分享
 
 
 

RFC878 - ARPANET 1822L Host Access Protocol

王朝other·作者佚名  2008-05-31
窄屏简体版  字體: |||超大  

Request for Comments: 878

Obsoletes RFCs: 851, 802

The ARPANET 1822L Host Access Protocol

RFC878

Andrew G. Malis

ARPANET Mail: malis@bbn-unix

BBN Communications Corp.

50 Moulton St.

Cambridge, MA 02238

December 1983

This RFCspecifies the ARPANET 1822L Host Access Protocol, which

is a sUCcessor to the existing 1822 Host Access Protocol. 1822L

allows ARPANET hosts to use logical names as well as 1822's

physical port locations to address each other.

1822L Host Access Protocol December 1983

RFC878

Table of Contents

1 INTRODUCTION.......................................... 1

2 THE ARPANET 1822L HOST ACCESS PROTOCOL................ 3

2.1 Addresses and Names................................. 5

2.2 Name Translations................................... 7

2.2.1 Authorization and Effectiveness................... 7

2.2.2 Translation Policies............................. 11

2.2.3 Reporting Destination Host Downs................. 13

2.2.4 1822L and 1822 Interoperability.................. 15

2.3 Uncontrolled Packets............................... 16

2.4 Establishing Host-IMP Communications............... 19

2.5 Counting RFNMs When Using 1822L.................... 20

2.6 1822L Name Server.................................. 23

3 1822L LEADER FORMATS................................. 25

3.1 Host-to-IMP 1822L Leader Format.................... 26

3.2 IMP-to-Host 1822L Leader Format.................... 34

4 REFERENCES........................................... 42

A 1822L-IP ADDRESS MAPPINGS............................ 43

- i -

1822L Host Access Protocol December 1983

RFC878

FIGURES

2.1 1822 Address Format.................................. 5

2.2 1822L Name Format.................................... 6

2.3 1822L Address Format................................. 6

3.1 Host-to-IMP 1822L Leader Format..................... 27

3.2 NDM Message Format.................................. 30

3.3 IMP-to-Host 1822L Leader Format..................... 35

3.4 Name Server Reply Format............................ 38

A.1 1822 Class A Mapping................................ 44

A.2 1822L Class A Mapping............................... 44

A.3 1822L Class B Mapping............................... 45

A.4 1822L Class C Mapping............................... 46

- ii -

1822L Host Access Protocol December 1983

RFC878

1 INTRODUCTION

This RFCspecifies the ARPANET 1822L Host Access Protocol, which

will allow hosts to use logical addressing (i.e., host names that

are independent of their physical location on the ARPANET) to

communicate with each other. This new host access protocol is

known as the ARPANET 1822L (for Logical) Host Access Protocol,

and is a successor to the current ARPANET 1822 Host Access

Protocol, which is described in sections 3.3 and 3.4 of BBN

Report 1822 [1]. Although the 1822L protocol uses different

Host-IMP leaders than the 1822 protocol, the IMPs will continue

to support the 1822 protocol, and hosts using either protocol can

readily communicate with each other (the IMPs will handle the

translation automatically).

The RFC's terminology is consistent with that used in Report

1822, and any new terms will be defined when they are first used.

Familiarity with Report 1822 (section 3 in particular) is

assumed. As could be eXPected, the RFCmakes many references to

Report 1822. As a result, it uses, as a convenient abbreviation,

"see 1822(x)" instead of "please refer to Report 1822, section x,

for further details".

This RFCupdates, and obsoletes, RFC851. The changes from that

RFCare:

- 1 -

1822L Host Access Protocol December 1983

RFC878

o Section 2.2.4 was rewritten for clarity.

o Section 2.5 was expanded to further discuss the effects of

using 1822L names on host-to-host virtual circuits.

o In section 3.2, the type 1 IMP-to-host message has two new

suBTypes, the type 9 message has one new subtype, and the type

15, subtype 4 message is no longer defined.

o An appendix describing the mapping between 1822L names and

internet (IP) addresses has been added.

All of these changes to RFC851 are marked by revision bars (as

shown here) in the right margin.

- 2 -

1822L Host Access Protocol December 1983

RFC878

2 THE ARPANET 1822L HOST ACCESS PROTOCOL

The ARPANET 1822L Host Access Protocol allows a host to use

logical addressing to communicate with other hosts on the

ARPANET. Basically, logical addressing allows hosts to refer to

each other using an 1822L name (see section 2.1) which is

independent of a host's physical location in the network. IEN

183 (also published as BBN Report 4473) [2] gives the use of

logical addressing considerable justification. Among the

advantages it cites are:

o The ability to refer to each host on the network by a name

independent of its location on the network.

o Allowing different hosts to share the same host port on a

time-division basis.

o Allowing a host to use multi-homing (where a single host uses

more than one port to communicate with the network).

o Allowing several hosts that provide the same service to share

the same name.

The main differences between the 1822 and 1822L protocols are the

format of the leaders that are used to introduce messages between

a host and an IMP, and the specification in those leaders of the

source and/or destination host(s). Hosts have the choice of

- 3 -

1822L Host Access Protocol December 1983

RFC878

using the 1822 or the 1822L protocol. When a host comes up on an

IMP, it declares itself to be an 1822 host or an 1822L host by

the type of NOP message (see section 3.1) it uses. Once up,

hosts can switch from one protocol to the other by issuing an

appropriate NOP. Hosts that do not use the 1822L protocol will

still be addressable by and can communicate with hosts that do,

and vice-versa.

Another difference between the two protocols is that the 1822

leaders are symmetric, while the 1822L leaders are not. The term

symmetric means that in the 1822 protocol, the exact same leader

format is used for messages in both directions between the hosts

and IMPs. For example, a leader sent from a host over a cable

that was looped back onto itself (via a looping plug or faulty

hardware) would arrive back at the host and appear to be a legal

message from a real host (the destination host of the original

message). In contrast, the 1822L headers are not symmetric, and

a host can detect if the connection to its IMP is looped by

receiving a message with the wrong leader format. This allows

the host to take appropriate action upon detection of the loop.

- 4 -

1822L Host Access Protocol December 1983

RFC878

2.1 Addresses and Names

The 1822 protocol defines one form of host specification, and the

1822L protocol defines two additional ways to identify network

hosts. These three forms are 1822 addresses, 1822L names, and

1822L addresses.

1822 addresses are the 24-bit host addresses found in 1822

leaders. They have the following format:

1 8 9 24

+----------------+---------------------------------+

Host number IMP number

+----------------+---------------------------------+

1822 Address Format

Figure 2.1

These fields are quite large, and the ARPANET will never use more

than a fraction of the available address space. 1822 addresses

are used in 1822 leaders only.

1822L names are 16-bit unsigned numbers that serve as a logical

identifier for one or more hosts. 1822L names have a much

simpler format:

- 5 -

1822L Host Access Protocol December 1983

RFC878

1 16

+--------------------------------+

1822L name

+--------------------------------+

1822L Name Format

Figure 2.2

The 1822L names are just 16-bit unsigned numbers, except that

bits 1 and 2 are not both zeros (see below). This allows over

49,000 hosts to be specified.

1822 addresses cannot be used in 1822L leaders, but there may be

a requirement for an 1822L host to be able to address a specific

physical host port or IMP fake host. 1822L addresses are used

for this function. 1822L addresses form a subset of the 1822L

name space, and have both bits 1 and 2 off.

1 2 3 8 9 16

+---+---+------------+----------------+

0 0 host # IMP number

+---+---+------------+----------------+

1822L Address Format

Figure 2.3

- 6 -

1822L Host Access Protocol December 1983

RFC878

This format allows 1822L hosts to directly address hosts 0-63 at

IMPs 1-255 (IMP 0 does not exist). Note that the highest host

numbers are reserved for addressing the IMP's internal fake

hosts. At this writing, the IMP has seven fake hosts, so host

numbers 57-63 address the IMP fake hosts, while host numbers 0-56

address real hosts external to the IMP. As the number of IMP

fake hosts changes, this boundary point will also change.

2.2 Name Translations

There are a number of factors that determine how an 1822L name is

translated by the IMP into a physical address on the network.

These factors include which translations are legal; in what order

different translations for the same name should be attempted;

which legal translations shouldn't be attempted because a

particular host port is down; and the interoperability between

1822 and 1822L hosts. These issues are discussed in the

following sections.

2.2.1 Authorization and Effectiveness

Every host on a C/30 IMP, regardless of whether it is using the

1822 or 1822L protocol to access the network, can have one or

more 1822L names (logical addresses). Hosts using 1822L can then

- 7 -

1822L Host Access Protocol December 1983

RFC878

use these names to address the hosts in the network independent

of their physical locations. Because of the implementation

constraints mentioned in the introduction, hosts on non-C/30 IMPs

cannot be assigned 1822L names. To circumvent this restriction,

however, 1822L hosts can also use 1822L addresses to access all

of the other hosts.

At this point, several questions arise: How are these names

assigned, how do they become known to the IMPs (so that

translations to physical addresses can be made), and how do the

IMPs know which host is currently using a shared port? To answer

each question in order:

Names are assigned by a central network administrator. When each

name is created, it is assigned to a host (or a group of hosts)

at one or more specific host ports. The host(s) are allowed to

reside at those specific host ports, and nowhere else. If a host

moves, it will keep the same name, but the administrator has to

update the central database to reflect the new host port.

Changes to this database are distributed to the IMPs by the

Network Operations Center (NOC). For a while, the host may be

allowed to reside at either of (or both) the new and old ports.

Once the correspondence between a name and one or more hosts

ports where it may be used has been made official by the

administrator, that name is said to be authorized. 1822L

- 8 -

1822L Host Access Protocol December 1983

RFC878

addresses, which actually refer to physical host ports, are

always authorized in this sense.

Once a host has been assigned one or more names, it has to let

the IMPs know where it is and what name(s) it is using. There

are two cases to consider, one for 1822L hosts and another for

1822 hosts. The following discussion only pertains to hosts on

C/30 IMPs.

When an IMP sees an 1822L host come up on a host port, the IMP

has no way of knowing which host has just come up (several hosts

may share the same port, or one host may prefer to be known by

different names at different times). This requires the host to

declare itself to the IMP before it can actually send and receive

messages. This function is performed by a new host-to-IMP

message, the Name Declaration Message (NDM), which lists the

names that the host would like to be known by. The IMP checks

its tables to see if each of the names is authorized, and sends

an NDM Reply to the host saying which names were actually

authorized and can now be used for sending and receiving messages

(i.e., which names are effective). A host can also use an NDM

message to change its list of effective names (it can add to and

delete from the list) at any time. The only constraint on the

host is that any names it wishes to use can become effective only

if they are authorized.

- 9 -

1822L Host Access Protocol December 1983

RFC878

In the second case, if a host comes up on a C/30 IMP using the

1822 protocol, the IMP automatically makes the first name the IMP

finds in its tables for that host become effective when it

receives the first 1822 NOP from the host. Thus, even though the

host is using the 1822 protocol, it can still receive messages

from 1822L hosts via its 1822L name. Of course, it can also

receive messages from an 1822L host via its 1822L address as

well. (Remember, the distinction between 1822L names and

addresses is that the addresses correspond to physical locations

on the network, while the names are strictly logical

identifiers). The IMPs translate between the different leaders

and send the proper leader in each case (see section 2.2.4).

The third question above has by now already been answered. When

an 1822L host comes up, it uses the NDM message to tell the IMP

which host it is (which names it is known by). Even if this is a

shared port, the IMP knows which host is currently connected.

Whenever a host goes down, its names automatically become non-

effective. When it comes back up, it has to make them effective

again.

- 10 -

1822L Host Access Protocol December 1983

RFC878

2.2.2 Translation Policies

Several hosts can share the same 1822L name. If more than one of

these hosts is up at the same time, any messages sent to that

1822L name will be delivered to just one of the hosts sharing

that name, and a RFNM will be returned as usual. However, the

sending host will not receive any indication of which host

received the message, and subsequent messages to that name are

not guaranteed to be sent to the same host. Typically, hosts

providing exactly the same service could share the same 1822L

name in this manner.

Similarly, when a host is multi-homed, the same 1822L name may

refer to more than one host port (all connected to the same

host). If the host is up on only one of those ports, that port

will be used for all messages addressed to the host. However, if

the host were up on more than one port, the message would be

delivered over just one of those ports, and the subnet would

choose which port to use. This port selection could change from

message to message. If a host wanted to insure that certain

messages were delivered to it on specific ports, these messages

could use either the port's 1822L address or a specific 1822L

name that referred to that port alone.

- 11 -

1822L Host Access Protocol December 1983

RFC878

Three different address selection policies are available for the

name mapping process. When translated, each name uses one of the

three policies (the policy is pre-determined on a per-name

basis). The three policies are:

o Attempt each translation in the order in which the physical

addresses are listed in the IMP's translation tables, to find

the first reachable physical host address. This list is

always searched from the top whenever an uncontrolled packet

is to be sent or a new virtual circuit connection has to be

created (see section 2.5). This is the most commonly used

policy.

o Selection of the closest physical address, which uses the

IMP's routing tables to find the translation to the

destination IMP with the least delay path whenever an

uncontrolled packet is to be sent or a new virtual circuit

connection has to be created.

o Use load leveling. This is similar to the second policy, but

differs in that searching the address list for a valid

translation starts at the address following where the previous

translation search ended whenever an uncontrolled packet is to

be sent or a new virtual circuit connection has to be created.

This attempts to spread out the load from any one IMP's hosts

- 12 -

1822L Host Access Protocol December 1983

RFC878

to the various host ports associated with a particular name.

Note that this is NOT network-wide load leveling, which would

require a distributed algorithm and tables.

2.2.3 Reporting Destination Host Downs

As was explained in report 1822, and as will be discussed in

greater detail in section 2.5, whenever regular messages are sent

by a host, the IMP opens a virtual circuit connection to each

destination host from the source host. A connection will stay

open at least as long as there are any outstanding (un-RFNMed)

messages using it and both the source and destination hosts stay

up.

However, the destination host may go down for some reason during

the lifetime of a connection. If the host goes down while there

are no outstanding messages to it in the network, then the

connection is closed and no other action is taken until the

source host submits the next message for that destination. At

that time, ONE of the following events will occur:

A1. If 1822 or an 1822L address is being used to specify the

destination host, then the source host will receive a type 7

(Destination Host Dead) message from the IMP.

A2. If an 1822L name is being used to specify the destination

- 13 -

1822L Host Access Protocol December 1983

RFC878

host, and the name maps to only one authorized host port,

then a type 7 message will also be sent to the source host.

A3. If an 1822L name is being used to specify the destination

host, and the name maps to more than one authorized host

port, then the IMP attempts to open a connection to another

authorized and effective host port for that name. If no

such connection can be made, the host will receive a type 15

(1822L Name or Address Error), subtype 5 (no effective

translations) message (see section 3.2). Note that a type 7

message cannot be returned to the source host, since type 7

messages refer to a particular destination host port, and

the name maps to more than one destination port.

Things get a bit more complicated if there are any outstanding

messages on the connection when the destination host goes down.

The connection will be closed, and one of the following will

occur:

B1. If 1822 or an 1822L address is being used to specify the

destination host, then the source host will receive a type 7

message for each outstanding message.

B2. If an 1822L name is being used to specify the destination

host, then the source host will receive a type 9 (Incomplete

Transmission), subtype 6 (message lost due to logically

addressed host going down) message for each outstanding

- 14 -

1822L Host Access Protocol December 1983

RFC878

message. The next time the source host submits another

message for that same destination name, the previous

algorithm will be used (either step A2 or step A3).

The above two algorithms also apply when a host stays up, but

declares the destination name for an existing connection to no

longer be effective. In this case, however, the type 7 messages

above will be replaced by type 15, subtype 3 (name not effective)

messages.

Section 2.3 discusses how destination host downs are handled for

uncontrolled packets.

2.2.4 1822L and 1822 Interoperability

As has been previously stated, 1822 and 1822L hosts can

intercommunicate, and the IMPs will automatically handle any

necessary leader and address format conversions. However, not

every combination of 1822 and 1822L hosts allows full

interoperability with regard to the use of 1822L names, since

1822 hosts are restricted to using physical addresses.

There are two possible situations where any incompatibility could

arise:

- 15 -

1822L Host Access Protocol December 1983

RFC878

o An 1822 host sending a message to an 1822L host: The 1822

host specifies the destination host by its 1822 address. The

destination host will receive the message with an 1822L leader

containing the 1822L addresses of the source and destination

hosts.

o An 1822L host sending a message to an 1822 host: The 1822L

host can use 1822L names or addresses to specify both the

source and destination hosts. The destination host will

receive the message with an 1822 leader containing the 1822

address of the source host.

2.3 Uncontrolled Packets

Uncontrolled packets (see 1822(3.6)) present a unique problem for

the 1822L protocol. Uncontrolled packets use none of the normal

ordering and error-control mechanisms in the IMP, and do not use

the normal virtual circuit connection facilities. As a result,

uncontrolled packets need to carry all of their overhead with

them, including source and destination names. If 1822L names are

used when sending an uncontrolled packet, additional information

is now required by the subnetwork when the packet is transferred

to the destination IMP. This means that less host-to-host data

can be contained in the packet than is possible between 1822

- 16 -

1822L Host Access Protocol December 1983

RFC878

hosts.

Uncontrolled packets that are sent between 1822 hosts may contain

not more than 991 bits of data. Uncontrolled packets that are

sent to and/or from 1822L hosts are limited to 32 bits less, or

not more than 959 bits. Packets that exceed this length will

result in an error indication to the host, and the packet will

not be sent. This error indication represents an enhancement to

the previous level of service provided by the IMP, which would

simply discard an overly long uncontrolled packet without

notification.

Other enhancements that are provided for uncontrolled packet

service are a notification to the host of any errors that are

detected by the host's IMP when it receives the packet. A host

will be notified if an uncontrolled packet contains an error in

the 1822L name specification, such as if the name is not

authorized or effective, if the remote host is unreachable (which

is indicated by none of its names being effective), if network

congestion control throttled the packet before it left the source

IMP, or for any other reason the source IMP was not able to send

the packet on its way.

In most cases, the host will not be notified if the uncontrolled

packet was lost once it was transmitted by the source IMP.

- 17 -

1822L Host Access Protocol December 1983

RFC878

However, the IMP will attempt to notify the source host if a

logically-addressed uncontrolled packet was mistakenly sent to a

host that the source IMP thought was effective, but which turned

out to be dead or non-effective at the destination IMP. This

non-delivery notice is sent back to the source IMP as an

uncontrolled packet from the destination IMP, so the source host

is not guaranteed to receive this indication.

If the source IMP successfully receives the non-delivery notice,

then the source host will receive a type 15 (1822L Name or

Address Error), subtype 6 (down or non-effective port) message.

If the packet is resubmitted or another packet is sent to the

same destination name, and there are no available effective

translations, then the source host will receive a type 15,

subtype 5 (no effective translations) message if the destination

name has more than one mapping; or will receive either a type 7

(Destination Host Dead) or a type 15, subtype 3 (name not

effective) message if the destination name has a single

translation.

Those enhancements to the uncontrolled packet service that are

not specific to logical addressing will be available to hosts

using 1822 as well as 1822L. However, uncontrolled packets must

be sent using 1822L leaders in order to receive any indication

that the packet was lost once it has left the source IMP.

- 18 -

1822L Host Access Protocol December 1983

RFC878

2.4 Establishing Host-IMP Communications

When a host comes up on an IMP, or after there has been a break

in the communications between the host and its IMP (see

1822(3.2)), the orderly flow of messages between the host and the

IMP needs to be properly (re)established. This allows the IMP

and host to recover from most any failure in the other or in

their communications path, including a break in mid-message.

The first messages that a host should send to its IMP are three

NOP messages. Three messages are required to insure that at

least one message will be properly read by the IMP (the first NOP

could be concatenated to a previous message if communications had

been broken in mid-stream, and the third provides redundancy for

the second). These NOPs serve several functions: they

synchronize the IMP with the host, they tell the IMP how much

padding the host requires between the message leader and its

body, and they also tell the IMP whether the host will be using

1822 or 1822L leaders.

Similarly, the IMP will send three NOPs to the host when it

detects that the host has come up. Actually, the IMP will send

six NOPs, alternating three 1822 NOPs with three 1822L NOPs.

Thus, the host will see three NOPs no matter which protocol it is

using. The NOPs will be followed by two Interface Reset

- 19 -

1822L Host Access Protocol December 1983

RFC878

messages, one of each style. If the IMP receives a NOP from the

host while the above sequence is occurring, the IMP will only

send the remainder of the NOPs and the Interface Reset in the

proper style. The 1822 NOPs will contain the 1822 address of the

host interface, and the 1822L NOPs will contain the corresponding

1822L address.

Once the IMP and the host have sent each other the above

messages, regular communications can commence. See 1822(3.2) for

further details concerning the ready line, host tardiness, and

other issues.

2.5 Counting RFNMs When Using 1822L

When a host submits a regular message using an 1822 leader, the

IMP checks for an existing simplex virtual circuit connection

(see 1822(3.1)) from the source host to the destination host. If

such a connection already exists, it is used. Otherwise, a new

connection from the source host port to the destination host port

is opened. In either case, there may be at most eight messages

outstanding on that connection at any one time. If a host

submits a ninth message on that connection before it receives a

reply for the first message, then the host will be blocked until

the reply is sent for the first message.

- 20 -

1822L Host Access Protocol December 1983

RFC878

Such connections can stay open for some time, but are timed out

after three minutes of no activity, or can be closed if there is

contention for the connection blocks in either the source or

destination IMP. However, a connection will never be closed as

long as there are any outstanding messages on it. This allows a

source host to count the number of replies it has received for

messages to each destination host address in order to avoid being

blocked by submitting a ninth outstanding message on any

connection.

When a host submits a regular message using an 1822L leader, a

similar process occurs, except that in this case, connections are

distinguished by the source port/source name/destination name

combination. When the message is received from a host, the IMP

first looks for an open connection for that same port and source

name/destination name pair. If such a connection is found, then

it is used, and no further name translation is performed. If,

however, no open connection was found, then the destination name

is translated, and a connection opened to the physical host port.

As long as there are any outstanding messages on the connection

it will stay open, and it will have the same restriction that

only eight messages may be outstanding at any one time. Thus, a

source host can still count replies to avoid being blocked, but

they must be counted on a source port and source name/destination

- 21 -

1822L Host Access Protocol December 1983

RFC878

name pair basis, instead of just by source port and destination

host address as before.

Since connections are based on the source name as well as the

destination name, this implies that there may be more than one

open connection from physical host port A to physical host port

B, which would allow more than 8 outstanding messages

simultaneously from the first to the second port. However, for

this to occur, either the source or destination names, or both,

must differ from one connection to the next. For example, if the

names "543" and "677" both translate to physical port 3 on IMP

51, then the host on that port could open four connections to

itself by sending messages from "543" to "543", from "543" to

"677", from "677" to "543", and from "677" to "677".

As has already been stated, the destination names in regular

messages are only translated when connections are first opened.

Once a connection is open, that connection, and its destination

physical host port, will continue to be used until it is closed.

If, in the meantime, a "better" destination host port belonging

to the same destination name became available, it would not be

used until the next time a new connection is opened to that

destination name.

- 22 -

1822L Host Access Protocol December 1983

RFC878

Also, the act of making an 1822L name be non-effective will not

automatically cause any connections using that name to be closed.

However, they will be closed after at most three minutes of

inactivity. A host can, if it wishes, make all of its names at a

port be noneffective and close all of its connections to and from

the port by flapping the host's ready line to that IMP port.

2.6 1822L Name Server

There may be times when a host wants to perform its own

translations, or might need the full list of physical addresses

to which a particular name maps. For example, a connection-based

host-to-host protocol may require that the same physical host

port on a multi-homed host be used for all messages using that

host-to-host connection, and the host does not wish to trust the

IMP to always deliver messages using a destination name to the

same host port.

In these cases, the host can submit a type 11 (Name Server

Request) message to the IMP, which requests the IMP to translate

the destination 1822L name and return a list of the addresses to

which it maps. The IMP will respond with a type 11 (Name Server

Reply) message, which contains the selection policy in use for

that name, the number of addresses to which the name maps, the

- 23 -

1822L Host Access Protocol December 1983

RFC878

addresses themselves, and for each address, whether it is

effective and its routing distance from the IMP. See section 3.2

for a complete description of the message's contents.

Using this information, the source host could make an informed

decision on which of the physical host ports corresponding to an

1822L name to use and then send the messages to that port, rather

than to the name.

The IMP also supports a different type of name service. A host

needs to issue a Name Declaration Message to the IMP in order to

make its names effective, but it may not wish to keep its names

in some table or file in the host. In this case, it can ask the

IMP to tell it which names it is authorized to use.

In this case, the host submits a type 12 (Port List Request)

message to the IMP, and the IMP replies with a type 12 (Port List

Reply) message. It contains, for the host port over which the

IMP received the request and sent the reply, the number of names

that map to the port, the list of names, and whether or not each

name is effective. The host can then use this information in

order to issue the Name Declaration Message. Section 3.2

contains a complete description of the reply's contents.

- 24 -

1822L Host Access Protocol December 1983

RFC878

3 1822L LEADER FORMATS

The following sections describe the formats of the leaders that

precede messages between an 1822L host and its IMP. They were

designed to be as compatible with the 1822 leaders as possible.

The second, fifth, and sixth Words are identical in the two

leaders, and all of the existing functionality of the 1822

leaders has been retained. In the first word, the 1822 New

Format Flag is now also used to identify the two types of 1822L

leaders, and the Handling Type has been moved to the second byte.

The third and fourth words contain the Source and Destination

1822L Name, respectively.

- 25 -

1822L Host Access Protocol December 1983

RFC878

3.1 Host-to-IMP 1822L Leader Format

1 4 5 8 9 16

+--------+--------+----------------+

1822L

Unused H2I Handling Type

Flag

+--------+--------+----------------+

17 20 21 22 24 25 32

+--------+-+------+----------------+

TLeader

Unused RFlags Message Type

C

+--------+-+------+----------------+

33 48

+----------------------------------+

Source Host

+----------------------------------+

49 64

+----------------------------------+

Destination Host

+----------------------------------+

65 76 77 80

+-------------------------+--------+

Message ID Sub-type

+-------------------------+--------+

81 96

+----------------------------------+

Unused

+----------------------------------+

Host-to-IMP 1822L Leader Format

Figure 3.1

- 26 -

1822L Host Access Protocol December 1983

RFC878

Bits 1-4: Unused, must be set to zero.

Bits 5-8: 1822L Host-to-IMP Flag:

This field is set to decimal 13 (1101 in binary).

Bits 9-16: Handling Type:

This field is bit-coded to indicate the transmission

characteristics of the connection desired by the host. See

1822(3.3).

Bit 9: Priority Bit:

Messages with this bit on will be treated as priority

messages.

Bits 10-16: Unused, must be zero.

Bits 17-20: Unused, must be zero.

Bit 21: Trace Bit:

If equal to one, this message is designated for tracing as

it proceeds through the network. See 1822(5.5).

Bits 22-24: Leader Flags:

Bit 22: A flag available for use by the destination host.

See 1822(3.3) for a description of its use by the IMP's

TTY Fake Host.

Bits 23-24: Reserved for future use, must be zero.

- 27 -

1822L Host Access Protocol December 1983

RFC878

Bits 25-32: Message Type:

Type 0: Regular Message - All host-to-host communication

occurs via regular messages, which have several sub-

types, found in bits 77-80. These sub-types are:

0: Standard - The IMP uses its full message and error

control facilities, and host blocking may occur.

3: Uncontrolled Packet - The IMP will perform no

message-control functions for this type of

message, and network flow and congestion control

may cause loss of the packet. Also see 1822(3.6)

and section 2.3.

1-2,4-15: Unassigned.

Type 1: Error Without Message ID - See 1822(3.3).

Type 2: Host Going Down - see 1822(3.3).

Type 3: Name Declaration Message (NDM) - This message is

used by the host to declare which of its 1822L names is

or is not effective (see section 2.2.1), or to make all

of its names non-effective. The first 16 bits of the

data portion of the NDM message, following the leader

and any leader padding, contains the number of 1822L

names contained in the message. This is followed by

the 1822L name entries, each 32 bits long, of which the

first 16 bits is a 1822L name and the second 16 bits

contains either of the integers zero or one. Zero

- 28 -

1822L Host Access Protocol December 1983

RFC878

indicates that the name should not be effective, and

one indicates that the name should be effective. The

IMP will reply with a NDM Reply message (see section

3.2) indicating which of the names are now effective

and which are not. Pictorially, a NDM message has the

following format (including the leader, which is

printed in hexadecimal, and without any leader

padding):

- 29 -

1822L Host Access Protocol December 1983

RFC878

1 16 17 32 33 48

+----------------+----------------+----------------+

0D00 0003 0000

+----------------+----------------+----------------+

49 64 65 80 81 96

+----------------+----------------+----------------+

0000 0000 0000

+----------------+----------------+----------------+

97 112 113 128 129 144

+----------------+----------------+----------------+

# of entries 1822L name #1 0 or 1

+----------------+----------------+----------------+

145 160 161 176

+----------------+----------------+

1822L name #2 0 or 1 etc.

+----------------+----------------+

NDM Message Format

Figure 3.2

An NDM with zero entries will cause all current

effective names for the host to become non-effective.

Type 4: NOP - This allows the IMP to know which style of

leader the host wishes to use. A 1822L NOP signifies

that the host wishes to use 1822L leaders, and an 1822

NOP signifies that the host wishes to use 1822 leaders.

All of the other remarks concerning the NOP message in

- 30 -

1822L Host Access Protocol December 1983

RFC878

1822(3.3) still hold. The host should always issue

NOPs in groups of three to insure proper reception by

the IMP. Also see section 2.4 for a further discussion

on the use of the NOP message.

Type 8: Error with Message ID - see 1822(3.3).

Type 11: Name Server Request - This allows the host to use

the IMP's logical addressing tables as a name server.

The destination name in the 1822L leader is translated,

and the IMP replies with a Name Server Reply message,

which lists the physical host addresses to which the

destination name maps.

Type 12: Port List Request - This allows the physical host

to request the list of names that map to the host port

over which this request was received by the IMP. The

IMP replies with a Port List Reply message, which lists

the names that map to the port.

Types 5-7,9-10,13-255: Unassigned.

Bits 33-48: Source Host:

This field contains one of the source host's 1822L names

(or, alternatively, the 1822L address of the host port the

message is being sent over). This field is not

automatically filled in by the IMP, as in the 1822 protocol,

because the host may be known by several names and may wish

- 31 -

1822L Host Access Protocol December 1983

RFC878

to use a particular name as the source of this message. All

messages from the same host need not use the same name in

this field. Each source name, when used, is checked for

authorization, effectiveness, and actually belonging to this

host. Messages using names that do not satisfy all of these

requirements will not be delivered, and will instead result

in an error message being sent back into the source host.

If the host places its 1822L address in this field, the

address is checked to insure that it actually represents the

host port where the message originated.

Bits 49-64: Destination Host:

This field contains the 1822L name or address of the

destination host. If it contains a name, the name will be

checked for effectiveness, with an error message returned to

the source host if the name is not effective.

Bits 65-76: Message ID:

This is a host-specified identification used in all type 0

and type 8 messages, and is also used in type 2 messages.

When used in type 0 messages, bits 65-72 are also known as

the Link Field, and should contain values specified in

Assigned Numbers [3] appropriate for the host-to-host

protocol being used.

- 32 -

1822L Host Access Protocol December 1983

RFC878

Bits 77-80: Sub-type:

This field is used as a modifier by message types 0, 2, 4,

and 8.

Bits 81-96: Unused, must be zero.

- 33 -

1822L Host Access Protocol December 1983

RFC878

3.2 IMP-to-Host 1822L Leader Format

1 4 5 8 9 16

+--------+--------+----------------+

1822L

Unused I2H Handling Type

Flag

+--------+--------+----------------+

17 20 21 22 24 25 32

+--------+-+------+----------------+

TLeader

Unused RFlags Message Type

C

+--------+-+------+----------------+

33 48

+----------------------------------+

Source Host

+----------------------------------+

49 64

+----------------------------------+

Destination Host

+----------------------------------+

65 76 77 80

+-------------------------+--------+

Message ID Sub-type

+-------------------------+--------+

81 96

+----------------------------------+

Message Length

+----------------------------------+

IMP-to-Host 1822L Leader Format

Figure 3.3

- 34 -

1822L Host Access Protocol December 1983

RFC878

Bits 1-4: Unused and set to zero.

Bits 5-8: 1822L IMP-to-Host Flag:

This field is set to decimal 14 (1110 in binary).

Bits 9-16: Handling Type:

This has the value assigned by the source host (see section

3.1). This field is only used in message types 0, 5-9, and

15.

Bits 17-20: Unused and set to zero.

Bit 21: Trace Bit:

If equal to one, the source host designated this message for

tracing as it proceeds through the network. See 1822(5.5).

Bits 22-24: Leader Flags:

Bit 22: Available as a destination host flag.

Bits 23-24: Reserved for future use, set to zero.

Bits 25-32: Message Type:

Type 0: Regular Message - All host-to-host communication

occurs via regular messages, which have several sub-

types. The sub-type field (bits 77-80) is the same as

sent in the host-to-IMP leader (see section 3.1).

Type 1: Error in Leader - See 1822(3.4). In addition to its

already defined sub-types, this message has two new

- 35 -

1822L Host Access Protocol December 1983

RFC878

sub-types:

4: Illegal Leader Style - The host submitted a leader

in which bits 5-8 did not contain the value 13,

14, or 15 decimal.

5: Wrong Leader Style - The host submitted an 1822L

leader when the IMP was expecting an 1822 leader,

or vice-versa.

Type 2: IMP Going Down - See 1822(3.4).

Type 3: NDM Reply - This is a reply to the NDM host-to-IMP

message (see section 3.1). It will have the same

number of entries as the NDM message that is being

replying to, and each listed 1822L name will be

accompanied by a zero or a one (see figure 3.2). A

zero signifies that the name is not effective, and a

one means that the name is now effective.

Type 4: NOP - The host should discard this message. It is

used during initialization of the IMP/host

communication. The Destination Host field will contain

the 1822L Address of the host port over which the NOP

is being sent. All other fields are unused.

Type 5: Ready for Next Message (RFNM) - See 1822(3.4).

Type 6: Dead Host Status - See 1822(3.4).

Type 7: Destination Host or IMP Dead (or unknown) - See

1822(3.4).

- 36 -

1822L Host Access Protocol December 1983

RFC878

Type 8: Error in Data - See 1822(3.4).

Type 9: Incomplete Transmission - See 1822(3.4). In

addition to its already defined sub-types, this message

has one new sub-type:

6: Logically Addressed Host Went Down - A logically

addressed message was lost in the network because

the destination host to which it was being

delivered went down. The message should be

resubmitted by the source host, since there may be

another effective host port to which the message

could be delivered (see section 2.2.3).

Type 10: Interface Reset - See 1822(3.4).

Type 11: Name Server Reply - This reply to the Name Server

Request host-to-IMP message contains, following the

leader and any leader padding, a word with the

selection policy and the number of physical addresses

to which the destination name maps, followed by two

words per physical address: the first word contains an

1822L address, and the second word contains a bit

signifying whether or not that particular translation

is effective and the routing distance (expected network

transmission delay, in 6.4 ms units) to the address's

IMP. In figure 3.4, which includes the leader without

any leader padding, EFF is 1 for effective and 0 for

- 37 -

1822L Host Access Protocol December 1983

RFC878

non-effective, and POL is a two-bit number indicating

the selection policy for the name (see section 2.2.2):

0: First reachable.

1: Closest physical address.

2: Load leveling.

3: Unused.

1 16 17 32 33 48

+----------------+----------------+----------------+

0E00 000B 0000

+----------------+----------------+----------------+

49 64 65 80 81 96

+----------------+----------------+----------------+

dest. name 0000 0000

+----------------+----------------+----------------+

97 112 113 128 129 144

+-+--------------+----------------+-+--------------+

P E

O # of addrs 1822L addr #1 F routing dist

L F

+-+--------------+----------------+-+--------------+

145 160 161 176

+----------------+-+--------------+

E

1822L addr #2 F routing dist etc.

F

+----------------+-+--------------+

Name Server Reply Format

Figure 3.4

- 38 -

1822L Host Access Protocol December 1983

RFC878

Type 12: Port List Reply - This is the reply to the Port

List Request host-to-IMP message. It contains the

number of names that map to this physical host port,

followed by two words per name: the first word contains

an 1822L name that maps to this port, and the second

contains either a zero or a one, signifying whether or

not that particular translation is effective. The

format is identical to the type 3 NDM Reply message

(see figure 3.2).

Type 15: 1822L Name or Address Error - This message is sent

in response to a type 0 message from a host that

contained an erroneous Source Host or Destination Host

field. Its sub-types are:

0: The Source Host 1822L name is not authorized or not

effective.

1: The Source Host 1822L address does not match the

host port used to send the message.

2: The Destination Host 1822L name is not authorized.

3: The physical host to which this singly-homed

Destination Host name translated is authorized and

up, but not effective. If the host was actually

down, a type 7 message would be returned, not a

type 15.

5: The multi-homed Destination Host name is authorized,

- 39 -

1822L Host Access Protocol December 1983

RFC878

but has no available effective translations.

6: A logically-addressed uncontrolled packet was sent

to a dead or non-effective host port. However, if

it is resubmitted, there may be another effective

host port to which the IMP may be able to attempt

to send the packet.

7: Logical addressing is not in use in this network.

8-15: Unassigned.

Types 4,13-14,16-255: Unassigned.

Bits 33-48: Source Host:

For type 0 messages, this field contains the 1822L name or

address of the host that originated the message. All

replies to the message should be sent to the host specified

herein. For message types 5-9 and 15, this field contains

the source host field used in a previous type 0 message sent

by this host.

Bits 49-64: Destination Host:

For type 0 messages, this field contains the 1822L name or

address that the message was sent to. This allows the

destination host to detect how it was specified by the

source host. For message types 5-9 and 15, this field

contains the destination host field used in a previous type

0 message sent by this host.

- 40 -

1822L Host Access Protocol December 1983

RFC878

Bits 65-76: Message ID:

For message types 0, 5, 7-9, and 15, this is the value

assigned by the source host to identify the message (see

section 3.1). This field is also used by message types 2

and 6.

Bits 77-80: Sub-type:

This field is used as a modifier by message types 0-2, 5-7,

9, and 15.

Bits 81-96: Message Length:

This field is contained in type 0, 3, 11, and 12 messages

only, and is the actual length in bits of the message

(exclusive of leader, leader padding, and hardware padding)

as computed by the IMP.

- 41 -

1822L Host Access Protocol December 1983

RFC878

4 REFERENCES

[1] "Specifications for the Interconnection of a Host and an

IMP", BBN Report 1822, December 1981 Revision.

[2] E. C. Rosen et. al., "ARPANET Routing Algorithm

Improvements", Internet Experimenter's Note 183 (also

published as BBN Report 4473, Vol. 1), August 1980, pp. 55-

107.

[3] J. Reynolds and J. Postel, "Assigned Numbers", Request For

Comments 870, October 1983, p. 14.

[4] J. Postel, ed., "Internet Protocol - DARPA Internet Program

Protocol Specification", Request for Comments 791, September

1981.

[5] J. Postel, "Address Mappings", Request for Comments 796,

September 1981.

- 42 -

1822L Host Access Protocol December 1983

RFC878

APPENDIX A

1822L-IP ADDRESS MAPPINGS

Once logical addressing is in active (or universal) use in a

network, to the extent that the "official" host tables for that

network specify hosts by their logical names rather than by their

physical network addresses, it would be desirable for hosts on

other networks to also be able to use the same logical names to

specify these hosts when sending traffic to them via the internet

[4].

Happily, there exists a natural mapping between logical names and

internet addresses that fits very nicely with the already

standard ARPANET-style address mapping as specified in RFC796,

Address Mappings [5]. The current ARPANET-style class A mapping

is as follows (from RFC796):

- 43 -

1822L Host Access Protocol December 1983

RFC878

+--------+ +--------+--------+

HOST ZERO IMP 1822 Address

+--------+ +--------+--------+

8 8 8

+--------+--------+--------+--------+

net # HOST LH IMP IP Address

+--------+--------+--------+--------+

8 8 8 8

1822 Class A Mapping

Figure A.1

For 1822L names and addresses, the mapping would be:

+--------+--------+

upper lower 1822L Name or Address

+--------+--------+

8 8

+--------+--------+--------+--------+

net # upper LH lower IP Address

+--------+--------+--------+--------+

8 8 8 8

1822L Class A Mapping

Figure A.2

For 1822L addresses, this mapping is identical to the 1822

mapping. For 1822L names, the IP address would appear to be

addressing a high-numbered (64-255) 1822 host. Although the LH

(logical host) field is still defined, its use is discouraged;

multiple logical names should now be used to multiplex multiple

- 44 -

1822L Host Access Protocol December 1983

RFC878

functions onto one physical host port.

This mapping extends to class B networks:

+--------+--------+

upper lower 1822L Name or Address

+--------+--------+

8 8

+----------------+--------+--------+

network number upper lower IP Address

+----------------+--------+--------+

16 8 8

1822L Class B Mapping

Figure A.3

Finally, logical addressing will allow IMP-based class C networks

for the first time. Previously, it was very hard to try to

divide the 8 bits of host specification into some number of host

bits and some number of IMP bits. However, if ALL of the

internet-accessible hosts on the network have logical names,

there is no reason why networks with up to 256 such logical names

cannot now use class C addresses, as follows:

- 45 -

1822L Host Access Protocol December 1983

RFC878

+--------+--------+

01000000 lower 1822L Name

+--------+--------+

8 8

+------------------------+--------+

network number lower IP Address

+------------------------+--------+

24 8

1822L Class C Mapping

Figure A.4

Those hosts on the network desiring internet access would be

assigned logical names in the range 40000 to 40377 (octal), and

the gateway(s) connected to that network would make the

translation from IP addresses to 1822L names as specified above.

Note that the network could have many more than 256 hosts, or 256

defined names; the only restriction is that hosts that desire

internet support or access be addressable by a name in the range

40000 - 40377. Traffic that was strictly local to the network

could use other names or even 1822L addresses.

- 46 -

1822L Host Access Protocol December 1983

RFC878

INDEX

1822...................................................... 3

1822 address.............................................. 5

1822 host................................................. 4

1822L..................................................... 3

1822L address............................................. 6

1822L and 1822 interoperability.......................... 15

1822L host................................................ 4

1822L name................................................ 5

address selection policy................................. 12

authorized................................................ 8

blocking................................................. 20

closest physical address................................. 12

connection............................................... 20

destination host..................................... 32, 40

effective............................................. 9, 23

first reachable.......................................... 12

handing type......................................... 27, 35

host downs............................................... 13

interoperability......................................... 15

leader flags......................................... 27, 35

link field............................................... 32

load leveling............................................ 12

logical addressing........................................ 3

message ID........................................... 32, 41

message length........................................... 41

message type......................................... 28, 35

multi-homing.............................................. 3

name server...................................... 23, 31, 37

NDM................................................... 9, 28

NDM reply............................................. 9, 36

NOC....................................................... 8

NOP........................................... 4, 19, 30, 36

priority bit............................................. 27

regular message...................................... 28, 35

RFNM................................................. 20, 36

source host.......................................... 31, 40

standard message......................................... 28

sub-type............................................. 33, 41

symmetric................................................. 4

trace bit............................................ 27, 35

- 47 -

1822L Host Access Protocol December 1983

RFC878

uncontrolled packet.................................. 16, 28

virtual circuit connection............................... 20

 
 
 
免责声明:本文为网络用户发布,其观点仅代表作者个人观点,与本站无关,本站仅提供信息存储服务。文中陈述内容未经本站证实,其真实性、完整性、及时性本站不作任何保证或承诺,请读者仅作参考,并请自行核实相关内容。
2023年上半年GDP全球前十五强
 百态   2023-10-24
美众议院议长启动对拜登的弹劾调查
 百态   2023-09-13
上海、济南、武汉等多地出现不明坠落物
 探索   2023-09-06
印度或要将国名改为“巴拉特”
 百态   2023-09-06
男子为女友送行,买票不登机被捕
 百态   2023-08-20
手机地震预警功能怎么开?
 干货   2023-08-06
女子4年卖2套房花700多万做美容:不但没变美脸,面部还出现变形
 百态   2023-08-04
住户一楼被水淹 还冲来8头猪
 百态   2023-07-31
女子体内爬出大量瓜子状活虫
 百态   2023-07-25
地球连续35年收到神秘规律性信号,网友:不要回答!
 探索   2023-07-21
全球镓价格本周大涨27%
 探索   2023-07-09
钱都流向了那些不缺钱的人,苦都留给了能吃苦的人
 探索   2023-07-02
倩女手游刀客魅者强控制(强混乱强眩晕强睡眠)和对应控制抗性的关系
 百态   2020-08-20
美国5月9日最新疫情:美国确诊人数突破131万
 百态   2020-05-09
荷兰政府宣布将集体辞职
 干货   2020-04-30
倩女幽魂手游师徒任务情义春秋猜成语答案逍遥观:鹏程万里
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案神机营:射石饮羽
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案昆仑山:拔刀相助
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案天工阁:鬼斧神工
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案丝路古道:单枪匹马
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案镇郊荒野:与虎谋皮
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案镇郊荒野:李代桃僵
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案镇郊荒野:指鹿为马
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案金陵:小鸟依人
 干货   2019-11-12
倩女幽魂手游师徒任务情义春秋猜成语答案金陵:千金买邻
 干货   2019-11-12
 
推荐阅读
 
 
 
>>返回首頁<<
 
靜靜地坐在廢墟上,四周的荒凉一望無際,忽然覺得,淒涼也很美
© 2005- 王朝網路 版權所有