1140 lines
43 KiB
Plaintext
1140 lines
43 KiB
Plaintext
.NC "The Design of the ARGO Network Layer"
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.sh 1 "Connectionless Network Layer
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.pp
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The following sections describe the design of the ARGO
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connectionless network layer (CLNL).
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The connectionless network service is provided by several
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network-layer protocols: ES-IS (ISO 9542),
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CLNP (ISO 8348), and (ISO 8208) X.25.
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The protocol CLNP is the primary connectionless network layer
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protocol.
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It is supported by X.25 when X.25 is used as a subnetwork layer.
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X.25 can also be viewed as a link layer protocol in this context.
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The ES-IS protocol supports CLNP by providing the following functions:
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.ip \(bu 5
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automatic mapping of NSAP-addresses to SNPA addresses,
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.ip \(bu 5
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automatic configuration of networks of end systems and intermediate
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systems, and
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.ip \(bu 5
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redirection of network-layer traffic in response to
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configuration changes.
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.pp
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The rest of this chapter describes the design of
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CLNP, the design of ES-IS,
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and the design of the connection-oriented
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network layer, including the connection-oriented subnetwork service (X.25).
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.pp
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CLNP has two subsets defined: the Inactive Network Layer
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protocol subset and the Non-Segmenting protocol subset.
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The Inactive Network Layer subset is a null-function subset
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in which the CLNP is not needed, and the
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protocol consists of sending
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a 1-byte header containing the value zero.
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This "subset" is not supported in ARGO.
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.pp
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The Non-Segmenting protocol subset permits simplification of the DT NPDU
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header when it is known that segmentation of the DT NPDU is not required.
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ARGO supports this subset.
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When this subset is used,
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the segmentation part of the DT NPDU (data packet) header is not present,
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and the \fIdon't segment\fR bit is set in the
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fixed part of the header.
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This subset is chosen by setting the bit
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\fICLNP_NO_SEG\fR in the \fIflags\fR argument to \fIclnp_output()\fR.
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.pp
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Throughout the remainder of this
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document,
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following definitions apply:
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.(b
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\(bu DT NPDU: data transfer NPDU.
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\(bu ER NPDU: error report NPDU.
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\(bu NPDU: either an ER or DT NPDU.
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.)b
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.sh 2 "DT NPDU Output"
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.pp
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A CLNP DT NPDU is transmitted by calling \fIclnp_output()\fR.
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.so figs/clnp_output.nr
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.\" FIGURE
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.CF
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outlines the sequence of steps taken by \fIclnp_output()\fR when
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transmitting an NPDU.
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The solid lines indicate normal flow of control. The
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dashed lines indicate possible error returns (with associated
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error code).
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.pp
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\fIClnp_output()\fR will automatically cache (in the \fIisopcb\fR)
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the header of each packet it sends. This cached copy of the header
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is used on subsequent sends reducing the amount of time spent generating
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the header. Therefore, the first action \fIclnp_output()\fR takes is to
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examine the cached header (if any). If the header is still valid (see below)
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then it is used. Otherwise, a new header is built.
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.sh 3 "When The Cached Header Is Invalid"
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.pp
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Before any resources are allocated, the options to be sent with the packet
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are examined. If any unsupported options are present, the error \fIEINVAL\fR
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is returned.
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Next, the length of the source and destination
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NSAP addresses (taken from the \fIisopcb\fR)
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are checked. The source address length may be zero. This
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indicates that \fIclnp_output()\fR should compute the source address based upon
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the route taken, in which case CLNP calls
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the function \fIclnp_srcroute()\fR.
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Source routing
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will be discussed in detail later in this section.
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If, in the process of checking
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the address lengths, an invalid length is detected, the error
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\fIENAMETOOLONG\fR is returned.
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.pp
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After checking the lengths of the addresses,
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CLNP allocates an \fImbuf\fR in which the DT NPDU header will be constructed.
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If an \fImbuf\fR cannot be found, the error
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\fIENOBUFS\fR is returned. Once the \fImbuf\fR is allocated,
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the fixed part of the DT NPDU header is copied into the \fImbuf\fR.
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.pp
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The next step is to route the DT NPDU. This is accomplished by the
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\fIclnp_route()\fR function.
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It is necessary to route the datagram early in the output process because
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in many cases, the source address will not be known until the route
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has been created.
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When a system is multi-homed it has several source addresses.
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The source address to choose depends on the
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network interface (thus, the route) used.
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.pp
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The address part of the DT NPDU follows the fixed part.
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Since appending the address part is the next task,
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the source address must be determined.
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Therefore the route must be determined.
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.pp
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After appending the address part to the fixed part of the
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NPDU header, CLNP
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appends any options given in the arguments to
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\fIclnp_output()\fR.
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The options are specified in a
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separate \fImbuf\fR stored in the \fIiso_pcb\fR.
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If this \fImbuf\fR
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pointer is not null, a copy of the \fImbuf\fR is made, and this copy is
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chained (appended) to the
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\fImbuf\fR in which the
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NPDU header resides. The options \fImbuf\fR linked in with the DT packet
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must be a copy of the options \fImbuf\fR passed to \fIclnp_output()\fR. If
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this was not done, then
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the options \fImbuf\fR passed would be freed by the interface
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driver after the NPDU had been transmitted.
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Since a copy must be made, it is possible for \fIclnp_output()\fR to
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return \fIENOBUFS\fR at this time.
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A later section of this chapter describes
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the handling of options in greater detail.
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.pp
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User data for the packet are passed to
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\fIclnp_output()\fR as an \fImbuf\fR chain.
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This \fImbuf\fR chain is appended to the DT NPDU header chain.
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At this point, the DT NPDU is ready for transmission.
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If header caching has not been disabled, a cache entry is made in the
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\fIisopcb\fR.
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If the size of the entire packet
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is less than the maximum transmission unit (MTU) of the
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network interface to be used,
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the packet is placed on the queue for that network interface,
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otherwise \fIclnp_fragment()\fR is invoked to
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break up the packet into smaller packets, called
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"derived NPDUs", and transmit the derived NPDUs.
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.sh 3 "When A Cached Header Exists"
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.pp
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In this case, \fIclnp_output()\fR updates the segmentation part of the
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header (if segmenting is permitted), computes the checksum, and transmits
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(or fragments) the packet.
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.pp
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The cached CLNP header is stored in the \fIstruct isopcb\fR. The field
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\fIisop_clnpcache\fR within the \fIisopcb\fR points to an \fImbuf\fR
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which contains a \fIstruct clnp_cache\fR:
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.(b
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\fC
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.TS
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tab(+);
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l s s.
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struct clnp_cache {
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.T&
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l l l l.
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+u_short+cni_securep;+/* ptr to security option */
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+struct iso_addr+clc_dst;+/* destination of packet */
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+struct mbuf+*clc_options;+/* ptr to options mbuf */
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+int+clc_flags;+/* flags passed to clnp_output */
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+int+clc_segoff;+/* offset of seg part of header */
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+struct sockaddr+*clc_firsthop;+/* first hop of packet */
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+struct ifnet+*clc_ifp;+/* ptr to interface */
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+struct mbuf+*clc_hdr;+/* cached pkt hdr (finally)! */
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};
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.TE
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\fR
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.)b
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The first three fields \fIclc_dst, clc_options\fR and \fIclc_flags\fR
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are used to check the validity of the cache entry. The cache is considered
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valid if:
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.ip \(bu 5
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The options mbuf has not changed.
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.ip \(bu 5
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The destination of the packet has not changed.
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.ip \(bu 5
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The route still exists and is up.
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.ip \(bu 5
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The flags have not changed.
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.pp
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If all these conditions are met, then the bulk of the \fIclnp_output()\fR
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processing is avoided. The fields \fIclc_segoff, clc_firsthop,\fR
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and \fIclc_ifp\fR are used by \fIclnp_output()\fR to transmit the packet.
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The field \fIclc_ifp\fR contains the actual cached header which is copied
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and then enqueued on the outgoing interface.
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.sh 2 "NPDU Input"
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.pp
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.\" FIGURE
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.so figs/clnp_input.nr
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All CLNP NPDUs are processed by \fIclnp_input()\fR.
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.CF
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outlines
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the flow of control within \fIclnlintr()\fR and \fIclnp_input()\fR.
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The solid lines
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indicate normal flow of control. The dashed lines indicate
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possible error returns.
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.pp
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\fIClnlintr()\fR is invoked by a software interrupt.
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This interrupt is posted by a device driver whenever a
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packet is placed in CLNL's input queue
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\fIclnlintrq()\fR, and the queue is empty.
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It is the responsibility of \fIclnlintr()\fR, when invoked,
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to process all packets present on the input queue.
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Thus, to begin the task of processing a packet, \fIclnlintr()\fR
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removes the next packet from the queue.
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When an error is discovered during processing, the packet is discarded and
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\fIclnlintr()\fR begins afresh.
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.pp
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Once removed, the type of the NPDU is checked. If the NPDU is an
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ES-IS packet, then \fIesis_input()\fR is called. If the NPDU is a CLNP
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packet, then \fIclnp_input()\fR is called. Other packets are silently
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discarded.
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The function \fIclnp_hdr_ck()\fR checks the NPDU for consistency.
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Before checking consistency, \fIclnp_hdr_ck()\fR insures
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that the entire NPDU header is located
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contigiously in a single \fImbuf\fR (\fIm_pullup()\fR\** performs this task).
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.(f
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\** If the NPDU header is larger than \fIMLEN\fR (currently 256), then
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\fIm_pullup()\fR will allocate a cluster \fImbuf\fR.
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.)f
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After "pulling" the header into a single \fImbuf\fR, \fIclnp_hdr_ck()\fR
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checks for the proper CLNP version and protocol identification.
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It also checks that the lifetime field is greater than zero.
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After checking header consistency, the NPDU checksum is computed.\**
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.(f
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\** If the checksum value is zero, the checksum is not computed.
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The value zero is reserved to mean \*(lqdo not use checksum\*(rq.
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.)f
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If the checksum is valid, \fIclnp_data_ck()\fR is called to insure
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that the amount of data in the \fImbuf\fR chain corresponds to the
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amount indicated in the NPDU header.
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.pp
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Once the consistency of the NPDU has been assured, the various parts of the
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packet are extracted.
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Care is taken with each extraction to insure that an attempt is not made
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to address data that does not really exist. (Such an attempt could
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result in a kernel trap).
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.pp
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Next, the options part of the NPDU, if present, is checked for validity.
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If unsupported options are found, the packet is discarded.
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See the section \*(lqNPDU options\*(rq for details of options processing.
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.pp
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Finally, after the preceding checks and extractions have been made, the
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destination address is examined.
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If the address indicates that the packet's destination is not this
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system, the packet is forwarded by calling \fIclnp_forward()\fR.
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See the section \*(lqDT NPDU Forwarding\*(rl for details of packet forwarding.
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If this end system is the
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packet's destination, processing continues.
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.pp
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If the packet is not complete, it is passed to \fIclnp_reass()\fR for
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reassembly.
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See the section \*(lqDT NPDU Reassembly\*(rq
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for details of packet reassembly.
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.pp
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At this point, a complete NPDU is in hand.
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If the NPDU is a DT NPDU, it is given to the transport layer
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by calling the TP input routine.
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Otherwise, it is give to the ER NPDU processing function,
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\fIclnp_er_input()\fR.
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.sh 3 "DT NPDU Forwarding"
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.pp
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Packet forwarding is accomplished by \fIclnp_forward()\fR.
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This is performed regardless of the system's type (end or intermediate).
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The task of
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forwarding a packet is fairly straight-forward. First, the lifetime
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field of the datagram is decremented.
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If this operation changes the value to zero, the packet is discarded.
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.pp
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If the source route option is present, and the address at the top of the list
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matches an address of one of the system's network interfaces, then
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the next-source-route-to-be-used offset is adjusted in the option.
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Next, the packet is routed by \fIclnp_route()\fR
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or \fIclnp_srcroute()\fR.
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If the record route option is present, the address of the outgoing
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network interface is recorded by \fIclnp_dooptions()\fR.
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.pp
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Finally the packet is dispatched.
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If the size of the entire packet is less than the MTU of the output
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network interface, the packet is enqueued for that interface,
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otherwise \fIclnp_fragment()\fR is invoked to
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fragment the packet and enqueue the derived NPDUs.
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.sh 2 "NPDU Options"
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.pp
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The options section of an NPDU consists of a series of triplets:
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\fIoption identification\fR, \fIoption length\fR,
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and \fIoption value\fR.
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These triplets are checked each time the options are examined or changed.
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To avoid repeated parsing of the options, the ARGO CLNP
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maintains an index.
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This index is organized as a \fIclnp_optidx\fR structure.
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This structure is shown below.
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.(b
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\fC
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.TS
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tab(+);
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l s s.
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struct clnp_optidx {
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.T&
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l l l l.
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+u_short+cni_securep;+/* ptr to security option */
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+char+cni_secure_len;+/* length of security option */
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+u_short+cni_srcrt_s;+/* offset of src rt option */
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+u_short+cni_srcrt_len;+/* length of src rt option */
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+u_short+cni_recrtp;+/* ptr to head of recrt option */
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+char+cni_recrt_len;+/* length of recrt option */
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+char+cni_priorp;+/* ptr to priority option */
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+u_short+cni_qos_formatp;+/* ptr to format of qos option */
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+char+cni_qos_len;+/* length of qos option */
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+char+cni_er_reason;+/* reason from ER pdu option */
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};
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.TE
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.)b
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This index allows CLNP quickly to discover the existence
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and value of an option.
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For example, if a security option is present, the \fIcni_securep\fR
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field of the option index is non-zero and the value of
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\fIcni_securep\fR is an offset to the beginning of the
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security option.
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The function \fIclnp_opt_sanity()\fR
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parses the options and computes the index.
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While parsing, it also verifies that the
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options are valid and correctly structured.
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If an error occurs while parsing an option,
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\fIclnp_opt_sanity()\fR returns an error code.
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The following sections describe how options are processed
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during the send, forward and receive operations.
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.sh 3 "Sending Options"
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.pp
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Options to be sent with a datagram are passed to \fIclnp_output()\fR as
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two arguments. An option index is passed along with an \fImbuf\fR
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containing the options.
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The options in the \fImbuf\fR must be formatted
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exactly as specified by CLNP.
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If the security, quality of service, or
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priority options are specified, \fIclnp_output()\fR will not transmit the
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datagram and \fIEINVAL\fR is returned.
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The system call \fIsetsockopt()\fR is used to set the CLNP options
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to be sent on a datagram.
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See \fIclnp(4)\fR for more information about setting CLNP options.
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.pp
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If a source route is specified,
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the normal CLNP routing function \fIclnp_route()\fR is not used, and
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\fIclnp_srcroute()\fR is invoked.
|
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.pp
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When the DECBIT config option is specified, \fIclnp_output\fR will
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automatically add the globally unique quality of service option to the packet.
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The sequencing preferred and low delay bits in this option are set.
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.sh 3 "Forwarding Options"
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.pp
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During packet forwarding, the padding, security,
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and priority options are ignored. If record route is selected, the
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function \fIclnp_dooptions()\fR logs the current network
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interface address in the record route list.
|
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.pp
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If a source route is specified,
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the normal CLNP routing function \fIclnp_route()\fR is not used, and
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\fIclnp_srcroute()\fR is invoked.
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.sh 4 "The Congestion Experienced Bit"
|
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.pp
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If a packet is forwarded containing the globally unique quality of
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service option, and the interface through which the packet will be
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transmitted has a queue length greater than \fIcongest_threshold\fR,
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then the congestion experienced bit is set in the quality of service option.
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.pp
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The threshold value stored in \fIcongest_threshold\fR may be changed
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with the \fIclnlutil\fR utility.
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.sh 3 "Receiving Options"
|
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.pp
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On receipt, all CLNP options are ignored except the security
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and globally unique quality of service option.
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If the security option is found, the packet is discarded.
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If the globally unique quality of service option is present, and the
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congestion experienced bit is set, then the transport congestion
|
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control function \fItpclnp_ctlinput(PRC_QUENCH2, addr)\fR is called.
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The following table summarizes the CLNP option processing.
|
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.(b
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.TS
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allbox, tab(+);
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l l l l.
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Option+Send+Forward+Receive
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=
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Padding+may be set+-+-
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Security+reject+ignore+discard
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Source Route+\fIclnp_srcroute()\fR+\fIclnp_srcroute()\fR+-
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Record Route+-+\fIclnp_dooptions()\fR+-
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QOS+added+congestion bit set+tpclnp_ctlinput()
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Priority+reject+ignore+-
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.TE
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.)b
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.sh 2 "DT NPDU Segmentation"
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.pp
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Segmentation is the process by which initial NPDUs are segmented into
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smaller derived NPDUs when the initial NPDU is too large for transmission
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on a network interface.
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Segmentation is accomplished by \fIclnp_fragment()\fR.
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This function chops the NPDU into pieces and individually places the pieces
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in the appropriate network interface's output queue.
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Each piece is made as large as possible.
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Note: The phrase "fragmentation" is used synonymously with "segmentation"
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throughout this prose and the CLNP fragmentation code. This is due to
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this author's familiarity with the DoD Internet Protocol which uses
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the term "fragment."
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.sh 2 "DT NPDU Reassembly"
|
|
.pp
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Derived NPDUs are put back together by the process called
|
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reassembly.
|
|
Reassembly is performed only at the destination end system.
|
|
When a derived NPDU arrives, it is passed to \fIclnp_reass()\fR.
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This function scans a linked list of NPDUs awaiting reassembly.
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Each packet in the list is represented by a fragment list
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|
descriptor, which is stored in an \fImbuf\fR:
|
|
.(b
|
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\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
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struct clnp_fragl {
|
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.T&
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|
l l l l.
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+struct iso_addr+cfl_src;+/* source */
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+struct iso_addr+cfl_dst;+/* destination */
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|
+u_short+cfl_id;+/* id of the pkt */
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+u_char+cfl_ttl;+/* time to live */
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+u_short+cfl_last;+/* offset of last
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+++byte of packet */
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+struct mbuf +*cfl_orighdr;+/* ptr to
|
|
+++original header */
|
|
+struct clnp_frag+*cfl_frags;+/* linked list
|
|
+++of fragments */
|
|
+struct clnp_fragl+*cfl_next;+/* next pkt be-
|
|
+++ing reassembled */
|
|
};
|
|
.TE
|
|
\fR
|
|
.)b
|
|
The fields \fIcfl_src\fR, \fIcfl_dst\fR, and \fIcfl_id\fR are used to
|
|
match an incoming derived NPDU with a fragment list.
|
|
\fICfl_orighdr\fR contains a copy of the NPDU header of the first fragment received.
|
|
The linked list of fragments pertaining to the packet is stored in the
|
|
\fIcfl_frags\fR field.
|
|
Each NPDU fragment represented by a \fIclnp_frag\fR structure,
|
|
stored in an \fImbuf\fR:
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
struct clnp_frag {
|
|
.T&
|
|
l l l l.
|
|
+u_int+cfr_first;+/* offset of
|
|
+++first byte of this frag */
|
|
+u_int+cfr_last;+/* offset of last
|
|
+++byte of this frag */
|
|
+u_int+cfr_bytes;+/* bytes to shave */
|
|
+struct mbuf+*cfr_data;+/* ptr to data */
|
|
+struct clnp_frag+*cfr_next;+/* next frag */
|
|
};
|
|
.TE
|
|
\fR
|
|
.)b
|
|
The fields \fIcfr_first\fR and \fIcfr_last\fR indicate the first and
|
|
last octet of the fragment.
|
|
\fICfr_data\fR points to an mbuf chain
|
|
which contains the data for the fragment.
|
|
.pp
|
|
If \fIclnp_reass()\fR finds a \fIclnp_fragl\fR structure matching the
|
|
incoming derived NPDU, \fIclnp_insert_frag()\fR is called to create
|
|
a \fIclnp_frag\fR structure and insert it in the linked list of
|
|
packet fragments.
|
|
If no \fIclnp_fragl\fR structure is found,
|
|
\fIclnp_newpkt()\fR is invoked to create a new fragment list structure.
|
|
.pp
|
|
The last task \fIclnp_reass()\fR performs is to check if the fragment
|
|
that just arrived completes the reassembly of the initial NPDU.
|
|
If it does, the reassembled NPDU is rearranged to
|
|
look like it just arrived intact.
|
|
It accomplishes this by linking the \fImbuf\fRs holding
|
|
the fragments into one \fImbuf\fR chain that represents the initial
|
|
NPDU.
|
|
A pointer to this \fImbuf\fR chain is returned by \fIclnp_reass()\fR.
|
|
.pp
|
|
If the newly arrived fragment does not complete an initial NPDU,
|
|
\fIclnp_reass()\fR returns NULL.
|
|
.sh 3 "Reassembly Lifetime Control"
|
|
.pp
|
|
One function of the CLNP is to prevent
|
|
a proliferation of fragments awaiting reassembly from
|
|
consuming buffers in an end system for indefinite periods of time.
|
|
This function is called reassembly lifetime control.
|
|
It is accomplished by
|
|
periodic traversal of
|
|
the list of \fIclnp_fragl\fR structures, decrementing the
|
|
\fIcfl_ttl\fR field.
|
|
This field is a copy of the NPDU time-to-live
|
|
field. If \fIcfl_ttl\fR reaches zero, all resources associated with the
|
|
fragment are released.
|
|
The procedure
|
|
\fIclnp_slowtimo()\fR, which is called by the system
|
|
clock every 500 milliseconds (every half-second),
|
|
performs the CLNP reassembly lifetime control.
|
|
.sh 2 "ER NPDU"
|
|
.pp
|
|
An ER NPDU is sent to the originator of a packet when a DT NPDU is
|
|
discarded and the error report function is not suppressed. Suppression
|
|
of the error report function is accomplished by setting the "no ER"
|
|
bit in the CLNP header.
|
|
A packet is discarded by \fIclnp_discard()\fR.
|
|
Before it
|
|
returns the \fImbufs\fR used to store the
|
|
the discarded packet to the \fImbuf\fR free list,
|
|
\fIclnp_discard()\fR
|
|
determines if the error report function is suppressed.
|
|
If not,
|
|
an ER NPDU will be sent to the originator of the discarded packet by
|
|
calling \fIclnp_emit_er()\fR.
|
|
.pp
|
|
\fIClnp_emit_er()\fR will create an ER NPDU, address it to the
|
|
originator of the discarded packet, route the NPDU,
|
|
and transmit it, sending the header of the discarded NPDU as data.
|
|
ER NPDUs may not be segmented.
|
|
If the ER NPDU is too large for the outgoing network interface,
|
|
the packet is truncated.
|
|
.sh 2 "Raw CLNP"
|
|
.pp
|
|
In order to test CLNP in isolation from higher layer
|
|
protocols, ARGO provides a \*(lqraw\*(rq interface to CLNP.
|
|
This raw interface is selected with the \fISOCK_RAW\fR parameter to
|
|
the
|
|
\fIsocket()\fR
|
|
system call.
|
|
When a \*(rqraw\*(rq socket is open,
|
|
and CLNP receives an NPDU,
|
|
CLNP must determine whether the incoming NPDU is destined for
|
|
the
|
|
\*(rqraw\*(rq interface or for the interface to the
|
|
OSI transport protocol entity.
|
|
ARGO addresses this problem by using non-standard NPDU types
|
|
for packets sent on \*(rqraw\*(rq sockets.
|
|
The type field in the CLNP NPDU header
|
|
is set to \fICLNP_RAW\fR (hex 1d) rather than \fICLNP_DT\fR
|
|
in NPDUs that originate from
|
|
\*(rqraw\*(rq sockets.
|
|
This non-standard type value is used by \fIclnp_input()\fR
|
|
to decide which upper layer protocol should receive the packet.
|
|
See \fIclnptest(8)\fR for more information about the.
|
|
\*(rqraw\*(rq CLNP interface.
|
|
.sh 2 "CLNP Echo"
|
|
.pp
|
|
In the DoD world, ICMP supports an \fIecho\fR service.
|
|
This allows one to \*(lqping\*(rq a distant gateway and
|
|
to receive an echo response (a packet in return) if the gateway is working.
|
|
There is no counterpart to \*(lqecho\*(rq in ISO 8473 (CLNP).
|
|
ARGO provides this non-standard feature in its connectionless
|
|
network layer.
|
|
.pp
|
|
Like raw CLNP, implementing an echo function requires a non-standard
|
|
NPDU type value to allow
|
|
\fIclnp_input()\fR to differentiate between a DT NPDU to be forwarded
|
|
or passed to a higher layer protocol, and an NPDU that is to be echoed.
|
|
When requesting an echo,
|
|
the CLNP type field is set to \fICLNP_EC\fR (hex 1E) rather
|
|
than CLNP_DT.
|
|
When \fIclnp_input()\fR receives a packet with type
|
|
\fICLNP_EC\fR,
|
|
it swaps the source and destination addresses, sets the
|
|
type field to \fICLNP_ECR\fR (hex 1F) and forwards
|
|
the packet back to the sender.
|
|
See also \fIclnpping(8)\fR.
|
|
.sh 2 "Timers"
|
|
.pp
|
|
The only timer used by CLNP is the
|
|
500 millisecond timer, which is
|
|
user for reassembly lifetime control.
|
|
See the section \*(lqReassembly Lifetime Control.\*(rq
|
|
.sh 1 "End System to Intermediate System Routing Protocol (ES-IS)"
|
|
.\" ROB
|
|
.sh 2 "Overview"
|
|
.pp
|
|
This section describes the implementation of the ES-IS routing protocol.
|
|
This protocol is used primarily to resolve NSAP address to SNPA address
|
|
translations. It is also used to identify end systems
|
|
and intermediate systems on
|
|
the local subnetwork.
|
|
All of this work is accomplished by transmitting
|
|
packets of the type End System Hello (ESH), Intermediate System Hello (ISH)
|
|
and Request Redirect (RD).
|
|
.pp
|
|
For the purpose of this section, the following definitions of end system (ES)
|
|
and intermediate system (IS) apply.
|
|
.ip \(bu 5
|
|
An \fIend system\fR is an open system that
|
|
is an OSI end system in the standard OSI sense
|
|
(that it supports a full OSI protocol suite in addition to the network layer)
|
|
and that
|
|
implements the functions of the
|
|
the ES-IS protocol that are mandatory for end systems,
|
|
such as the Query Configuration function and the Record Redirect
|
|
function,
|
|
but that does not implement
|
|
the functions of the ES-IS protocol that are for intermediate systems.
|
|
.ip \(bu 5
|
|
An \fIintermediate system\fR is an open system that
|
|
is an OSI intermediate system in the standard OSI sense
|
|
(that it performs packet routing in the network layer)
|
|
and that
|
|
implements the functions of the
|
|
the ES-IS protocol that are mandatory for intermediate systems,
|
|
such as the Request Redirect function,
|
|
but not the functions of the ES-IS protocol that are for end systems.
|
|
.pp
|
|
While system may be an ES or an IS or both according to the
|
|
standard OSI definitions, this is not the case in the context of
|
|
the ES-IS protocol.
|
|
.pp
|
|
An ARGO system is by default an end system, by the definitions given above.
|
|
An ARGO system can be made to function as an intermediate system
|
|
instead of an end system with the \fIclnlutil\fR program.
|
|
See \fIclnlutil(8)\fR for more information.
|
|
.sh 2 "Report Configuration Function"
|
|
.pp
|
|
The report configuration function is used by end systems and intermediate
|
|
systems to inform each other of their reachability and current subnetwork
|
|
addresses.
|
|
This function is invoked whenever the configuration timer
|
|
expires.
|
|
This timer fires at a frequency of once every
|
|
\fIesis_config_time\fR seconds.
|
|
By default, this value is 60 (seconds),
|
|
but it may be changed with the \fIclnlutil\fR program.
|
|
.pp
|
|
The report configuration function is contained in the C function
|
|
\fIesis_config()\fR. Called every \fIesis_config_time\fR seconds,
|
|
\fIesis_config()\fR searches the list of active network interfaces
|
|
calling \fIesis_shoutput\fR for each interface that is up, has
|
|
broadcast ability and has an ISO address configured.
|
|
.pp
|
|
The function \fIesis_shoutput()\fR has the responsibility of building and
|
|
transmitting ESH and ISH packets.
|
|
It takes several arguments, including a pointer to a network interface
|
|
and
|
|
a packet type (ESH or ISH).
|
|
If the packet type is ESH, then
|
|
each NSAP address configured on the specified interface is added to
|
|
the ESH NPDU. ISH NPDUs may only contain a single NSAP address\**.
|
|
.(f
|
|
\** Actually, ISH packets contain Network Entity Titles (NETs). ARGO
|
|
does not make a distinction between NETs and NSAPs.
|
|
.)f
|
|
After the packet is built, it is transmitted on the subnetwork. ESH packets
|
|
are sent to the multicast address \fIall intermediate systems\fR, whereas
|
|
ISH packets are sent to the multicast address \fIall end systems\fR.
|
|
.pp
|
|
Each ISH and ESH NPDU contains
|
|
a holding timer setting. This setting (specified
|
|
in seconds) is used by the receiver of the NPDU to set its
|
|
holding timer. When its holding timer expires, the information from
|
|
the NPDU is erased. The holding timer value sent on each ISH and ESH NPDU
|
|
is contained in the variable \fIesis_holding_time\fR. By default, this
|
|
timer setting is 120 seconds. This value may be changed with the
|
|
\fIclnlutil\fR utility program.
|
|
.sh 2 "Record Configuration Function"
|
|
.pp
|
|
The Record Configuration function receives ESH or ISH NPDUs, extracts the
|
|
configuration information, and updates kernel-resident tables.
|
|
The two functions \fIesis_eshinput()\fR and \fIesis_ishinput()\fR
|
|
process incoming ESH and ISH NPDUs, respectively.
|
|
.pp
|
|
The ES-IS entity maintains a table that
|
|
associates a SNPA-addresses with NSAP-addresses.
|
|
This table is called the \fISNPA cache\fR.
|
|
.pp
|
|
Whenever an ESH or ISH NPDU is received,
|
|
an entry is made in the SNPA cache
|
|
via the \fIsnpac_add()\fR function.
|
|
This entry is kept in the cache until the holding timer expires.
|
|
In addition to adding an entry to the SNPA cache, \fIsnpac_add()\fR creates
|
|
a default ISO route toward the sender of the ISH.
|
|
One such route is kept so that the ES-IS entity has at most one
|
|
route to an IS at any time.
|
|
Note that ISHs from different sources will
|
|
cause the route to the source of the earlier ISH to be
|
|
overwritten.
|
|
The default route
|
|
will be removed when the ISH holding timer expires.
|
|
.pp
|
|
If, at the time an ESH or ISH NPDU is received, the SNPA cache
|
|
contains no entry for the NSAP address in the NPDU just received,
|
|
an ESH or ISH (depending on the system type) NPDU is
|
|
transmitted to the sender of the NPDU just received.
|
|
.sh 2 "Resolving NSAP addresses to SNPA addresses: Query Configuration Function"
|
|
.pp
|
|
Whenever a device driver needs to resolve an NSAP address to
|
|
an SNPA address, it calls \fIiso_snparesolve()\fR. This function first looks
|
|
up the NSAP address in the SNPA cache. If a match is found, the
|
|
corresponding SNPA address is returned. If a match is not found and the
|
|
system is an end system, and there is a known intermediate system, then
|
|
the SNPA address of the intermediate system is returned. It is assumed that
|
|
the intermediate system will forward the packet and transmit a redirect back
|
|
(see "Redirection Generation", below).
|
|
If a match is not found and the system is an end system, but there is no
|
|
known intermediate system, then \fIiso_snparesolve()\fR will return
|
|
the multicast address \fIall end systems\fR.
|
|
In all other cases, \fIiso_snparesolve()\fR will return an error.
|
|
This is known as the query configuration function.
|
|
.sh 3 "Configuration Response Function"
|
|
.pp
|
|
In order for the query configuration function to be effective, the network
|
|
entity that receives a CLNP DT sent to the \fIall end system\fR
|
|
multicast address must transmit an ESH back to the sender of the DT.
|
|
This is called the configuration response function and is accomplished by
|
|
calling \fIsh_output()\fR from within \fIclnp_input()\fR.
|
|
.sh 2 "Redirection Generation"
|
|
.pp
|
|
When an intermediate system forwards a packet onto the same interface
|
|
upon which
|
|
the packet arrived, a redirect (RD) NPDU is generated. This NPDU is
|
|
transmitted by calling \fIesis_rdoutput()\fR from within \fIclnp_forward()\fR.
|
|
Note that end systems may forward packets but they do not generate RD PDUs.
|
|
.sh 2 "Redirection Receipt"
|
|
.pp
|
|
RD NPDUs direct an end system to create an SNPA cache entry
|
|
for an NSAP address, or, if such an entry exists, to change
|
|
the SNPA address associated with the NSAP address.
|
|
The receipt of RD NPDUs is handled by \fIesis_rdinput()\fR.
|
|
This function
|
|
parses the RD NPDU and adds an entry to the SNPA cache for the corresponding
|
|
destination NSAP address.
|
|
If the redirect is toward an intermediate system,
|
|
meaning that the RD NPDU contains an SNPA address
|
|
of an intermediate system (gateway),
|
|
a route is created for the destination NSAP with the intermediate system as
|
|
the first hop, or gateway, in the route.
|
|
.sh 2 "Multicast Addresses"
|
|
.pp
|
|
As specified by the December 1987 NBS agreements, the address
|
|
\fIall end systems\fR is {0x09, 0x00, 0x2B, 0x00, 0x00, x04} and the address
|
|
\fIall intermediate systems\fR is {0x09, 0x00, x02B, 0x00, 0x00, 0x05}.
|
|
These multicast addresses are only used on the 802.3 subnetwork (baseband).
|
|
Broadcast addresses are used on the 802.5 subnetwork (token ring). See
|
|
the comment in \fC/sys/netargo/iso_snpac.c\fR for more information on
|
|
multicast addresses.
|
|
.sh 1 "Connection Oriented Network Service and Subnetwork Service"
|
|
.pp
|
|
The following sections describe the design of the Connection Oriented
|
|
Network Service (CONS) and the Connection Oriented Subnetwork Service
|
|
(COSNS).
|
|
The CONS and COSNS are provided by two functionally separate but related
|
|
modules, a connection manager and the ISO 8208 (X.25) protocols.
|
|
The connection manager is also known in OSI terminology as a
|
|
subnetwork dependent convergence function, or SNDCF.
|
|
In ARGO it is used for more than an SNDCF, and it is a sort of
|
|
"glue" that binds a transport service, a network service, a
|
|
subnetwork service, and a device driver together, so
|
|
hereinafter it is called "the glue".
|
|
This code performs the some of the functions of ISO 8878,
|
|
which specifies how ISO 8208 (X.25) can be used to provide the OSI
|
|
connection oriented network service.
|
|
The X.25 protocols are implemented in a coprocessor
|
|
made by Eicon Technology, Inc.
|
|
The device driver \fBecn\fR is the Unix kernel interface to this
|
|
coprocessor.
|
|
The sections that follow describe the glue and the \fBecn\fR device
|
|
driver.
|
|
.sh 2 "The Glue"
|
|
.pp
|
|
The glue provides
|
|
services to several modules in the kernel:
|
|
.ip "Subnetwork service" 5
|
|
is provided to other network layer protocols, such as CLNP (ISO 8473).
|
|
The ARGO CLNP uses this service.
|
|
The Internet IP could be made to use this service with
|
|
minimal effort, because this service interface is made to look
|
|
like a standard Unix BSD link layer service (it has
|
|
a device driver interface).
|
|
.ip "Network service" 5
|
|
is provided to transport layer protocols, such as TP (ISO 8073).
|
|
This service interface looks like a standard Unix BSD
|
|
network service (a procedure call interface).
|
|
.ip "Transport service" 5
|
|
could be provided to the socket module.
|
|
While this is not provided with the ARGO software, the glue
|
|
is designed to permit
|
|
such a service to be provided with little additional programming effort.
|
|
.pp
|
|
Higher layer protocols
|
|
that use a connection-oriented
|
|
network or subnetwork service need to manage virtual
|
|
circuits in a similar fashion.
|
|
Rather than put connection management functions into each higher
|
|
layer protocol (HLP) entity
|
|
that uses the CONS or COSNS,
|
|
in ARGO the connection management is in one module, the glue.
|
|
Other alternatives exist, for example in the OSI world,
|
|
one may place in the TP entity the function of connection management for TP,
|
|
and implement a network connection management subprotocol
|
|
of the transport layer (ISO 8073 DAD1, NCMS).
|
|
In addition, connection management for CLNP may be implemented as part of
|
|
the CLNP entity.
|
|
A subnetwork dependent convergence protocol (ISO 8878/A) may
|
|
be implemented to support connection management for CLNP.
|
|
The approach taken in ARGO is different from those suggested in ISO
|
|
for two reasons.
|
|
First, ARGO aims to minimize the amount of code written to perform a given
|
|
task.
|
|
Second, ARGO has several coexisting paths through the network layer,
|
|
which the ISO approach does not address.
|
|
For example, in both ISO 8878/A and in NCMS it is assumed that if
|
|
an incoming call arrives from NSAP \(*b
|
|
while a call to NSAP \(*b is being placed,
|
|
the two calls are resolved to one virtual circuit.
|
|
This is not feasible in the ARGO scenario, since it may not be known
|
|
until after
|
|
the calls are established and higher level packets are exchanged
|
|
whether the two calls are to be used
|
|
for the same path and for the same higher layer protocols.
|
|
A possible alternative approach is to use an NSAP-address for each path
|
|
through the network layer
|
|
(or protocol suite).
|
|
This was rejected in the ARGO design because it puts the burden
|
|
on the calling application entity or network entity to
|
|
determine the proper NSAP-address to use to determine the protocol
|
|
suite to be used to reach the destination end system.
|
|
For this reason, none of the approaches suggested in ISO is adopted
|
|
here.
|
|
.pp
|
|
The glue provided in the ARGO
|
|
kernel does not provide the full OSI network service.
|
|
It provides that subset of the network service that is used
|
|
by ARGO TP and by ARGO CLNP.
|
|
The OSI connection-oriented network service elements that are
|
|
are provided are described in Chapter Four,
|
|
in the section titled "Connection Oriented Network Service".
|
|
.pp
|
|
Each module using the glue has its own service
|
|
interface to the glue.
|
|
.\" When X.25 is used as a
|
|
.\"transport service, the standard protocol switch table is used, and the procedure
|
|
.\"\fIcons_usrreq()\fR is the protosw entry for a
|
|
.\"service in the iso protosw table that provides the
|
|
.\"SOCK_STREAM abstraction in the AF_ISO address family,
|
|
.\"with protocol ISOPROTO_X25.
|
|
.\"This service is called XTS in the glue code and hereafter
|
|
.\"in this document.
|
|
.\".pp
|
|
When the transport layer uses the glue as a network service,
|
|
the interface is the procedure
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
error = cons_output( isop, m, len, isdgm )
|
|
.T&
|
|
l l l.
|
|
+struct isopcb +*isop;
|
|
+struct mbuf +*m;
|
|
+int+error, len, isdgm;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
When the network layer uses the glue as a subnetwork service
|
|
the interface is the device driver-like procedure
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
error = cosns_output( ifp, m, dst )
|
|
.T&
|
|
l l l.
|
|
+struct ifnet +*ifp;
|
|
+struct mbuf +*m;
|
|
+struct sockaddr_iso +*dst;
|
|
+int+error;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
When the glue is used as a connection-oriented service
|
|
(i.e., by TP 0, and by TP 4 during the transport
|
|
connection establishment phase, during which
|
|
it is not yet known whether class 0 or class 4 will be used)
|
|
the following procedures are used:
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
error = cons_openvc( copcb, dstaddr, so )
|
|
.T&
|
|
l l l.
|
|
+struct cons_pcb +*copcb;
|
|
+struct sockaddr_iso +*dstaddr;
|
|
+struct socket+*so;
|
|
.T&
|
|
l s s s.
|
|
+++
|
|
error = cons_netcmd( cmd, isop, vc, isdgm )
|
|
.T&
|
|
l l l.
|
|
+int+cmd;
|
|
+struct isopcb +*isop;
|
|
+int+channel, isdgm;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
The procedure \fIcons_openvc()\fR places a call.
|
|
The procedure \fIcons_netcmd()\fR accepts, rejects, or clears
|
|
a call.
|
|
There is no incoming call indication, because
|
|
the glue uses the passive open model for accepting calls.
|
|
The HLP simply sees a new incoming packet, and is given
|
|
a virtual circuit number (channel) along with the incoming packet.
|
|
If the HLP chooses to reject the call
|
|
it may do so, which will cause the virtual circuit (VC) to be cleared.
|
|
.pp
|
|
The glue may reject (clear) an incoming call for its own reasons.
|
|
The following table lists the reasons that the glue may
|
|
clear a call and the ISO 8208 diagnostic code used on the X.25 clear packet
|
|
in each case.
|
|
For a complete list of the permissible diagnostic codes, see
|
|
Figure 14-B of ISO 8208.
|
|
.in -5
|
|
.(b
|
|
.TS
|
|
center expand box tab(+);
|
|
l l.
|
|
Reason+Diagnosic code
|
|
=
|
|
The VC was opened for use with CLNP +Higher level initiated reset
|
|
or TP 4 and has been idle for the +user resynchronization
|
|
maximum inactivity time. +(0xfa)
|
|
_
|
|
The HLP closed +Higher level initiated disconnection
|
|
this network connection. +- normal (0xf1)
|
|
_
|
|
The HLP rejected +Higher level initiated connection
|
|
this network connection. +rejection - transient condition (0xf4)
|
|
_
|
|
The X.25 call packet contained +Higher level initiated connection
|
|
facilities that are not supported +rejection - incompatible
|
|
by the glue, or did not contain +information in user data (0xf8)
|
|
necessary information, e.g. calling +
|
|
or called DTE address. +
|
|
_
|
|
The X.25 call packet contained +Higher level initiated connection
|
|
call user data that does not +rejection - unrecognizable protocol
|
|
indicate any HLP supported by ARGO +identifier in user data
|
|
HLP supported by ARGO +(0xf9)
|
|
_
|
|
The given destination +OSI Network service problem: NSAP
|
|
NSAP-address is not supported +address unknown (permanent
|
|
+condition) (0xeb)
|
|
_
|
|
The X.25 packet or a facility +Packet not allowed-
|
|
therein was too long +packet too long. (0x27)
|
|
.TE
|
|
.)b
|
|
.in +5
|
|
.pp
|
|
The glue provides several functions common to all
|
|
modules (HLPs) that use the glue.
|
|
Regardless of the HLP,
|
|
the DTE addresses and NSAP addresses are associated in the same
|
|
manner.
|
|
One same network layer protocol identification scheme
|
|
(ISO PDTR 9577) for all HLPs.
|
|
Several different HLPs need to close inactive X.25
|
|
virtual circuits after a timer expires.
|
|
The glue insulates the
|
|
device driver interface to the X.25 coprocessor
|
|
from the HLP.
|
|
.pp
|
|
TP class 0 connections
|
|
.\" and the X.25 "transport service"
|
|
do not share X.25 VCs
|
|
.\" with each other or among transport service-level circuits (sockets),
|
|
so
|
|
.\" these two modules need to keep X.25
|
|
the glue needs to maintain
|
|
a 1-1 correspondence between VCs
|
|
and sockets.
|
|
.\" For use by TP 0 and XTS,
|
|
For use by TP 0,
|
|
one network-level pcb is needed for each socket, and that is a
|
|
\fIcons_pcb\fR, described below.
|
|
.pp
|
|
TP class 4 connections may share VCs,
|
|
and TP 4 makes no correspondence between sockets and VCs.
|
|
CLNP regards VCs similarly to TP 4.
|
|
A given VC may be used simultaneously for many higher level connections,
|
|
but all higher level connections using a given VC must use the same
|
|
path or protocol suite.
|
|
In other words, a TP4 connection running over CONS may not share a
|
|
VC with a TP4 connection running over CLNS/COSNS.
|
|
.pp
|
|
To manage VCs and to maintain the separation of sharable and non-sharable
|
|
VCs, the glue uses the following protocol control block:
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
struct cons_pcb {
|
|
.T&
|
|
l l l.
|
|
+struct isopcb+_co_isopcb;
|
|
+u_short+co_state;
|
|
+u_char+co_flags;
|
|
+u_short+co_ttl;
|
|
+u_short+co_init_ttl;
|
|
+int+co_channel;
|
|
+struct ifnet+*co_ifp;
|
|
+struct protosw+*co_proto;
|
|
+struct dte_addr+co_peer_dte;
|
|
+struct ifqueue+co_pending;
|
|
};
|
|
.T&
|
|
l l s.
|
|
#define co_next+_co_isopcb.isop_next
|
|
#define co_prev+_co_isopcb.isop_prev
|
|
#define co_head+_co_isopcb.isop_head
|
|
#define co_laddr+_co_isopcb.isop_laddr
|
|
#define co_faddr+_co_isopcb.isop_faddr
|
|
#define co_lport+_co_isopcb.isop_laddr.siso_tsuffix
|
|
#define co_fport+_co_isopcb.isop_faddr.siso_tsuffix
|
|
#define co_route+_co_isopcb.isop_route
|
|
#define co_socket+_co_isopcb.isop_socket
|
|
}+
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
The \fIcons_pcb\fR contains
|
|
an \fIisopcb\fR so that TP 0
|
|
.\" and XTS
|
|
may use the routines that manipulate \fIisopcb\fR structures for allocating
|
|
and
|
|
deallocating PCBs, binding addresses to PCBs,
|
|
and finding routes.
|
|
.pp
|
|
A CONS PCB has states CLOSED, LISTENING, CLOSING,
|
|
CONNECTING, ACKWAIT, and OPEN.
|
|
This represents the state of the VC to the degree necessary to the glue.
|
|
The glue uses the passive open model for opening VCs.
|
|
The coprocessor device driver always accepts
|
|
incoming calls and passes an indication to the glue when
|
|
a call is accepted by the coprocessor.
|
|
If the user of the glue (the HLP) or the glue itself decides
|
|
that the VC is not desired, the VC is cleared.
|
|
.pp
|
|
The \fIcons_pcb\fR contains a bit mask, \fIco_flags\fR, with values:
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l l l l.
|
|
#define+CONSF_OCRE+0x40+/* created on OUTPUT */
|
|
#define+CONSF_ICRE+0x20+/* created on INPUT */
|
|
#define+CONSF_DGM+0x04+/* for datagram use only */
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
The flag
|
|
CONSF_DGM means that the VC is being used to provide a
|
|
datagram (connectionless, unreliable, unsequenced)
|
|
service to the higher layer, and that requests for additional VCs
|
|
from the same higher layer entity
|
|
may be served by this VC, effectively
|
|
multiplexing higher layer connections on this VC.
|
|
When this flag is set in a \fIcons_pcb\fR, there is no associated
|
|
\fIco_socket\fR pointer.
|
|
When CONSF_DGM is not set, there is an associated
|
|
\fIco_socket\fR pointer, and the VC is being used for
|
|
TP 0.
|
|
.pp
|
|
The flag
|
|
CONSF_ICRE means that the VC was created by
|
|
and incoming call indication.
|
|
The flag
|
|
CONSF_OCRE means that the VC was created
|
|
on behalf of an outgoing call request.
|
|
.pp
|
|
The \fIstruct dte_addr\fR field, \fIco_peer_dte\fR,
|
|
contains the peer's DTE address.
|
|
The glue locates VCs by searching the list of protocol control
|
|
blocks for a PCB with a DTE matching that desired.
|
|
.pp
|
|
The glue is given an NSAP-address by the HLP entity.
|
|
The glue finds the desired DTE address by searching the
|
|
ES-IS SNPA cache for an SNPA-address (DTE address) associated
|
|
with the NSAP-address given by the HLP entity.
|
|
This means that to use the CONS, an entry for each desired
|
|
peer must appear in the SNPA cache.
|
|
ARGO does not provide the ES-IS protocol for use with ISO 8208, so
|
|
"permanent" or static entries must be placed in this cache by hand,
|
|
using the utility program \fIclnlutil\fR.
|
|
.pp
|
|
When an incoming call is accepted, the peer's DTE address is
|
|
placed in the SNPA cache along with
|
|
an NSAP address generated as follows:
|
|
.np
|
|
If the incoming call contained the peer's NSAP-address
|
|
in an Address Extension Facility (AEF, available with 1984 X.25),
|
|
this NSAP-address is used, otherwise
|
|
.np
|
|
the glue creates a "type-37" address (the format defined by AFI 37
|
|
in ISO 8348/AD 2).
|
|
.pp
|
|
TP 4 can have its outgoing packets sent on more than one VC.
|
|
The glue presently contains no mechanism for fanning outgoing
|
|
packets onto several VCs, however,
|
|
it does not prohibit packets arriving for TP 4 on any VC that
|
|
opened with the protocol identifier for TP.
|
|
.pp
|
|
The glue has the ability to generate AEFs on outgoing calls, but
|
|
this ability is turned off,
|
|
since the public data network on which ARGO runs at Wisconsin
|
|
does not support 1984 X.25, and so it rejects packets containing
|
|
AEFs.
|
|
The use of AEFs can be reinstated by making a kernel with the
|
|
option \fBX25_1984\fR or by adding the line
|
|
.nf
|
|
.in +5
|
|
\fC
|
|
#define X25_1984
|
|
\fR
|
|
.in -5
|
|
.fi
|
|
at the top of the file
|
|
\fC/sys/netargo/if_cons.c\fR
|
|
and rebuilding the kernel.
|