasons--but in order to cater to the

possibility, we want the function in the protocol from the

RFC928 December 1984

Introduction to H-FP

beginning, on the grounds that we can envision SOME other uses for

it even in non-MLS environments [unlike the security labeling

trick discussed above, which only seems to make sense for MLS

Hosts/OPEs--that is, it doesn't burden the Host to reject a Begin

every once in a while but it would to go around labeling "chunks"

unnecessarily all the time].)

Routing

Concern has been voiced over the issue of what provisions the

protocol should make to deal with the situation where a Host,

probably for traffic/load reasons, has multiple OPEs and the

question arises of which OPE to use/route to. I claim this is a

non-issue at the protocol level. If the Host-side H-FP PI gets a

"No resources" response to a Begin, it can go off to another OPE

if it wants to. "Not our department". The conceptual model is

that of a Host and AN OPE--which "ought to" be expandable to carry

more load at some level. If you want multiple links for some

reason, the simplest solution would seem to be to have multiple

Channel Layers as well, but the whole thing just gets too iffy to

have anything sensible to prescribe in the protocol. In other

words, extending the concept to deal with discrete multiple OPEs

is either a Fabrication sort of thing, or a Notes to Host-side

Implementors sort of thing on a per specific OPE basis.

Operator Interface

It's probably implicit in the foregoing, but it might be worth

saying explicitly that the operator interface to a specific OPE is

a non-issue in terms of the protocol, beyond the provision we're

made for "Shutdown coming" responses as a reflection of a probable

operator interface action we imagine most operator interfaces

would provide. (It might also be worth noting that if your Host

does "color changes", your OPE had better have a trustworthy way

of being told to change the label it plops on all IP datagrams it

emits, but that comes under the heading of an Aside to Specialized

Implementors.)

RFC928 December 1984

Introduction to H-FP

Fine Points

There are a couple of known "loose ends" which are exceedingly fine

points in some sense that do bear separate mention:

The Allocate Event

While mentally testing to see if the new H-FP would indeed

off-load TCP, we came up against an interesting question: Viewing

H-FP as "just an interface at a distance" to a TCP PI, what about

the Allocate "Interface Event" in the TCP spec? As far as I'm

concerned, this could be classed as a non-issue, because I submit

that the spec is wrong in declaring that there is such a thing as

a MANDATORY Interface Event whereby the user of a TCP PI lets the

PI know how much data it can take. Granted, you might find such a

thing in most implementations, but what if you were in a virtual

memory environment with segment sharing (or a distributed

supervisor) and you wanted to avoid copies, so all that passed at

the interface to the PI (or even at the interface from the PI) was

a pointer? That is, the "DOD version" of the TCP spec has fallen

into the trap of assuming things about the execution environment

that it shouldn't have.

One moral of this is that

AN INTERFACE TO AN INTERPRETER OF A PROTOCOL IS N*O*T "THE

PROTOCOL".

Another moral is that the interface to the Host-side H-FP PI is

hard to say much about, but is where the equivalent functionality

will be found if you've offloaded TCP. That is, it's reasonable

to let the user "tell" the outboard PI at Begin time if big or

small buffers are expected to be in play "net-ward" as part of the

protocol, but the outboard PI is expected to deliver bits to the

Host as they come unless throttled by the Channel Layer, or by

some to-be-invented other discipline to force the OPE to buffer.

(For present purposes, we envision letting the Channel Layer

handle it, but nifty mechanizations of encouraging the OPE to

"make like a buffer" would be at least looked at.) As a

Fabrication issue, it is the case that "equity" has to be dealt

with with regard to the use of the OPE's resources (especially

buffers) across H-FP connections/channels, but that's a different

issue anyway, touched upon in the final fine point.

RFC928 December 1984

Introduction to H-FP

Precedence

Clearly, the existence of a notion of Precedence in DOD protocols

has to get reflected in the outboard PI's implementations. Just

what, if any, role it has in the H-FP, per se, is, however, by no

means clear. That is, if the Host doesn't take Begins from the

OPE and is "full up" on the number of Server Telnet connections

it's willing to handle, what should happen if a high precedence

SYN comes in on the Telnet Well-Known Socket (in present day

terms)? Probably the OPE should arbitrarily close a low

precedence connection to make room for the new one, and signal the

Host, but even that assumes the Host will always hurry to be

prepared to do a new passive Begin. Perhaps we've stumbled across

still another argument in favor of "Symmetric Begins".... At any

rate, Precedence does need further study--although it shouldn't

deter us from making "the rest" of the protocol work while we're

waiting for inspiration on how to handle Precedence too.

A Note on Host Integration

The most important thing about Hosts in any intercomputer network is

that they furnish the resources to be shared. The most significant

obstacle to sharing those resources, however, is the fact that almost

invariably they were designed under the assumption that the Host was

a fully autonomous entity. That is, few operating systems currently

deployed "expect" to be members of a heterogeneous community of

operating systems. In many cases, this built-in insularity goes so

far as to have applications programs cognizant of the particular type

of terminal from which they will be invoked.

Intercomputer networking protocols attempt to resolve the problems of

heterogeneity by virtue of presenting appropriate common intermediate

representations (or "virtualizations") of the constructs and concepts

necessary to do resource sharing. A Host-Host protocol such as TCP

"is" a virtual interprocess communication mechanism; a virtual

terminal protocol such as Telnet obviously is a mechanism for

defining and dealing with virtual terminals; FTP offers common

representations of files; and so on. It cannot be stressed strongly

enough, though, that this entire approach to intercomputer networking

is predicated on the assumption that the modules which interpret the

protocols (PIs, as we'll refer to them often) will be PROPERLY

integrated into the various participating operating systems. Even in

the presence of powerful OPEs, wherein the bulk of the work of the

various PIs is performed outboard of the Host, the inboard "hooks"

which serve to interface the outboard PIs to the native system must

not only be present, they must be "right". The argument parallels

the analysis of the flexible vs. rigid front-ending attachment

RFC928 December 1984

Introduction to H-FP

strategy issue of [1]; to borrow an example, if you attempt to

integrate FTP by "looking like" a native terminal user and the

operator forces a message to all terminals, you've got an undetected

pollution of your data stream. So the key issue in attaching Hosts to

networks is not what sort of hardware is required or what sort of

protocol is interpreted by the Host and the OPE (or comm subnet

processor, for that matter), but how the PIs (full or partial) are

made to interrelate with the pre-existing environment.

It would be well beyond the scope of this document to attempt even to

sketch (much less specify) how to integrate H-FP PIs into each type

of operating system which will be found in the DoD. An example,

though, should be of use and interest. Therefore, because it is the

implementation with which we are most intimately familiar, even

though it's been several years, we propose to sketch the Multics

operating system integration of the original ARPANET Network Control

Program (NCP)--which is functionally equivalent to an H-FP PI for

offloading ARM L II and L I--and Telnet. (A few comments will also

be made about FTP.) Note, by the way, that the sketch is for a

"full-blown" H-FP; that is, shortcuts along the lines of the

scenario-driven approach mentioned above are not dealt with here.

One of the particularly interesting features of Multics is the fact

that each process possesses an extremely large "segmented virtual

memory". That is, memory references other than to the segment at

hand (which can itself be up to 256K 36-bit words long) indirect

through a descriptor segment, which is in principle "just another

segment", by segment number and offset within the segment, so that a

single process--or "scheduling and access control entity"--can

contain rather impressive amounts of code and data. Given that the

code is "pure procedure" (or "re-entrant"), a "distributed

supervisor" approach is natural; each process, then, appears to have

in its address space a copy of each procedure segment (with

system-wide and process-specific data segments handled

appropriately). Without going too far afield, the distributed

supervisor approach allows interrupts to be processed by whichever

process happens to be running at a given time, although, of course,

interprocess communication may well be a consequence of processing a

particular interrupt.

A few other necessary background points: A distinguished process,

called the Answering Service, exists, originally to field interrupts

from terminals and in general to create processes after

authenticating them. Other shared resources such as line printers

are also managed by distinguished processes, generically known as

"Daemons". Device driver code, as is customary on many operating

systems, resides at least in part in the supervisor (or hard core

RFC928 December 1984

Introduction to H-FP

operating system). Finally (for our purposes, at least), within a

process all interfaces are by closed subroutine calls and all I/O is

done by generic function calls on symbolically named streams; also,

all system commands (and, of course, user written programs which need

to) use the streams "user_input" and "user_output" for the obvious

purposes. (At normal process creation time, both user I/O streams

are "attached" to the user's terminal, but either or both can be

attached to any other I/O system interface module instead--including

to one which reads and writes files, which is handy for consoleless

processes.)

All that almost assuredly doesn't do justice to Multics, but equally

likely is more than most readers of this document want to know, so

let's hope it's enough to make the following integration sketch

comprehensible. (There will be some conscious omissions in the

sketch, and douBTless some unconscious ones, but if memory serves, no

known lies have been included.)

Recalling that NCP is functionally equivalent to H-FP, let's start

with it. In the first place, the device driver for the 1822 spec

hardware interface resides in the supervisor. (For most systems, the

PI for H-FP's link protocol probably would too.) In Multics,

interrupt time processing can only be performed by supervisor

segments, so in the interests of efficiency, both the IMP-Host (1822

software) Protocol PI and the multiplexing/demultiplexing aspects of

the Host-Host Protocol PI also reside in the supervisor. (An H-FP PI

would probably also have its multiplexing/demultiplexing there; that

is, that portion of the Channel Layer code which mediates access to

the OPE and/or decides what process a given message is to be sent to

might well be in the supervisor for efficiency reasons. It is not,

however, a hard and fast rule that it would be so. The system's

native interprocess communications mechanism's characteristics might

allow all the Channel Layer to reside outside of the supervisor.)

Even with a very large virtual memory, though, there are

administrative biases against putting too much in the supervisor, so

"everything else" lives outside the supervisor. In fact, there are

two places where the rest of the Host-Host Protocol is interpreted on

Multics, although it is not necessarily the case that an H-FP PI

would follow the same partitioning even on Multics, much less on some

other operating system. However, with NCP, because there is a

distinguished "control link" over which Host-Host commands are sent

in the NCP's Host-Host protocol, the Multics IMP-Host Protocol PI

relegates such traffic to a Network Daemon process, which naturally

is a key element in the architecture. (Things would be more

efficient, though, if there weren't a separate Daemon, because other

processes then have to get involved with interprocess communication

RFC928 December 1984

Introduction to H-FP

to it; H-FP PI designers take note.) To avoid traversing the Daemon

for all traffic, though, normal reads and writes (i.e., noncontrol

link traffic) are done by the appropriate user process. By virtue of

the distributed supervisor approach, then, there is a supervisor call

interface to "the NCP" available to procedures (programs) within user

processes. (The Daemon process uses the same interface, but by virtue

of its ID has the ability to exercise certain privileged primitives

as well.)

If a native process (perhaps one meaning to do "User Telnet", but not

limited to that) wanted to use the network, it would call the open

primitive of "the NCP", do reads and writes, and so on. An

interesting point has to do with just how this interface works: The

reads are inherently asynchronous; that is, you don't know just when

the data from the net are going to be available. In Multics, there's

an "event" mechanism that's used in the NCP interface that allows the

calling process to decide whether or not it will go blocked waiting

for input when it reads the net (it might want to stay active in

order to keep outputting, but need to be prepared for input as well),

so asynchrony can be dealt with. In the version of Unix (tm) on

which an early NFE was based, however, native I/O was always

synchronous; so in order to deal with both input from the terminal

and input from the net, that system's User Telnet had to consist of

two processes (which is not very efficient of system resources).

Similar considerations might apply to other operating systems

integrating H-FP; native I/O and interprocess communication

disciplines have to be taken into account in designing. (Nor can one

simply posit a brand new approach for "the network", because Telnet

will prove to rely even more heavily on native mode assumptions.)

The other aspect of NCP integration which we should at least touch

on--especially because process-level protocols make no sense without

it--is how "Well-Known Sockets" (WKSs) work. In broad terms, on

Multics the Network Daemon initially "owns" all sockets. For

Well-Known Sockets, where a particular process-level protocol will be

in effect after a successful connection to a given WKS, code is added

to the Answering Service to call upon the NCP at system

initialization time to be the process "listening" on the WKSs. (This

is a consequence of the fact that the Answering Service is/was the

only Multics process which can create processes; strategies on other

systems would differ according to their native process creation

disciplines.) How to get the "right kind of process" will be

sketched in the discussions of the process level protocols, but the

significant notion for now is that typically SOME sort of prior

arrangement would be done by any networked Host to associate the

right kind of process with a WKS.

RFC928 December 1984

Introduction to H-FP

Now, we don't expect that the foregoing will enable even the world's

greatest system jock to go out and design the integration of an H-FP

PI for a system that had never been networked (in the ARPANET style

of networking) before. But we propose to stop there and turn to some

comments on process level protocols, for two reasons: In the first

place, it would take us much too far afield to go into significantly

greater detail; and in the second place, because of the functional

equivalence of H-FP and NCP combined with the number of operating

systems which have integrated NCP and, for that matter, TCP/IP, which

are also functionally equivalent to H-FP (used for offloading L II

and L I), models are available in the ARPANET community and concerned

H-FP PI implementors can follow them.

Turning to Telnet integration, and returning to Multics as an

example, we note that "User Telnet" is straightforward. "All you

need" (for small values of "all") from an INBOARD User Telnet is a

command that gives the user some sort of interface, converts between

the native Multics character set and terminal discipline and the

Network Virtual Terminal equivalents (and as Multics is very generic

when it comes to I/O, that's not hard), and writes and reads "the

net" (more accurately, calls upon the Host-Host protocol PI--or upon

the H-FP PI to get at the H-HP--appropriately). (One point that's

not obvious: make the Well-Known Socket "on the other side" a

parameter, defaulting to the Telnet WKS, because you'll want to use

the same command to get at other process-level protocols.) If

there's an OPE in play which offloads User Telnet, however, things

can be even simpler: the inboard command just reads and writes the

terminal and lets the OUTBOARD User Telnet PI handle the conversion

to and from the Virtual Terminal form (presumably, from and to the

desired local form).

When it comes to the incoming ("Server") aspects of Telnet, life can

get complicated on some systems for an inboard implementation.

However, fortunately for our purposes,

Multics' native mechanisms lend themselves readily to integration; an

awareness of the inboard issues will be useful even if in response to

a connection attempt on the Telnet WKS, the (Server) Host is

obligated to associate the connection (the actual logic is somewhat

more complex under the ARPANET Host-Host Protocol, which employs

paired simplex connections) with a process that is prepared to

translate between Telnet and native mode representations and

otherwise "look like" a local user process--that is, in particular

the connection becomes an I/O source/sink to the native command

processor on time-sharing systems. As indicated, process creation is

taken care of in Multics by having the Answering Service process

listen on the WKS. Because the Answering Service is in some sense

RFC928 December 1984

Introduction to H-FP

just another Multics process, it too does user I/O through the normal

system mechanisms. So while for local terminals the user I/O streams

are attached through a module called "ttydim" (where "dim" stands for

"device interface module"), NVTs are attached through a functionally

equivalent and identically invoked module called "nttydim" (the

Answering Service knows which DIM to use based on the symbolic

designator of the "line" on which it received the interrupt, as it

happens).

[The notion of "attaching" the streams bears a bit more explanation:

Attach is a primitive of the Multics generic I/O mechanism which

associates a stream name and a particular DIM (or I/O system

interface module in later terminology); the other I/O primitives

(read, write, etc.) are invoked with the stream name as a parameter

and an I/O "switch" causes the entry point corresponding to the

primitive to be invoked in whichever DIM the stream is currently

attached to. So a Server Telnet process starts life attached

through nttydim to a particular network connection, while a local

process starts life attached through ttydim to a particular physical

line, and both processes proceed indistinguishably (viewed from

outside the I/O switch, anyway).]

The pre-existing orderliness that makes things easy on Multics does

not, unfortunately, appear in all operating systems. Indeed,

delicate choices occasionally have to be made as to WHICH native

terminal to map to on systems that don't do generic I/O in native

mode, and it is likely that for some systems the particular mapping

to bring into play in Server Telnet might be determined by the

particular application program invoked. This issue can become very

touchy when the application "expects" a "data entry terminal", say.

The Server Telnet for such a system would naturally attempt to

negotiate the "DET" option with the corresponding User Telnet. But

the user might be at a physical terminal that isn't a member of the

DET class, so that User Telnet must either refuse to negotiate the

option or--and we would recommend this alternative strongly, as it

seems to be within the "spirit" of the protocol--offer some sort of

simulation, however crude, of the behavior of a DET. Also,

something sensible has to be done on systems where there is no clear

analog of the command processor expected to be managing the Server

process. (Say, when a "menu" of applications is always displayed on

an available terminal in native mode.)

A final Telnet integration issue (although other points could be

noted, we're not pretending to be exhaustive and this should be

enough to "give the flavor"): The Telnet Interrupt Process generic

function calls for particularly careful integration. Here, the

intent of the function is to virtualize what is called the "quit

RFC928 December 1984

Introduction to H-FP

button" on some systems. That is, the user wants the system to

interrupt his process (which may, for example, be in a loop) and get

back to the command processor (or "the system" itself). On native

character-at-a-time systems, the native mechanism is usually the

entering of a particular "control character"; on native

line-at-a-time systems, the native mechanism is usually the striking

of the "ATTN" or Interrupt button or the "Break" key (sometimes more

than once, to distinguish it from a communication to the executing

program). But the native mechanisms typically involve interrupt time

code, and Server Telnet typically wouldn't be executing at that

level, so the solution (omitting the intricacies of the interaction

with the NCP or the H-FP PI, which also get into the act) would be to

make use of--in the Multics case--a pre-existing INTRAprocess signal,

or to add such a mechanism (unless the architecture chosen has a

Server Telnet Daemon of some sort, in which case an INTERprocess

signal would be needed).

The extension of the foregoing to an outboard Server Telnet may not

be obvious, but we won't expend a great deal of time on it here.

Even if "the protocol" is being handled in an OPE, the Host-side

software must be able to associate an H-FP connection with the

command language interpreter of a user process and to respond

appropriately to an H-FP Signal command if it arrives, and the OPE

must know not only the desired character set but also the local

equivalents of Erase and Kill, at the minimum.

We'll skip FTP integration, on the grounds that this note is already

too lengthy, except to mention that in the OUTBOARD case it's still

going to be necessary to convey the name of the appropriate file and

Directory to/from some appropriate Host-side code. (Similar problems

must be dealt with for outboard handling of "mail" if it's not part

of FTP.)

One other "integration" issue, which has been hinted at earlier and

about which not much can be said beyond some general guidelines: The

"top edge" of a Host-side H-FP protocol interpreter (i.e., the Host

user program interface, for

Hosts that are "doing real networking" rather than just using the OPE

to get at User Telnet and/or FTP and to offer Server Telnet and/or

FTP [and maybe "mail"], presumably in the "scenario-driven" fashion

sketched earlier) MUST BE APPROPRIATE TO THE HOST. In other words,

on Multics, where "everything" is closed subroutines, there would

presumably be a closed subroutine interface with event channels for

reads, pointers to buffers, and all that sort of thing, but on some

other style of operating system, the interface to the H-FP PI might

turn out to be "all" interprocess communication, or to "look like" a

RFC928 December 1984

Introduction to H-FP

device of some special class, or "all" system

calls/JSYSs/EOTs/Whatevers. We can't be much more specific, but we'd

be remiss to convey any impression that H-FP is a "free lunch". As

noted, an H-FP PI requires the same kind of integration as a generic

NCP--it's just smaller, and serves as insulation against changes (in

the offloaded protocols in general, or in the proximate comm subnet

in particular).

References

(References [1]-[3] will be available in M. A. Padlipsky's "The

Elements of Networking Style", Prentice Hall, 1985.)

[1] Padlipsky, M. A., "The Host-Front End Protocol Approach", MTR

3996, Vol. III, MITRE Corp., 1980.

[2] Padlipsky, M. A., "The Elements of Networking Style", M81-41,

MITRE Corp., 1981.

[3] Padlipsky, M. A., "A Perspective on the ARPANET Reference Model",

M82-47, MITRE Corp., 1982.

[4] Bailey, G., "Network Access Protocol", S-216,718, National

Security Agency Central Security Service, 1982.

[5] Day, J. D., G. R. Grossman, and R. H. Howe, "WWMCCS Host to Front

End Protocol", 78012.C-INFE.14, Digital Technology Incorporated,

1979.

 
 
 
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