InfoMagic Standards 1994 January

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Text File | 1991-12-22 | 153KB | 6,129 lines

.rs .\" Troff code generated by TPS Convert from ITU Original Files .\" Not Copyright (~c) 1991 .\" .\" Assumes tbl, eqn, MS macros, and lots of luck. .TA 1c 2c 3c 4c 5c 6c 7c 8c .ds CH .ds CF .EQ delim @@ .EN .nr LL 40.5P .nr ll 40.5P .nr HM 3P .nr FM 6P .nr PO 4P .nr PD 9p .po 4P .rs \v'|.5i' .LP \fBMONTAGE:\ FIN DU \(sc 6.28 EN\(hyT\*\|ETE DE CETTE PAGE\fR .sp 2P .LP \v'43P' \fB7\fR \fBFormats for facility fields and registration fields\fR .sp 1P .RT .LP .EF '% Fascicle\ VIII.2\ \(em\ Rec.\ X.25'' .OF '''Fascicle\ VIII.2\ \(em\ Rec.\ X.25 %' .sp 1P .LP 7.1 \fIGeneral\fR .sp 9p .RT .PP The facility field is present only when a DTE is using an optional user facility requiring some indication in the \fIcall request\fR , \fIincoming call\fR , \fIcall accepted\fR , \fIcall connected\fR , \fIclear request\fR , \fIclear indication\fR or \fIDCE clear confirmation\fR packet. .bp .PP The registration field is present in a \fIregistration request\fR packet only when the DTE wishes to request the DCE to agree or to stop a previous agreement for an optional user facility and is present in a \fIregistration\fR \fIconfirmation\fR packet when the DCE whishes to indicate which optional user facilities are available or which optional user facilities are currently in effect. .PP The facility/registration field contains one or more facility/registration elements. The first octet of each facility/registration element contains a facility/registration code to indicate the facility or facilities requested/negociated. .PP The facility/registration codes are divided into four classes, by making use of bits\ 8 and\ 7 of the facility/registration code field, in order to specify facility/registration parameters consisting of\ 1, 2, 3\ or a variable number of octets. The general class coding of the facility/registration code field is shown in Table\ 28/X.25. .RT .LP .sp 1 .ce \fBH.T. [T45.25]\fR .ce TABLE\ 28/X.25 .ce \fBGeneral class coding for facility/registration code\fR .ce \fBfields\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | lw(120p) . Bits 8 7 6 5 4 3 2 1 _ .T& lw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | lw(120p) . Class A 0 0 X X X X X X T{ for single octet parameter field T} .T& lw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | lw(120p) . Class B 0 1 X X X X X X T{ for double octet parameter field T} .T& lw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | lw(120p) . Class C 1 0 X X X X X X T{ for triple octet parameter field T} .T& lw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | lw(120p) . Class D 1 1 X X X X X X T{ for variable length parameter field T} _ .TE .nr PS 9 .RT .ad r \fBTable 28/X.25 [T45.25], p.\fR .sp 1P .RT .ad b .RT .PP .sp 1 For class D the octet following the facility/registration code indicates the length, in octets, of the facility/registration parameter field. The facility/registration parameter field length is binary coded and bit\ 1 is the low order bit of this indicator. .PP The formats for the four classes are shown in Figure 23/X.25. .RT .PP The facility/registration code field is binary coded and, without extension, provides for a maximum of 64\ facility/registration codes for classes\ A, B and\ C and 63\ facility/registration codes for class\ D giving a total of 255\ facility/registration codes. .PP Facility/registration code 11111111 is reserved for extension of the facility/registration code. The octet following this octet indicates an extended facility/registration code having the format\ A, B, C and\ D as defined above. Repetition of facility/registration code\ 11111111 is permitted and additional extensions thus result. .PP The coding of the facility/registration parameter field is dependent on the facility being requested/negociated. .PP A facility/registration code may be assigned to identify a number of specific facilities, each having a bit in the parameter field indicating facility requested/facility not requested. In this situation, the parameter field is binary encoded with each bit position relating to a specific facility. A\ 0 indicates that the facility related to the particular bit is not requested and a\ 1 indicates that the facility related to the particular bit is requested. Parameter bit positions not assigned to a spectific facility are set to zero. If none of the facilities represented by the facility/registration code are requested for a virtual call or for on\(hyline facility registration, the facility/registration code and its associated parameter field need not be present. .PP In addition to the facility/registration codes defined in \(sc\ 7, other codes may be used for: .RT .LP \(em non\(hyX.25 facilities which may be provided by some network(s) (\fIcall set\(hyup\fR and \fIregistration\fR packets); .LP \(em CCITT\(hyspecified DTE facilities as described in Annex\ G of this Recommendation (\fIcall set\(hyup\fR , \fIclear request\fR and \fIclear indication\fR packets). .bp .LP .rs .sp 36P .ad r \fBFigure 23/X.25 [T46.25], p. 2 (A traiter comme tableau MEP)\fR .sp 1P .RT .ad b .RT .PP Facility/registration markers, consisting of a single octet pair, are used to separate requests for X.25 facilities as defined in \(sc\(sc\ 6 and\ 7 from other categories as defined above, and, when several categories of facilities are simultaneously present, to separate these categories from each other. .PP The first octet of the marker is a facility/registration code field and is set to zero. The second octet is a facility/registration parameter field. .PP The facility/registration parameter field of a marker is set to zero when the marker precedes requests for: .RT .LP \(em registration codes specific to the local network (\fIregistration\fR packets); .LP \(em non\(hyX.25 facilities provided by the network in case of intranetwork calls (\fIcall set\(hyup\fR packets); .LP \(em non\(hyX.25 facilities provided by the network to which the calling DTE is connected, in case of internetwork calls (\fIcall set\(hyup\fR packets). .bp .PP The facility parameter field of a marker is set to all ones when the marker precedes requests for non\(hyX.25 facilities provided by the network to which the called DTE is connected, in case of internetwork calls (\fIcall set\(hyup\fR packets). .PP The facility parameter field of a marker is set to 00001111 when the marker precedes requests for CCITT\(hyspecfied DTE facilities. .PP All networks will support the facility markers with a facility parameter field set to all ones or to 00001111. .PP DTEs should not use a facility marker with a facility parameter field set to all ones in case of intranetwork calls. However, if a DTE uses such a marker in an intranetwork call, the DCE is not obliged to clear the call, and the marker, with the corresponding facility requests, may be transmitted to the remote DTE. .PP Facility/registration codes for X.25 facilities and for the other categories of facilities may be simultaneously present. However, requests for X.25 facilities must precede the other requests, and requests for CCITT\(hyspecified DTE facilities must follow the other requests. .PP The coding of CCITT\(hyspecified DTE facilities should comply with the description in Annex\ G. However, the DCE is not required to verify that compliance. If the network verifies that compliance and finds an error, it may clear the call with the cause \*QInvalid facility request\*U. The CCITT\(hyspecified DTE facilities are passed unchanged by public data networks between the two packet\(hymode DTEs. .RT .sp 1P .LP 7.2 \fICoding of facility field in call set\(hyup and clearing packets\fR .sp 9p .RT .PP The coding of the facility code field and the format of the facility parameter field are the same in the various \fIcall set\(hyup\fR and \fIclearing\fR packets in which they are used. .RT .sp 1P .LP 7.2.1 \fICoding of the facility code fields\fR .sp 9p .RT .PP Table 29/X.25 gives the coding of the facility code fields and the packet types in which they may be present. .RT .sp 2P .LP 7.2.2 \fICoding of the facility parameter fields\fR .sp 1P .RT .sp 1P .LP 7.2.2.1 \fIFlow control parameter negotiation facility\fR \v'3p' .sp 9p .RT .LP 7.2.2.1.1 \fIPacket size\fR .PP The packet size for the direction of transmission from the called DTE is indicated in bits\ 4, 3, 2 and\ 1 of the first octet of the facility parameter field. The packet size for the direction of transmission from the calling DTE is indicated in bits\ 4, 3, 2 and\ 1 of the second octet. Bits\ 8, 7, 6 and\ 5 of each octet must be zero. .PP The four bits indicating each packet size are binary coded and express the logarithm base\ 2 of the number of octets of the maximum packet size. .PP Networks may offer values from 4 to 12, corresponding to packet sizes of\ 16, 32, 64, 126, 256, 512, 1024, 2048 or\ 4096, or a contiguous subset of these values. All Administrations will provide a packet size of\ 128. .RT .sp 1P .LP 7.2.2.1.2 \fIWindow size\fR .sp 9p .RT .PP The window size for the direction of transmission from the called DTE is indicated in bits\ 7 to\ 1 of the first octet of the facility parameter field. The window size for the direction of transmission from the calling DTE is indicated in bits\ 7 to\ 1 of the second octet. Bit\ 8 of each octet must be zero. .PP The bits indicating each window size are binary coded and express the size of the window. A value of zero is not allowed. .bp .RT .ce \fBH.T. [1T47.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(342p) . TABLE\ 29/X.25 .T& cw(342p) . T{ \fBCoding of the facility code field\fR T} .T& cw(60p) | cw(30p) sw(30p) sw(30p) sw(30p) sw(30p) sw(30p) sw(30p) | cw(72p) , ^ | c | c | c | c | c | c | c | ^ . Facility T{ Packet types in which it may be used T} T{ Facility code bits 8\ \ 7\ \ 6\ \ 5\ \ 4\ \ 3\ \ 2\ \ 1 T} Call request Incoming call Call accepted Call connected Clear request Clear indication DCE clear confirmation _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(72p) . T{ Flow control parameter negotiation: T} X X X X .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em\ packet size T{ 0\ \ 1\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0 T} .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em\ window size T{ 0\ \ 1\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 1 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . Throughput class negotiation X X X X T{ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . Closed user group selection: X X .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em\ basic format T{ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 1 T} .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em\ extended format T{ 0\ \ 1\ \ 0\ \ 0\ \ 0\ \ 1\ \ 1\ \ 1 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . T{ Closed user group with outgoing access selection: T} X X .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em\ basic format T{ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0\ \ 1 T} .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em\ extented format T{ 0\ \ 1\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0\ \ 0 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . T{ Bilateral closed user group selection T} X X T{ 0\ \ 1\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1 T} _ .T& lw(60p) | cw(30p) | cw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | lw(72p) , l | l | l | l | l | l | l | l | ^ . Reverse charging X X Fast select X X T{ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1 (see Note 1) T} _ .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . NUI selection X X (see Note 2) T{ 1\ \ 1\ \ 0\ \ 0\ \ 0\ \ 1\ \ 1\ \ 0 T} _ .TE .nr PS 9 .RT .ad r \fBTableau 29/X.25 [1T47.25]\ \ \ A L'ITALIENNE, p. 3\fR .sp 1P .RT .ad b .RT .LP \fR .bp .ce \fBH.T. [2T47.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(342p) . T{ TABLE\ 29/X.25\ \fI(cont.)\fR T} .T& cw(60p) | cw(30p) sw(30p) sw(30p) sw(30p) sw(30p) sw(30p) sw(30p) | cw(72p) , ^ | c | c | c | c | c | c | c | ^ . Facility T{ Packet types in which it may be used T} T{ Facility code bits 8\ \ 7\ \ 6\ \ 5\ \ 4\ \ 3\ \ 2\ \ 1 T} Call request Incoming call Call accepted Call connected Clear request Clear indication DCE clear confirmation _ .T& lw(60p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(72p) . Charging information: .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | cw(72p) . \(em requesting service X X T{ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0 T} .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . \(em receiving information: X X .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . i) monetary unit T{ 1\ \ 1\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0\ \ 1 T} .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . ii) segment count T{ 1\ \ 1\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0 T} .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . iii) call duration T{ 1\ \ 1\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1 T} _ .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . RPOA selection: X .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . \(em\ basic format T{ 0\ \ 1\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0 T} .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(72p) . \(em\ extended format T{ 1\ \ 1\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0 T} _ .T& lw(60p) | cw(30p) | lw(30p) | cw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(72p) . Call deflection selection X (see Note 4) T{ 1\ \ 1\ \ 0\ \ 1\ \ 0\ \ 0\ \ 0\ \ 1 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | lw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(72p) . T{ Call redirection or deflection notification T} X T{ 1\ \ 1\ \ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 1 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(72p) . T{ Called line address modified notification T} X (see Note 3) X X (see Notes\ 3 and\ 4) X T{ 0\ \ 0\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0\ \ 0 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(72p) . T{ Transit delay selection and indication T} X X X T{ 0\ \ 1\ \ 0\ \ 0\ \ 1\ \ 0\ \ 0\ \ 1 \fR T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(72p) . Marker (see \(sc 7.1) X X X X X X T{ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0\ \ 0 T} _ .T& lw(60p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(72p) . Reserved for extension T{ 1\ \ 1\ \ 1\ \ 1\ \ 1\ \ 1\ \ 1\ \ 1 \fINote\ 1\fR \ \(em\ This facility code and associated facility parameter will be present in the \fIincoming call\fR \| packet if either or both of \fIreverse charging\fR (if \fIreverse charging acceptance\fR is subscribed to) or \fIfast select\fR (if \fIfast select acceptance\fR is subscribed to) is indicated. They may, but need not, be present if neither \fIreverse charging acceptance\fR nor \fIfast select\fR \fIacceptance\fR are subscribed to. .parag \fINote\ 2\fR \ \(em\ This facility code and associated facility parameter may be present in \fIcall accepted\fR \| packet only in conjunction with the \fINUI subscription\fR facility (see \(sc\ 6.21.3). .parag \fINote\ 3\fR \ \(em\ Only when the reason \*QCalled DTE originated\*U is used in the parameter field (see \(sc\(sc\ 6.26 and 7.2.2.12). .parag \fINote\ 4\fR \ \(em\ The DTE is not allowed to use both \fIcall deflection selection\fR \| and \fIcalled line address modified notification\fR facilities in the same \fIclear request\fR packet. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau 29/X.25 [2T47.25]\ \ \ A L'ITALIENNE, p. 4\fR .sp 1P .RT .ad b .RT .LP .bp .PP Window sizes of 8 to 127 are only valid if extended sequence numbering is used (see \(sc\ 6.2). The ranges of contiguous values allowed by a network for calls with normal numbering and extended numbering are network dependent. All Administrations will provide a window size of\ 2. .RT .sp 1P .LP 7.2.2.2 \fIThroughput class negotiation facility\fR .sp 9p .RT .PP The throughput class for the direction of data transmission from the called DTE is indicated in bits\ 8, 7, 6 and\ 5. The throughput class for the direction of data transmission from the calling DTE is indicated in bits\ 4, 3, 2 and\ 1. .PP The four bits indicating each throughput class are binary coded and correspond to throughput classes as indicated in Table\ 30/X.25. .RT .ce \fBH.T. [T48.25]\fR .ce TABLE\ 30/X.25 .ce \fBCoding of throughput classes\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(84p) . Bits: or Bits: 4 \| \| 8 3 \| \| 7 2 \| \| 6 1 \| \| 5 Throughput class (bit/s) _ .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 0 0 0 Reserved .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 0 0 1 Reserved .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 0 1 0 Reserved .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 0 1 1 75 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 1 0 0 150 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 1 0 1 300 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 1 1 0 600 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 0 1 1 1 1\|200 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 0 0 0 2\|400 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 0 0 1 4\|800 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 0 1 0 9\|600 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 0 1 1 19\|200 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 1 0 0 48\|000 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 1 0 1 64\|000 .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 1 1 0 Reserved .T& lw(36p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | rw(84p) . 1 1 1 1 Reserved _ .TE .nr PS 9 .RT .ad r \fBTable 30/X.25 [T48.25], p.\fR .sp 1P .RT .ad b .RT .sp 2P .LP 7.2.2.3 \fIClosed user group selection facility\fR .sp 1P .RT .sp 1P .LP 7.2.2.3.1 \fIBasic format\fR .sp 9p .RT .PP The index to the closed user group selected for the virtual call is in the form of two decimal digits. Each digit is coded in a semi\(hyoctet in binary coded decimal with bit\ 5 being the low order bit of the first digit and bit\ 1 being the low order bit of the second digit. .PP Indexes to the same closed user group at different DTE/DCE interfaces may be different. .RT .sp 1P .LP 7.2.2.3.2 \fIExtended format\fR .sp 9p .RT .PP The index to the closed user group selected for the virtual call is in the form of four decimal digits. Each digit is coded in a semi\(hyoctet in .PP binary coded decimal with bit\ 5 of the first octet being the low order bit of the first digit, bit\ 1 of the first octet being the low order bit of the second digit, bit\ 5 of the second octet being the low order bit of the third digit and bit\ 1 of the second octet being the low order bit of the fourth digit. .PP Indexes to the same closed user group at different DTE/DCE interfaces may be different. .bp .RT .sp 2P .LP 7.2.2.4 \fIClosed user group with outgoing access selection facility\fR .sp 1P .RT .sp 1P .LP 7.2.2.4.1 \fIBasic format\fR .sp 9p .RT .PP The index to the closed user group selected for the virtual call is in the form of two decimal digits. Each digit is coded in a semi\(hyoctet in binary coded decimal with bit\ 5 being the low order bit of the first digit and bit\ 1 being the low order bit of the second digit. .PP Indexes to the same closed user group at different DTE/DCE interfaces may be different. .RT .sp 1P .LP 7.2.2.4.2 \fIExtended format\fR .sp 9p .RT .PP The index to the closed user group selected for the virtual call is in the form of four decimal digits. Each digit is coded in a semi\(hyoctet in binary coded decimal with bit\ 5 of the first octet being the low order bit of the first digit, bit\ 1 of the first octet being the low order bit of the second digit, bit\ 5 of the second octet being the low order bit of the third digit, and bit\ 1 of the second octet being the low order bit of the fourth digit. .PP Indexes to the same closed user group at different DTE/DCE interfaces may be different. .RT .sp 1P .LP 7.2.2.5 \fIBilateral closes user group selection facility\fR .sp 9p .RT .PP The index to the bilateral closed user group selected for the virtual call is in the form of 4\ decimal digits. Each digit is coded in a semi\(hyoctet in binary coded decimal with bit\ 5 of the first octet being the low order bit of the first digit, bit\ 1 of the first octet being the low order bit of the second digit, bit\ 5 of the second octet being the low order bit of the third digit, and bit\ 1 of the second octet being the low order bit of the fourth digit. .PP Indexes to the same bilateral closed user group at different DTE/DCE interfaces may be different. .RT .sp 1P .LP 7.2.2.6 \fIReverse charging and fast select facilities\fR .sp 9p .RT .PP The coding of the facility parameter field is: .RT .LP Bit\ 1\ =\ 0\ for reverse charging not requested .LP Bit\ 1\ =\ 1\ for reverse charging requested .LP Bit\ 8\ =\ 0\ and\ bit\ 7\ =\ 0\ or\ 1 for fast select not requested .LP Bit\ 8\ =\ 1\ and\ bit\ 7\ =\ 0 for fast select requested with no restriction on response .LP Bit\ 8\ =\ 1\ and\ bit\ 7\ =\ 1 for fast select requested with restriction on response .PP \fINote\fR \ \(em\ Bits\ 6, 5, 4, 3 and\ 2 may be assigned to other facilities in the future; presently, they are set to\ 0. .sp 1P .LP 7.2.2.7 \fINUI selection facility\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field. The following octets contain the network user identifier, in a format determined by the network administration. .RT .sp 2P .LP 7.2.2.8 \fICharging information facility\fR .sp 1P .RT .sp 1P .LP 7.2.2.8.1 \fIParameter field for requesting service\fR .sp 9p .RT .PP The coding of the facility parameter field is: .PP Bit\ 1\ =\ 0 for charging information not requested .PP Bit\ 1\ =\ 1 for charging information requested .PP \fINote\fR \ \(em\ Bits\ 8, 7, 6, 5, 4, 3 and\ 2 may be assigned to other facilities in the future; presently, they are set to\ 0. .bp .RT .sp 1P .LP 7.2.2.8.2 \fIParameter field indicating monetary unit\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field. .PP The parameter field indicates the charging. The coding of the parameter is for further study. .RT .sp 1P .LP 7.2.2.8.3 \fIParameter field indicating segment count\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field and has the value \fIn\fR \ \(mu8 where \fIn\fR \ is the number of different tariff periods managed by the network. .PP For each tariff period, the first four octets of the facility parameter field indicate the number of segments sent to the DTE. The following four octets indicate the number of segments received from the DTE. .PP Each digit is coded in a semi\(hyoctet in binary coded decimal and bit\ 1 or bit\ 5 of each semi\(hyoctet is the low order bit of each digit and bits\ 4 to\ 1 of the last octet represent the lowest order digit of the segment count. .PP Segment size and the specific packet types to be counted are a matter of the Administration in the case of national calls and are specified in Recommendation\ D.12 for international calls. .PP \fINote\fR \ \(em\ The relationship between a particular tariff period and its place in the parameter field is a national matter. The order is given by each Administration. .RT .sp 1P .LP 7.2.2.8.4 \fIParameter field indicating call duration\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field and has the value \fIn\fR \ \(mu\ 4 where \fIn\fR \ is the number of different tariff periods managed by the network. .PP For each tariff period, the first octet of the facility parameter field indicates number of days, the second indicates number of hours, the third indicates number of minutes and the fourth indicates number of seconds. Each digit is coded in a semi\(hyoctet in binary coded decimal and bit\ 1 or bit\ 5 of each semi\(hyoctet is the low order bit of each digit. Bits\ 4 to\ 1 of each octet represent the low order digit. .PP \fINote\fR \ \(em\ The relationship between a particular tariff period and its place in the parameter field is a national matter. The order is given by each Administration. .RT .sp 2P .LP 7.2.2.9 \fIRPOA selection facility\fR .sp 1P .RT .sp 1P .LP 7.2.2.9.1 \fIBasic format\fR .sp 9p .RT .PP The parameter field contains the data network identification code for the requested initial RPOA transit network and is in the form of four decimal digits. .PP Each digit is coded in a semi\(hyoctet in binary coded decimal with bit\ 5 of the first octet being the low order bit of the first digit, bit\ 1 of the first octet being the low order bit of the second digit, bit\ 5 of the second octet being the low order bit of the third digit, and bit\ 1 of the second octet being the low order bit of the fourth digit. .RT .sp 1P .LP 7.2.2.9.2 \fIExtended format\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field and has the value \fIn\fR \ \(mu\ 2, where \fIn\fR \ is the number of RPOA transit networks selected. .PP Each RPOA transit network is indicated by a data network identification code, and is in the form of four decimal digits. Each digit is coded in a semi\(hyoctet in binary coded decimal with bit\ 5 of the first octet being the low order bit of the first digit, bit\ 1 of the first octet being the low order bit of the second digit, bit\ 5 of the second octet being the low order bit of the third digit, and bit\ 1 of the second octet being the low order of the fourth digit. .PP RPOA transit network should appear in the facility parameter field in the order that the calling DTE wishes them to be traversed. .bp .RT .sp 1P .LP 7.2.2.10 \fICall deflection selection facility\fR .sp 9p .RT .PP The octet following the facility code indicates the length, in octets, of the facility parameter field and has the value \fIn\fR \ +\ 2, where \fIn\fR \ is the number of octets necessary to hold the called address of the DTE to which the call is to be deflected (the alternative DTE). .PP The first octet of the facility parameter field indicates the reason for the DTE deflecting the call. The coding of this octet is: .RT .LP bits: 8 7 6 5 4 3 2 1 .LP or 1 1 X X X X X X .PP \fINote\fR \ \(em\ Each X may be independently set to 0 of 1 by the called DTE and is passed transparently to the DTE to which the call is deflected. If bits\ 8 and \ 7 are not set to\ 1 by the called DTE, they are forced to this value by the DCE. .PP The second octet indicates the number of semi\(hyoctets in the alternative DTE address. This address length indicator is binary coded and bit\ 1 is the low order bit. Its value is limited to\ 15 when the A\ bit is set to\ 0 (see \(sc\ 5.2.1), to\ 17 when the A\ bit is set to 1. .PP The following octets contains the alternative DTE address, using coding which corresponds to the coding of the called DTE address field in the address block (see \(sc\ 5.2.1). When the number of semi\(hyoctets of the alternative DTE address is odd, a semi\(hyoctet with zeros in bits\ 4, 3, 2 and\ 1 will be inserted after the last semi\(hyoctet in order to maintain octet alignment. .RT .sp 1P .LP 7.2.2.11 \fICall restriction or call deflection notification facility\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field and has the value \fIn\fR \ +\ 2, where \fIn\fR \ is the number of octets necessary to hold the originally called DTE address. .PP The first octet of the facility parameter field indicates the reason for the call redirection of call deflection. The coding of this octet is given in Table\ 31/X.25. .RT .LP .sp 1 .ce \fBH.T. [T49.25]\fR .ce TABLE\ 31/X.25 .ce \fBCoding of the reason in the call redirection or .ce call deflection\fR .ce \fBnotification facility parameter .ce field\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(156p) | cw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) , ^ | c | c | c | c | c | c | c | c. Bits 8 7 6 5 4 3 2 1 _ .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . Originally called DTE busy 0 0 0 0 0 0 0 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Call distribution within a hunt group\|\ua\d\u)\d T} 0 0 0 0 0 1 1 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Originally called DTE out of order T} 0 0 0 0 1 0 0 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . Systematic call redirection 0 0 0 0 1 1 1 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Call deflection by the originally called DTE\|\ub\d\u)\d T} 1 1 X X X X X T{ X \ua\d\u)\d This value may be used by some networks for network\(hydependent reasons not described in this Recommendation. .parag \ub\d\u)\d The Xs are those set by the originally called DTE in the \fIcall deflection selection\fR \| facility (see \(sc\ 7.2.2.10). .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable 31/X.25 [T49.25], p.\fR .sp 1P .RT .ad b .RT .LP .sp 1 .PP The second octet indicates the number of semi\(hyoctets in the originally called DTE address. This address length indicator is binary coded and bit\ 1 is the low order bit. Its value is limited to\ 15 when the A\ bit is set to\ 0 (see \(sc\ 5.2.1), to\ 17 when the A\ bit is set to\ 1. .bp .PP The following octets contain the originally called DTE address. When both the calling DTE and the alternative DTE have subscribed to the \fITOA/NPI address subscription\fR facility (see \(sc\ 6.2.8), or when none of them have subscribed to this facility, the originally called DTE address is coded identically to the called DTE address field in the \fIcall request\fR packet. When these conditions are not satisfied, the network converts from one address format to the other (see \(sc\ 5.2.1). When the number of semi\(hyoctets of the originally added DTE address is odd, a semi\(hyoctet with zeros in bits\ 4, 3, 2 and\ 1 will be inserted after the last semi\(hyoctet in order to maintain octet alignment. .RT .sp 1P .LP 7.2.2.12 \fICalled line address modified notification facility\fR .sp 9p .RT .PP The coding of the facility parameter field for \fIcalled line\fR \fIaddress modified notification\fR is given in Table\ 32/X.25. .RT .ce \fBH.T. [T50.25]\fR .ce TABLE\ 32/X.25 .ce \fBCoding of the parameter field for\fR .ce \fBcalled line address modified notification facility\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(156p) | cw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) sw(6p) sw(12p) , ^ | c | c | c | c | c | c | c | c. Bits 8 7 6 5 4 3 2 1 _ .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(6p) | cw(12p) . T{ Call redirection due to originally called DTE busy T} 0 0 0 0 0 0 0 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(6p) | cw(12p) . T{ Call distribution within a hunt group T} 0 0 0 0 0 1 1 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(6p) | cw(12p) . T{ Call redirection due to originally called DTE out of order T} 0 0 0 0 1 0 0 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(6p) | cw(12p) . T{ Call redirection due to prior request from originally called DTE for systematic call redirection T} 0 0 0 0 1 1 1 1 .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(6p) | cw(12p) . T{ Called DTE originated\|\ua\d\u)\d T} 1 0 X X X X X X .T& lw(156p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(6p) | cw(12p) . T{ Call deflection by the originally called DTE\|\ub\d\u)\d T} 1 1 X X X X X T{ X \ua\d\u)\d Each X may be independently set to 0 or 1 by the called DTE and is passed transparently to the calling DTE. Bit\ 8, when received from the called DTE, and when it is not set to\ 1, is forced to 1 by the DCE. .parag \ub\d\u)\d The Xs are those set by the originally called DTE in the \fIcall deflection selection\fR \| facility (see \(sc\ 7.2.2.10). .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable 32/X.25 [T50.25], p.\fR .sp 1P .RT .ad b .RT .sp 1P .LP 7.2.2.13 \fITransit delay selection and indication facility\fR .sp 9p .RT .PP This parameter is two octets. Transit delay is expressed in milliseconds, binary coded, with bit\ 8 of octet\ 1 being the high order bit and bit\ 1 of octet\ 2 being the low order bit. The expressed transit delay may have a value from\ 0 to 65\|534 (all bits set to\ 1 but the low order bit). .PP \fINote\fR \ \(em\ During the interim period when this optional user facility is not yet supported by all networks, the transit delay indicated in the \fIcall\fR \fIconnected\fR packet transmitted to the calling DTE should have a value of .PP 65\|535 (all ones) when either a transit network involved in the virtual call or the destination network does not support this facility. So, this value should be interpreted by the calling DTE as an indication that the actual transit delay cannot be transmitted to it. .RT .sp 1P .LP 7.3 \fICoding of the registration field of registration packets\fR .sp 9p .RT .PP The coding of the registration code field and the format of the registration parameter field are the same in \fIregistration request\fR packets and \fIregistration confirmation\fR packets in which they are used. .bp .RT .sp 1P .LP 7.3.1 \fICoding of the registration code fields\fR .sp 9p .RT .PP Table 33/X.25 gives the coding of the registration code field and the registration code field and the packet types in which they may be present. .RT .ce \fBH.T. [T51.25]\fR .ce TABLE\ 33/X.25 .ce \fBCoding of the registration code field\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(84p) | cw(36p) sw(36p) | cw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) , ^ | c | c | c s s s s s s s ^ | ^ | ^ | c | c | c | c | c | c | c | c. Facility May be used in: Registration code registration request registration confirmation Bits 8 7 6 5 4 3 2 1 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Facilities that may be negotiated only when all logical channels used for virtual calls are in state \fIp1\fR T} X X 0 0 0 0 0 1 0 1 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Facilities that may be negotiated at any time T} X X 0 1 0 0 0 1 0 1 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . Availability of facilities X 0 1 0 0 0 1 1 0 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Non\(hynegotiable facility values T} X 0 0 0 0 0 1 1 0 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Default throughput classes assignment T} X X 0 0 0 0 0 0 1 0 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Non\(hystandard default packet sizes T} X X 0 1 0 0 0 0 1 0 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . T{ Non\(hystandard default window sizes T} X X 0 1 0 0 0 0 1 1 _ .T& lw(84p) | cw(36p) | cw(36p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) . Logical channel type ranges X X 1 1 0 0 1 0 0 T{ 0 \fINote\fR \ \(em\ Whether or not the \fIcall redirection\fR \| facility may be negotiated requires further study. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable 33/X.25 [T51.25], p.\fR .sp 1P .RT .ad b .RT .PP The absence of a registration code in a \fIregistration request\fR packet means that the DTE does not want to modify the previous agreement for the concerned facility(ies). .PP The absence of a registration code in a \fIregistration confirmation\fR packet means that the concerned facility(ies) is not supported by the DCE or is not permitted by the DCE to be negociated by the \fIon\(hyline facility\fR \fIregistration\fR facility. .PP DTEs and DCEs should discard registration elements with registration codes that they do not support or do not know. .RT .sp 2P .LP 7.3.2 \fICoding of the registration parameter fields\fR .sp 1P .RT .sp 1P .LP 7.3.2.1 \fIFacilities that may be negotiated only when all logical\fR \fIchannels used for virtual calls are in state\ p1\fR .sp 9p .RT .PP Each one of the following bits of the registration parameter field corresponds to one facility that may be negotiated only when all logical channels for virtual calls are in state\ \fIp1\fR (see annex\ F), and that needs only a single bit value to indicate its value. The correspondence between bits and facilities is given in Table\ 34/X.25. .bp .RT .ce \fBH.T. [T52.25]\fR .ce TABLE\ 34/X.25 .ce \fBCorrespondence between bits and facilities\fR .ce \fBfor the registration parameter field\fR .ce \fBcorresponding to facilities that may be negotiated only\fR .ce .ce \fBwhen all logical channels used for virtual calls are in state p1\fR .ce \fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(60p) | cw(120p) . Bit number T{ Facility corresponding to the bit T} _ .T& cw(60p) | lw(120p) . 8 7 6 5 4 T{ \ \ Reserved for future use (see Note 1) T} .T& cw(60p) | lw(120p) . 3 T{ \fID bit modification\fR \| facility T} .T& cw(60p) | lw(120p) . 2 T{ \fIPacket retransmission\fR \| facility T} .T& cw(60p) | lw(120p) . 1 T{ \fIExtended packet sequence numbering\fR \| facility (see Note 2) \fINote\ 1\fR \ \(em\ Bits 8, 7, 6, 5 and 4 should be ignored when received and set to 0 when transmitted by DTE or DCE. .parag \fINote\ 2\fR \ \(em\ Further study is needed to determine the exact method to negotiate this facility. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable 34/X.25 [T52.25 ], p.\fR .sp 1P .RT .ad b .RT .PP A bit set to 1/0 in a \fIregistration request\fR packet means that the DTE asks for the DCE to invoke/revoke the corresponding facility. .PP A bit set to 1/0 in a \fIregistration confirmation\fR packet means that the corresponding facility is invoked/revoked by the DCE. .RT .sp 1P .LP 7.3.2.2 \fIFacilities that may be negotiated at any time\fR .sp 9p .RT .PP Each one of the following bits of the registration parameter field corresponds to one facility that may be negotiated at any time (see Annex\ F). The correspondence between bits and facilities is given in Table\ 35/X.25. .RT .PP A bit set to 1/0 in a \fIregistration request\fR packet means that the DTE asks for the DCE to invoke/revoke the corresponding facility. .PP A bit set to 1/0 in a \fIregistration confirmation\fR packet means that the corresponding facility is invoked/revoked by the DCE. .RT .sp 1P .LP 7.3.2.3 \fIAvailability of facilities\fR .sp 9p .RT .PP Each one of the following bits of the registration parameter field corresponds to one facility whose availability must be indicated to the DTE. The correspondence between bits and facilities is given in Table\ 36/X.25. .RT .PP A bit set to 1/0 by the DCE in a \fIregistration confirmation\fR packet means that the corresponding facility is available/not available for use by the DTE, or negotiable/not negotiable by the DTE. .sp 1P .LP 7.3.2.4 \fINon\(hynegotiable facilities values\fR .sp 9p .RT .PP Each one of the following bits of the registration parameter field corresponds to one facility which is not available for negotiation but whose value should be indicated to the DTE. .PP Bit\ 1: \fILocal charging prevention\fR facility .PP \fINote\fR \ \(em\ Bits 8, 7, 6, 5, 4, 3 and\ 2 should be ignored when received by the DTE and set to\ 0 when transmitted by the DCE. .bp .RT .ce \fBH.T. [T53.25]\fR .ce TABLE\ 35/X.25 .ce \fBCorrespondence between bits and facilities\fR .ce \fBfor the registration parameter field\fR .ce \fBcorresponding to facilities that may be negotiated at any time\fR .ce \fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(54p) | cw(54p) | cw(120p) . Octet number Bit number T{ Facility corresponding to the bit T} _ .T& cw(54p) | cw(54p) | lw(120p) . 1 8 7 6 5 4 3 2 1 T{ Reserved for future use (see Note) \fICharging information\fR \| facility (per interface basis) \fIThroughput classe negotiation\fR \| facility \fIFlow control parameter negotiation\fR \| facility \fIReverse charging acceptance\fR \| facility \fIFast select acceptance\fR \| facility \fIOutgoing calls barred\fR \| facility \fIIncoming calls barred\fR \| facility T} _ .T& cw(54p) | cw(54p) | lw(120p) . 2 1 to 8 T{ Reserved for future use (see Note) \fINote\fR \ \(em\ Bit 8 of octet 1 and bits 8, 7, 6, 5, 4, 3, 2 and 1 of octet 2 should be ignored when received and set to\ 0 when transmitted by the DTE or DCE. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau 35/X.25 [T53.25], p. 10\fR .sp 1P .RT .ad b .RT .ce \fBH.T. [T54.25]\fR .ce TABLE\ 36/X.25 .ce \fBCorrespondence between bits and facilities\fR .ce \fBfor the registration parameter field\fR .ce \fBindicating availability of facilites\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(54p) | cw(54p) | cw(120p) . Octet number Bit number T{ Facility corresponding to the bit T} _ .T& cw(54p) | cw(54p) | lw(120p) . 1 8 7 6 5 4 3 2 1 T{ \fIReverse charging\fR \| facility (see Note 1) \fIReverse charging acceptance\fR \| facility \fICharging information\fR \| facility (per call basis) (see Note\ 1) \fICharging information\fR \| facility (per interface basis) \fICalled line address modified notification\fR \| facility (see Note\ 1) \fID bit modification\fR \| facility \fIPacket retransmission\fR \| facility \fIExtended packet sequence numbering\fR \| facility T} _ .T& cw(54p) | cw(54p) | lw(120p) . 2 8 7 6 5 4 3 2 1 T{ \fB.\fR \ Reserved for future use (see Note 2) \fB.\fR \fIRPOA selection\fR \| facility (see Note 1) \fILogical channel type ranges\fR \| registration facility \fINon\(hystandard default packet size\fR \| registration facility \fINon\(hystandard default window size\fR \| registration facility \fIDefault throughput classes assignment\fR \| registration facility \fINote\ 1\fR \ \(em\ A bit set to 1/0 for the corresponding facility indicates that it is available for use by the DTE; no further negotiation is required for these facilities. .parag \fINote\ 2\fR \ \(em\ Bits 8, 7 and 6 of octet 2 should be ignored when received by the DTE and set to\ 0 when transmitted by the DCE. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau 36/X.25 [T54.25], p. 11\fR .sp 1P .RT .ad b .RT .LP .bp .PP A bit is set to 1/0 in a \fIregistration confirmation\fR packet when the DCE has invoked/revoked the corresponding facility. .RT .sp 1P .LP 7.3.2.5 \fIDefault throughput classes\fR .sp 9p .RT .PP The throughput class for the direction of data transmission from the DTE is indicated in bits\ 8, 7, 6 and\ 5. The throughput class for the direction of data transmission from the DCE is indicated in bits\ 4, 3, 2 and\ 1. .PP The four bits indicating each throughput class are binary coded and correspond to throughput classes as indicated in Table\ 30/X.25 (see \(sc\ 7.2.2.2). .PP \fINote\fR \ \(em\ Registration applies only to facility values for virtual calls; it does not apply to facility values for permanent virtual circuits. .RT .sp 1P .LP 7.3.2.6 \fINon\(hystandard default packet sizes\fR .sp 9p .RT .PP The packet size for the direction of data transmission from the DCE is indicated in bits\ 4, 3, 2 and\ 1 of the first octet. The packet size for the direction of data transmission from the DTE is indicated in bits\ 4, 3, 2 and\ 1 of the second octet. Bits\ 8, 7, 6 and\ 5 of each octet must be zero. .PP The four bits indicating each packet size are binary coded and express the logarithm base\ 2 of the number of octets of the maximum packet size. .PP Networks may offer values from 4 to 12, corresponding to packet sizes of\ 16, 32, 64, 128, 256, 512, 1024, 2048 or 4096, or a subset of these values. All Administrations will provide a packet size of\ 128. .PP \fINote\fR \ \(em\ Registration applies only to facility values for virtual calls; it does not apply to facility values for permanent virtual circuits. .RT .sp 1P .LP 7.3.2.7 \fINon\(hystandard default window sizes\fR .sp 9p .RT .PP The window size for the direction of data transmission from the DCE is indicated in bits\ 7 to\ 1 of the first octet. The window size for the direction of data transmission from the DTE is indicated in bits\ 7 to\ 1 of the second octet. Bit\ 8 of each octet must be zero. .PP The bits indicating each window size are binary coded and express the size of the window. A value of zero is not allowed. .PP Window sizes of 8 to 127 are only valid when extended sequence numbering is used. The ranges of values allowed by a network are network dependent. All Administrations will provide a window size of\ 2. .PP \fINote\fR \ \(em\ Registration applies only to facility values for virtual calls; it does not apply to facility values for permanent virtual circuits. .RT .sp 1P .LP 7.3.2.8 \fILogical channel types ranges\fR .sp 9p .RT .PP The octet following the registration code field indicates the length, in octets, of the registration parameter field and shall indicate 14\ octets. .PP Bits 4, 3, 2 and 1 of octets 1, 3, 5, 7, 9 and 11 of registration parameter field shall contain the logical channel group number for parameters\ LIC, HIC, LTC, HTC, LOC and\ HOC, respectively (see Annex\ A). Bits\ 8, 7, 6 and\ 5 of these octets must be set to zero. .PP Octets 2, 4, 6, 8, 10 and 12 of the registration parameter field shall contain the logical channel numbers for parameters\ LIC, HIC, LTC, HTC, LOC and\ HOC, respectively (see Annex\ A). .PP No one\(hyway incoming logical channels is represented by LIC and HIC both equal to zero; no two\(hyway logical channels is represented by LTC and HTC both equal to zero; and no one\(hyway outgoing logical channels is represented by LOC and HOC both equal to zero. .PP Bits 4, 3, 2 and 1 of octet 13 of the registration parameter field shall contain the high order bits of the total number of logical channels to be used for virtual calls. Bits\ 8, 7, 6 and\ 5 of octet\ 13 must be set to zero. Octet\ 14 of the registration parameter field shall contain the low order bits of the total number of logical channels to be used for virtuals calls. .PP \fINote\ 1\fR \ \(em\ The inequalites of Annex A must apply to non\(hyzero values of LIC, HIC, LTC, HTC, LOC and HOC. .PP \fINote\ 2\fR \ \(em\ The total number of logical channels to be used for virtual calls as indicated in octets\ 13 and\ 14 is equal to the sum of the number of one\(hyway incoming logical channels, two\(hyway logical channels and one\(hyway outgoing logical channels. .bp .RT .ce 1000 ANNEX\ A .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBRange of logical channels used for virtual calls\fR .sp 1P .RT .ce 0 .ce 1000 \fBand permanent virtual circuits\fR .ce 0 .PP In the case of a single logical channel DTE, logical channel\ 1 will be used. .sp 1P .RT .PP For each multiple logical channel DTE/DCE interface, a range of logical channels will be agreed upon with the Administration according to Figure\ A\(hy1/X.25. .LP .rs .sp 45P .ad r \fBFigure A\(hy1/X.25, p.\fR .sp 1P .RT .ad b .RT .LP .bp .ce 1000 ANNEX\ B .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBPacket layer DTE/DCE interface state diagrams\fR .sp 1P .RT .ce 0 .LP B.1 \fISymbol definition of the state diagrams\fR .sp 1P .RT .LP .rs .sp 22P .ad r \fBFigure CCITT 19172, p.\fR .sp 1P .RT .ad b .RT .sp 1P .LP B.2 \fIOrder definition of the state diagrams\fR .sp 9p .RT .PP For the sake of clarity, the normal procedure at the interface is described in a number of small state diagrams. In order to describe the normal procedure fully, it is necessary to allocate a priority to the different figures and to relate a higher order diagram with a lower one. This has been done by the following means: .RT .LP \(em The figures are arranged in order of priority with Figure\ B\(hy1/X.25 (restart) having the highest priority and subsequent figures having lower priority. Priority means that when a packet belonging to a higher order diagram is transferred, that diagram is applicable and the lower order one is not. .LP \(em The relation with a state in a lower order diagram is given by including that state inside an ellipse in the higher order diagram. .LP .rs .sp 11P .ad r Blanc .ad b .RT .LP .bp .LP .rs .sp 47P .ad r \fBFIGURE B\(hy1/X.25, p. 14\fR .sp 1P .RT .ad b .RT .LP .bp .LP .rs .sp 47P .ad r \fBFIGURE B\(hy2/X.25, p. 15\fR .sp 1P .RT .ad b .RT .LP .bp .LP .rs .sp 47P .ad r \fBFIGURE B\(hy3/X.25, p. 16\fR .sp 1P .RT .ad b .RT .LP .bp .ce 1000 ANNEX\ C .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBActions taken by the DCE on receipt of packets\fR .sp 1P .RT .ce 0 .ce 1000 \fBin a given state of the packet layer DTE/DCE\fR .ce 0 .ce 1000 \fBinterface as perceived by the DCE\fR .ce 0 .LP \fIIntroduction\fR .sp 1P .RT .PP This annex specifies the actions taken by the DCE on receipt of packets in a given state of the packet layer DTE/DCE interface as perceived by the DCE. .PP It is presented as a succession of chained tables. .PP The following rules are valid for all these tables: .RT .LP 1) there may be more than one error associated with a packet. The network will stop normal processing of a packet when an error is encountered. Thus only one diagnostic code is associated with an error indication by the DCE. The order of packet decoding and checking on networks is not standardized; .LP 2) for those networks which are octet aligned, the detection of a non\(hyintegral number of octets may be made at the data link or packet layer. In this annex, only those networks which are octet aligned and detect the non\(hyintegral number of octets at the packet layer are concerned with the considerations about octet alignment; .LP 3) in each table, the actions taken by the DCE are indicated in the following way: .LP \(em DISCARD: the DCE discards the received packet and takes no subsequent action as a direct result of receiving that packet; the DCE remains in the same state; .LP \(em DIAG ## x: the DCE discards the received packet and, for networks which implement the \fIdiagnostic\fR packet, transmits to the DTE a \fIdiagnostic\fR packet containing the diagnostic\ ##\ x. The state of the interface is not changed; .LP \(em NORMAL or ERROR: the corresponding action is specified after each table. .LP 4) Annex E gives a list of the diagnostic codes which may be used. .LP .sp 2 .ce \fBH.T. [T55.25]\fR .ce TABLE\ C\(hy1/X.25 .ce \fBSpecial cases\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(114p) | cw(114p) . Packet from DTE Any state _ .T& lw(114p) | cw(114p) . T{ Any packet with packet length shorter than 2 octets, including data link layer valid I\(hyframe containing no packet T} DIAG ## 38 _ .T& lw(114p) | cw(114p) . T{ Any packet with invalid general format identifier (GFI) T} DIAG ## 40 _ .T& lw(114p) | cw(114p) . T{ Any packet with unassigned logical channel T} DIAG ## 36 _ .T& lw(114p) | cw(114p) . T{ Any packet with correct GFI and assigned logical channel, or with correct GFI and bits\ 1 to\ 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to\ 0 T} (see Table C\(hy2/X.25) _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy1/X.25 [T55.25], p. 17\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T56.25]\fR .ce TABLE\ C\(hy2/X.25 .ce \fBAction taken by the DCE on receipt of packets in a\fR .ce \fBgiven state of the packet layer DTE/DCE interface as\fR .ce .ce \fBperceived by the DCE: restart and registration procedure\fR .ce \fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ State of the interface as perceived by the DCE Packet from the DTE T} Packet layer ready r1 DTE restart request r2 DCE restart indication r3 _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Restart request with bits 1 to 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to zero T} NORMAL (r2) DISCARD NORMAL (r1) _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ DTE restart confirmation with bits 1 to 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to zero T} ERROR (r3) ## 17 ERROR (r3) ## 18 NORMAL (r1) _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Registration request (when supported by the DCE) with bits\ 1 to\ 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to zero T} NORMAL (r1) NORMAL (r2) NORMAL (r3) _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet supported by the DCE other than restart request, DTE restart confirmation and registration request (when supported by the DCE) with bits\ 1 to\ 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to zero T} DIAG ## 36 DIAG ## 36 DIAG ## 36 _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet having a packet type identifier which is shorter than 1\ octet, with bits\ 1 to\ 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to zero T} DIAG ## 38 ERROR (r3) ## 38 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet having a packet type identifier which is undefined or not supported by the DCE (i.e., reject or registration packets), with bits\ 1 to\ 4 of octet\ 1 and bits\ 1 to\ 8 of octet\ 2 equal to zero T} DIAG ## 33 ERROR (r3) ## 33 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Data, interrupt, call set\(hyup and clearing, flow control or reset, with assigned logical channel T} T{ See Table C\(hy3/X.25 or C\(hy4/X.25 (see Note) T} ERROR (r3) ## 18 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Restart request, DTE restart confirmation or registration request (when supported by the network) with bits\ 1 to\ 4 of octet\ 1 or bits\ 1 to\ 8 of octet\ 2 unequal to zero T} T{ See Table C\(hy3/X.25 or C\(hy4/X.25 (see Note) T} ERROR (r3) ## 41 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet having a packet type identifier which is shorter than 1\ octet, with assigned logical channel T} T{ See Table C\(hy3/X.25 or C\(hy4/X.25 (see Note) T} ERROR (r3) DISCARD ## 38 _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet having a packet type identifier which is undefined or not supported by the DCE (i.e., reject or registration packets), with assigned logical channel T} T{ See Table C\(hy3/X.25 or C\(hy4/X.25 (see Note) T} ERROR (r3) ## 33 T{ DISCARD \fINote\fR \ \(em\ Table C\(hy3/X.25 for logical channels assigned to virtual calls, Table\ C\(hy4/X.25 for logical channels assigned to permanent virtual circuits. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy2/X.25 [1T56.25], p. 18\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T56.25]\fR .ce ERROR (r3): .ce .line .ce \ \ ## x .ce .line .ce .ce The DCE discards the received packet, indicates a .ce restarting by transmitting to the DTE a .ce \fIrestart indication\fR .ce packet, with the cause \*QLocal .ce procedure error\*U and the diagnostic ##\ x, and enters .ce state\ r3. If connected through a virtual call, the .ce distant DTE is also informed of the restarting by a .ce \fIclear indication\fR .ce packet, with the cause \*QRemote .ce procedure error\*U (same diagnostic). In the case of a .ce permanent virtual circuit, the distant DTE will be .ce informed by a \fIreset indication\fR .ce packet, with the cause .ce \*QRemote procedure error\*U (same diagnostic). .ce .parag .ce NORMAL\ (ri): .ce Provided none of the following error conditions has occurred, .ce the action taken by the DCE follows the procedure as defined in .ce \(sc\(sc\ 3 and\ 6.1 and DTE/DCE interface enters .ce state\ ri: .ce .parag .ce a) .ce If a \fIrestart request\fR .ce \| packet or \fIDTE restart confirmation\fR .ce .ce packet received in state\ r3, or a \fIregistration request\fR .ce packet received in state\ r2 or\ r3, exceeds the maximum .ce permitted length, is too short or is not octet aligned .ce (see rule\ 2 in the introduction of this annex), .ce the DCE will invoke the ERROR\ ##\ 39, ##\ 38 or ##\ 82 .ce procedure, respectively. .ce .parag .ce \fINote\fR .ce \ \(em\ In the case of a \fIregistration request\fR .ce \| packet received .ce in state\ r2 or\ r3 with the error(s) as noted above, alternative .ce behavior by the DCE is for further study. .ce .parag .ce Some networks may invoke the ERROR ##\ 81 procedure if the .ce restarting cause field is not \*QDTE originated\*U in the .ce \fIrestart request\fR .ce packet received in state\ r3. .ce .parag .ce .ce b) .ce If a \fIrestart request\fR .ce \| or a \fIregistration request\fR .ce \| packet .ce received in state\ r1 exceeds the maximum permitted length, .ce is too short or is not octet aligned .ce (see rule\ 2 in the introduction of .ce this annex), the DCE shall invoke the .ce DIAG\ ##\ 39, ##\ 38 or ##\ 82 procedure, respectively. .ce .parag .ce Some networks may invoke the DIAG ## 81 procedure if the .ce restarting cause field is not \*QDTE originated\*U in the .ce \fIrestart request\fR .ce packet received in state\ r1. .ce .parag .ce .ce c) .ce If a \fIregistration request\fR .ce \| packet is received .ce from the DTE when the \fIon\(hyline facility registration\fR .ce facility is\fR .ce supported by the DCE but not subscribed by .ce the DTE, the DCE shall transmit to the DTE .ce a \fIregistration confirmation\fR .ce packet with the cause .ce \*QLocal procedure error\*U, the diagnostic\ ##\ 42, and no .ce registration field. .ce If a \fIregistration request\fR .ce packet modifying .ce one or more of the facilities which can take .ce effect only when all logical channels used for .ce virtual calls are in state\ p1 (see Annex\ F), is received .ce when it is possible to make the modification, .ce the DCE shall transmit a \fIrestart indication\fR .ce packet\fR .ce with the cause \*QRegistration/cancellation confirmed\*U and .ce diagnostic\ ##\ 0 and enter state\ r3, if there is one or more .ce logical channels assigned to permanent virtual .ce circuits. This action ensures that the permanent virtual .ce circuits are reset so that all of the negotiated .ce facilities can properly take .ce effect. .ce .parag .ce .ce \fBH.T. [1T58.25]\fR .ce TABLE\ C\(hy3/X.25 .ce \fBAction taken by the DCE on receipt of packets in a given state of\fR .ce .ce \fBthe packet layer DTE/DCE interface as perceived by the DCE:\fR .ce \fBcall set\(hyup and\fR .ce \fBclearing on logical channel assigned to virtual call\fR .ce (see Note 1) .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(60p) | cw(24p) sw(24p) sw(24p) sw(24p) sw(24p) sw(24p) sw(24p) , ^ | l | l | l | l | l | l | l. T{ State of the interface as perceived by the DCE Packet from the DTE with logical channel assigned to virtual call T} T{ Packet layer ready r1 rien Ready p1 rien DTE waiting p2 (see Note 3) rien\fR DCE waiting p3 (see Note 2) rien Data transfer p4 rien Call collision p5 (see Notes 2 and 3) rien DTE\ clear request p6 rien DCE\ clear indication p7 T} _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . Call request NORMAL (p2) ERROR (p7) ## 21 NORMAL (p5) ERROR (p7) ## 23 ERROR (p7) ## 24 ERROR (p7) ## 25 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . Call accepted ERROR (p7) ## 20 ERROR (p7) ## 21 NORMAL (p4) ERROR (p7) ## 23 ERROR (p7) ## 24 ERROR (p7) ## 25 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . Call request NORMAL (p6) NORMAL (p6) NORMAL (p6) NORMAL (p6) NORMAL (p6) DISCARD NORMAL (p1) _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . DTE clear confirmation ERROR (p7) ## 20 ERROR (p7) ## 21 ERROR (p7) ## 22 ERROR (p7) ## 23 ERROR (p7) ## 24 ERROR (p7) ## 25 NORMAL (p1) _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Data, interrupt, reset or flow control T} ERROR (p7) ## 20 ERROR (p7) ## 21 ERROR (p7) ## 22 See Table C\(hy4/X.25 ERROR (p7) ## 24 ERROR (p7) ## 25 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Restart request, DTE restart confirmation or registration request with bits\ 1 to\ 4 of octet\ 1 or bits\ 1 to\ 8 of octet\ 2 unequal to zero T} ERROR (p7) ## 41 ERROR (p7) ## 41 ERROR (p7) ## 41 See Table C\(hy4/X.25 ERROR (p7) ## 41 ERROR (p7) ## 41 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Packets having a packet type identifier which is shorter than one octet T} ERROR (p7) ## 38 ERROR (p7) ## 38 ERROR (p7) ## 38 See Table C\(hy4/X.25 ERROR (p7) ## 38 ERROR (p7) ## 38 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Packet having a packet type identifier which is undefined or not supported by the DCE (i.e., reject or registration packet) T} ERROR (p7) ## 33 ERROR (p7) ## 33 ERROR (p7) ## 33 See Table C\(hy4/X.25 ERROR (p7) ## 33 ERROR (p7) ## 33 T{ DISCARD \fINote\ 1\fR \ \(em\ On permanent virtual circuit, only state p4 exists and the DCE takes no action except those specified in Table\ C\(hy4/X.25. .parag \fINote\ 2\fR \ \(em\ This state does nos exist in the case of an outgoing one\(hyway logical channel (as perceived by the DTE). .parag \fINote\ 3\fR \ \(em\ This state does not exist in the case of an incoming one\(hyway logical channel (as perceived by the DTE). T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy2/X.25 [2T56.25], p. 19\fR .sp 1P .RT .ad b .RT .LP .rs .sp 21P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [1T58.25]\fR .ce TABLE\ C\(hy3/X.25 .ce \fBAction taken by the DCE on receipt of packets in a given state of\fR .ce .ce \fBthe packet layer DTE/DCE interface as perceived by the DCE:\fR .ce \fBcall set\(hyup and\fR .ce \fBclearing on logical channel assigned to virtual call\fR .ce (see Note 1) .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(60p) | cw(24p) sw(24p) sw(24p) sw(24p) sw(24p) sw(24p) sw(24p) , ^ | l | l | l | l | l | l | l. T{ State of the interface as perceived by the DCE Packet from the DTE with logical channel assigned to virtual call T} T{ Packet layer ready r1 rien Ready p1 rien DTE waiting p2 (see Note 3) rien\fR DCE waiting p3 (see Note 2) rien Data transfer p4 rien Call collision p5 (see Notes 2 and 3) rien DTE\ clear request p6 rien DCE\ clear indication p7 T} _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . Call request NORMAL (p2) ERROR (p7) ## 21 NORMAL (p5) ERROR (p7) ## 23 ERROR (p7) ## 24 ERROR (p7) ## 25 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . Call accepted ERROR (p7) ## 20 ERROR (p7) ## 21 NORMAL (p4) ERROR (p7) ## 23 ERROR (p7) ## 24 ERROR (p7) ## 25 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . Call request NORMAL (p6) NORMAL (p6) NORMAL (p6) NORMAL (p6) NORMAL (p6) DISCARD NORMAL (p1) _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . DTE clear confirmation ERROR (p7) ## 20 ERROR (p7) ## 21 ERROR (p7) ## 22 ERROR (p7) ## 23 ERROR (p7) ## 24 ERROR (p7) ## 25 NORMAL (p1) _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Data, interrupt, reset or flow control T} ERROR (p7) ## 20 ERROR (p7) ## 21 ERROR (p7) ## 22 See Table C\(hy4/X.25 ERROR (p7) ## 24 ERROR (p7) ## 25 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Restart request, DTE restart confirmation or registration request with bits\ 1 to\ 4 of octet\ 1 or bits\ 1 to\ 8 of octet\ 2 unequal to zero T} ERROR (p7) ## 41 ERROR (p7) ## 41 ERROR (p7) ## 41 See Table C\(hy4/X.25 ERROR (p7) ## 41 ERROR (p7) ## 41 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Packets having a packet type identifier which is shorter than one octet T} ERROR (p7) ## 38 ERROR (p7) ## 38 ERROR (p7) ## 38 See Table C\(hy4/X.25 ERROR (p7) ## 38 ERROR (p7) ## 38 DISCARD _ .T& lw(60p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) | cw(24p) . T{ Packet having a packet type identifier which is undefined or not supported by the DCE (i.e., reject or registration packet) T} ERROR (p7) ## 33 ERROR (p7) ## 33 ERROR (p7) ## 33 See Table C\(hy4/X.25 ERROR (p7) ## 33 ERROR (p7) ## 33 T{ DISCARD \fINote\ 1\fR \ \(em\ On permanent virtual circuit, only state p4 exists and the DCE takes no action except those specified in Table\ C\(hy4/X.25. .parag \fINote\ 2\fR \ \(em\ This state does nos exist in the case of an outgoing one\(hyway logical channel (as perceived by the DTE). .parag \fINote\ 3\fR \ \(em\ This state does not exist in the case of an incoming one\(hyway logical channel (as perceived by the DTE). T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [1T58.25], p. 20\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T58.25]\fR .ce ERROR (p7): .ce .line .ce \ \ ## x .ce .line .ce The DCE discards the received packet, indicates a .ce clearing by transmitting to the DTE a \fIclear indication\fR .ce packet, .ce with the cause \*QLocal procedure error\*U and the diagnostic\ ##\ x, .ce and enters state\ p7. If connected through a virtual .ce call, the distant DTE is also informed of the clearing .ce by a \fIclear indication\fR .ce packet, with the cause .ce \*QRemote procedure error\*U (same diagnostic). .ce .parag .ce NORMAL\ (pi): .ce Provide none of the following error conditions has occurred, the action taken by the DCE follows the procedures as defined in \(sc\ 4 .ce and the DTE/DCE interface enters state\ pi. In all the cases specified .ce hereunder, the DCE will transmit to the DTE a \fIclear indication\fR .ce with the .ce appropriate cause and diagnostic, and enter state\ p7. If connected .ce through a virtual call, the distant DTE is also .ce informed of the clearing by a \fIclear indication\fR .ce packet .ce with the cause \*QRemote procedure error\*U .ce (same diagnostic). .ce \fBH.T. [3T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(228p) . T{ a)\ \ \fICall request packet\fR T} .T& cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 1. Packet not octet aligned (see rule\ 2 in the introduction of this annex) T} Local procedure error ## 82 .T& lw(108p) | cw(60p) | cw(60p) . \ 2. Packet too short Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 3. Incoming one\(hyway logical channel (as perceived by the DTE) T} Local procedure error ## 34 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 4. Address length larger than remainder of packet T} Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 5. Address contains a non\(hyBCD digit T} Local procedure error ## 67, ## 68 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 6. Invalid calling DTE address (see Note) T} Local procedure error ## 68 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 7. Invalid called DTE address (see Note) T} T{ Local procedure error or not obtainable T} T{ ## 67 \ \fINote\fR \ \(em\ Possible reasons for invalid address are: \ \(em\ Prefix digit not supported; \ \(em\ Invalid type of address/numbering plan identification informations (A bit set to\ 1); \ \(em\ National address smaller than permitted by the national address format; \ \(em\ National address larger than permitted by the national address format; \ \(em\ DNIC less than four digits, etc. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [2T58.25], p. 21\fR .sp 1P .RT .ad b .RT .LP .sp 5 .ce \fBH.T. [3T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(228p) . T{ a)\ \ \fICall request packet\fR T} .T& cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 1. Packet not octet aligned (see rule\ 2 in the introduction of this annex) T} Local procedure error ## 82 .T& lw(108p) | cw(60p) | cw(60p) . \ 2. Packet too short Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 3. Incoming one\(hyway logical channel (as perceived by the DTE) T} Local procedure error ## 34 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 4. Address length larger than remainder of packet T} Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 5. Address contains a non\(hyBCD digit T} Local procedure error ## 67, ## 68 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 6. Invalid calling DTE address (see Note) T} Local procedure error ## 68 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 7. Invalid called DTE address (see Note) T} T{ Local procedure error or not obtainable T} T{ ## 67 \ \fINote\fR \ \(em\ Possible reasons for invalid address are: \ \(em\ Prefix digit not supported; \ \(em\ Invalid type of address/numbering plan identification informations (A bit set to\ 1); \ \(em\ National address smaller than permitted by the national address format; \ \(em\ National address larger than permitted by the national address format; \ \(em\ DNIC less than four digits, etc. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [3T58.25], p. 22\fR .sp 1P .RT .ad b .RT .LP .rs .sp 3P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [4T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 8. Value of the facility length field geater than 109 T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 9. No combination of facilities could equal facility length T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . T{ 10. Facility length larger than remainder of packet T} Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . 11. Facility code not allowed Invalid facility request ## 65 .T& lw(108p) | cw(60p) | cw(60p) . T{ 12. Facility value not allowed or invalid T} Invalid facility request ## 66 .T& lw(108p) | cw(60p) | cw(60p) . T{ 13. Class coding of the facility corresponding to a length of parameter larger than remainder of packet T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . 14. Facility code repeated Local procedure error ## 73 .T& lw(108p) | cw(60p) | cw(60p) . T{ 15. Invalid network user identifier T} Invalid facility request ## 84 .T& lw(108p) | cw(60p) | cw(60p) . T{ 16. \fINUI selection\fR \| facility expected by the DCE and not provided by the DTE T} Local procedure error ## 84 .T& lw(108p) | cw(60p) | cw(60p) . T{ 17. Invalid/unsupported NUI value or missing NUI detected at inter\(hynetwork interface T} Access barred ## 84 .T& lw(108p) | cw(60p) | cw(60p) . 18. RPOA selection required RPOA out of order ## 76 .T& lw(108p) | cw(60p) | cw(60p) . T{ 19. Facility values conflicts (e.g., a particular combination not supported) T} Invalid facility request ## 66 .T& lw(108p) | cw(60p) | cw(60p) . T{ 20. CCITT\(hyspecified DTE facility code or parameter not allowed or invalid T} Invalid facility request ## 77 .T& lw(108p) | cw(60p) | cw(60p) . T{ 21. Call user data larger than 16, or 128 in case of \fIfast select\fR facility T} Local procedure error ## 39 _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [4T58.25], p. 23\fR .sp 1P .RT .ad b .RT .LP .rs .sp 10P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [5T58.25]\fR .ce If the virtual call cannot be established by the network, .ce the DCE should use a \fIcall progress\fR .ce \| signal and diagnostic code among .ce the following: .ce .parag .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ 22. Requested RPOA out of order T} RPOA out of order ## 0 .T& lw(108p) | cw(60p) | cw(60p) . T{ 23. Requested RPOA invalid or not supported T} RPOA out of order ## 119 .T& lw(108p) | cw(60p) | cw(60p) . 24. Unknown number Not obtainable ## 67 .T& lw(108p) | cw(60p) | cw(60p) . 25. Incoming call barred Access barred ## 70 .T& lw(108p) | cw(60p) | cw(60p) . T{ 26. Closed user group protection T} Access barred ## 65 .T& lw(108p) | cw(60p) | cw(60p) . 27. Ship absent Ship absent ## \ 0 .T& lw(108p) | cw(60p) | cw(60p) . 28. Reverse charging rejected T{ Reverse charging acceptance not subscribed T} ## \ 0 .T& lw(108p) | cw(60p) | cw(60p) . 29. Fast select rejected T{ Fast select acceptance not subscribed T} ## \ 0 .T& lw(108p) | cw(60p) | cw(60p) . 30. Called DTE out of order Out of order ## \ 0 ## greater than 127 .T& lw(108p) | cw(60p) | cw(60p) . T{ 31. No logical channel available T} Number busy ## 71 .T& lw(108p) | cw(60p) | cw(60p) . 32. Call collision Number busy ## 71, ## 72 .T& lw(108p) | cw(60p) | cw(60p) . T{ 33. The remote DTE/DCE interface or the transit network does not support a function or a facility requested T} Incompatible destination T{ ## \ 0 \ \fINote\fR \ \(em\ Precise definition of error condition 30 necessitates further study, and should take into account the possible \ non\(hysupport of the virtual call service (only permanent virtual circuit) by the destination\ DTE. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [5T58.25], p. 24\fR .sp 1P .RT .ad b .RT .LP .sp 1 .ce \fBH.T. [6T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ 34. Procedure error at the remote DTE/DCE interface T} Remote procedure error T{ [see b) and c) below and Annex D] T} .T& lw(108p) | cw(60p) | cw(60p) . T{ 35. Temporary network congestion or fault condition within the network T} Network congestion T{ ## 0, ## 122 or ## greater than 127 T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [6T58.25], p. 25\fR .sp 1P .RT .ad b .RT .LP .rs .sp 1P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [7T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(228p) . T{ b)\ \ \fICall accepted packet\fR T} .T& cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 1. Packet not octet aligned (see rule\ 2 in the introduction of this annex) T} Local procedure error ## 82 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 2. Address length larger than remainder of packet T} Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 3. Address contains a non\(hyBCD digit T} Local procedure error ## 67, ## 68 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 4. Invalid calling DTE address [see Note under\ a)] T} Local procedure error ## 68 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 5. Invalid called DTE address [see Note under\ a)] T} Local procedure error ## 67 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 6. Value of the facility length greater than\ 109 T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 7. No combination of facilities could equal facility length T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 8. Facility length larger than remainder of packet T} Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 9. Facility code not allowed T} Invalid facility request ## 65 .T& lw(108p) | cw(60p) | cw(60p) . T{ 10. Facility value not allowed or invalid T} Invalid facility request ## 66 .T& lw(108p) | cw(60p) | cw(60p) . T{ 11. Class coding of the facility corresponding to a length of parameter field larger than remainder of packet T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . 12. Facility code repeated Local procedure error ## 73 .T& lw(108p) | cw(60p) | cw(60p) . T{ 13. Invalid network user identifier T} Invalid facility request ## 84 .T& lw(108p) | cw(60p) | cw(60p) . T{ 14. \fINUI selection\fR \| facility expected by the DCE and not provided by the DTE T} Local procedure error ## 84 .T& lw(108p) | cw(60p) | cw(60p) . T{ 15. Invalid/unsupported NUI value or missing NUI detected at inter\(hynetwork interface T} Access barred ## 84 .T& lw(108p) | cw(60p) | cw(60p) . T{ 16. Facility value conflict (e.g., a particular combination not supported) T} Invalid facility request ## 66 .T& lw(108p) | cw(60p) | cw(60p) . T{ 17. CCITT\(hyspecified DTE facility code or parameter not allowed or invalid T} Invalid facility request ## 77 .T& lw(108p) | cw(60p) | cw(60p) . T{ 18. Call user data larger than 128 (if \fIfast select\fR facility requested) T} Local procedure error ## 39 .T& lw(108p) | cw(60p) | cw(60p) . T{ 19. Call user data present (if \fIfast select\fR \| facility not requested) T} Local procedure error ## 39 .T& lw(108p) | cw(60p) | cw(60p) . T{ 20. The \fIincoming call\fR \| packet indicated fast select with restriction on response T} Local procedure error ## 42 _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [7T58.25], p. 26\fR .sp 1P .RT .ad b .RT .LP .rs .sp 1P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [8T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(228p) . T{ Some networks may invoke the ERROR ## 74 procedure if the calling and/or called DTE address length fields are not equal to\ 0 in the \fIcall accepted\fR packet, except when the \fIcalled line address modified\fR \fInotification\fR facility is present in the facility field. T} .T& lw(228p) . T{ c)\ \ \fIClear request packet\fR T} .T& cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of Annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 1. Packet not octet aligned (see rule\ 2 in the introduction of this annex) T} Local procedure error ## 82 .T& lw(108p) | cw(60p) | cw(60p) . \ 2. Packet too short Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 3. Packet length incorrectly larger than 5 octets T} Local procedure error ## 39 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 4. Calling DTE address length field not set to zero (at any time); called DTE address length field not set to zero except when the \fIcalled line address modified notification\fR facility is present in clearing a call in state\ p3 T} Local procedure error ## 74 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 5. Invalid called DTE address when the \fIcalled line address\fR \fImodified notification\fR facility is present in clearing a call in state\ p3 [see Note under\ a)] T} Local procedure error ## 67 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 6. Value of the facility length field greater than\ 109 T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 7. No combination of facilities could equal facility length T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 8. Facility length larger than remainder of packet T} Local procedure error ## 38 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 9. Facility code not allowed T} Invalid facility request ## 65 .T& lw(108p) | cw(60p) | cw(60p) . T{ 10. Facility value not allowed or invalid T} Invalid facility request ## 66 .T& lw(108p) | cw(60p) | cw(60p) . T{ 11. Class coding of the facility corresponding to a parameter field length larger than remainder of packet T} Local procedure error ## 69 .T& lw(108p) | cw(60p) | cw(60p) . 12. Facility code repeated Local procedure error ## 73 .T& lw(108p) | cw(60p) | cw(60p) . T{ 13. \fICall deflection selection\fR \| facility requested when the maximum number of call redirections and call deflections is reached T} Invalid facility request ## 78 .T& lw(108p) | cw(60p) | cw(60p) . T{ 14. \fICall deflection selection\fR \| facility requested after timer expiration T} Invalid facility request ## 53 .T& lw(108p) | cw(60p) | cw(60p) . T{ 15. Clear user data larger than 128 (if \fIfast select\fR facility requested) T} Local procedure error ## 39 .T& lw(108p) | cw(60p) | cw(60p) . T{ 16. Clear user data present (if \fIfast select\fR facility and \fIcall deflection selection\fR facility not requested) T} Local procedure error ## 39 .T& lw(108p) | cw(60p) | cw(60p) . T{ 17. Clear user data larger than 16 (if \fIfast select\fR facility not requested and \fIcall deflection selection\fR facility requested) T} Local procedure error ## 39 _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [8T58.25], p. 27\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [9T58.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(228p) . T{ Some networks may invoke the ERROR ## 81 procedure if the clearing cause field is not \*QDTE originated\*U in the \fIclear request\fR packet.\fR T} .T& lw(228p) . T{ d)\ \ \fIDTE clear confirmation packet\fR T} .T& cw(108p) | cw(60p) | cw(60p) . Error condition Cause T{ Specific diagnostics (see Note 3 of annex E) T} _ .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 1. Packet not octet aligned (see rule\ 2 in the introduction of this annex) T} Local procedure error ## 82 .T& lw(108p) | cw(60p) | cw(60p) . T{ \ 2. Packet length greater than 3\ octets T} Local procedure error ## 39 _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy3/X.25 [9T58.25], p. 28\fR .sp 1P .RT .ad b .RT .LP .rs .sp 38P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [T59.25]\fR .ce TABLE\ C\(hy4/X.25 .ce \fBAction taken by the DCE on receipt of packets in a given state of\fR .ce \fBthe packet layer DTE/DCE interface\fR .ce \fBas perceived by the DCE: data transfer\fR .ce \fB(flow control and reset) on assigned logical channels\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(108p) . Data transfer (p4) .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ State of the interface as perceived by the DCE Packet from the DTE with assigned logical channel T} Flow control ready (d1) DTE reset request (d2) DCE reset indication (d3) _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . Reset request NORMAL (d2) DISCARD NORMAL (d1) _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . DTE reset confirmation ERROR (d3) ## 27 ERROR (d3) ## 28 NORMAL (d1) _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Data, interrupt or flow control T} NORMAL (d1) ERROR (d3) ## 28 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Restart request, DTE restart confirmation or registration request with bits\ 1 to\ 4 of octet\ 1 or bits\ 1 to\ 8 of octet\ 2 unequal to zero T} ERROR (d3) ## 41 ERROR (d3) ## 41 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet having a packet type identifier which is shorter than 1\ octet T} ERROR (d3) ## 38 ERROR (d3) ## 38 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Packet having a packet type identifier which is undefined or not supported by the DCE (i.e., reject or registration packet) T} ERROR (d3) ## 33 ERROR (d3) ## 33 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . T{ Invalid packet type on a permanent virtual circuit T} ERROR (d3) ## 35 ERROR (d3) ## 35 DISCARD _ .T& lw(108p) | cw(36p) | cw(36p) | cw(36p) . Reject packet not subscribed ERROR (d3) ## 37 ERROR (d3) ## 37 T{ DISCARD ERROR (d3): .line \ \ ## x .line The DCE discards the received packet, indicates a reset by transmitting to the DTE a \fIreset indication\fR packet, with the cause \*QLocal procedure error\*U and the diagnostic\ ##\ x, and enter state\ d3. The distant DTE is also informed of the reset by a \fIreset indication\fR packet, with the cause \*QRemote procedure error\*U (same diagnostic). .parag NORMAL (di): Provided none of the following error conditions or special situations has occurred, the actions taken by the DCE follows the procedure as defined in\ \(sc\ 4: .parag a) if the packet exceeds the maximum permitted length, is too short, is not octet aligned (see rule\ 2 in the introduction of this annex), the DCE will invoke the ERROR\ ##\ 39, ##\ 38 or ##\ 82 procedure, respectively; b) some networks may invoke the ERROR ## 81 procedure if the resetting cause field in a \fIreset request\fR packet does not have the value \*QDTE originated\*U; c) some networks may invoke the ERROR ## 83 procedure if the Q bit is not set to the same value within a complete packet sequence; d) if the P(S) or the P(R) received is not valid, the DCE will invoke the ERROR\ ##\ 1 or\ ##\ 2 procedure respectively; e) the DCE will consider the receipt of a \fIDTE interrupt\fR \fIconfirmation\fR packet which does not correspond to a yet unconfirmed \fIDCE interrupt\fR packet as an error and will invoke the ERROR\ ##\ 43 procedure. The DCE will consider a \fIDTE interrupt\fR packet received before a previous \fIDTE interrupt\fR packet has been confirmed as an error, and will invoke the ERROR\ ##\ 44 procedure; f ) if the network has a temporary inability to handle data traffic for a permanent virtual circuit (see \(sc\ 4.2), and if the packet is a \fIdata, interrupt, flow control\fR or \fIreset request\fR packet received in state\ d1, the DCE shall transmit to the DTE a \fIreset indication\fR packet with the cause \*QNetwork out of order\*U and enter state\ d3 (\fIdata, interrupt\fR or \fIflow control\fR packet) or d1\ (\fIreset request\fR packet). .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy4/X.25 [T59.25], p. 29\fR .sp 1P .RT .ad b .RT .LP .bp .ce 1000 ANNEX\ D .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBPacket layer DCE time\(hyouts and DTE time\(hylimits\fR .sp 1P .RT .ce 0 .LP D.1 \fIDCE time\(hyouts\fR .sp 1P .RT .PP Under certain circumstances this Recommendation requires the DTE to respond to a packet issued from the DCE within a stated maximum time. .PP Table D\(hy1/X.25 covers these circumstances and the actions that the DCE will initiate upon the expiration of that time. .PP The time\(hyout values used by the DCE will never be less than those indicated in Table\ D\(hy1/X.25. .RT .sp 1P .LP D.2 \fIDTE time\(hylimits\fR .sp 9p .RT .PP Under certain circumstances, this Recommendation requires the DCE to respond to a packet from the DTE within a stated maximum time. Table\ D\(hy2/X.25 gives these maximum times. The actual DCE response times should be well within the specified time\(hylimits. The rare situation where a time\(hylimit is exceeded should only occur when there is a fault condition. .PP To facilitate recovery from such fault conditions, the DTE may incorporate timers. The time\(hylimits given in Table\ D\(hy2/X.25 are the lower limits of the times a DTE should allow for proper operation. A time\(hylimit longer than the values shown may be used. Suggestions on possible DTE actions upon expiration of the time\(hylimits are given in Table\ D\(hy2/X.25. .PP \fINote\fR \ \(em\ A DTE may use a time shorter than the value given for T21 in Table\ D\(hy2/X.25. This may be appropriate when the DTE knows the normal response time of the called DTE to an incoming call. In this case, the timer should account for the normal maximum response time of the called DTE and the estimated maximum call set\(hyup time. .RT .LP .rs .sp 24P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [T60.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(342p) . TABLE\ D\(hy1/X.25 .T& cw(342p) . \fBDCE time\(hyouts\fR .T& cw(24p) | cw(24p) | cw(30p) | cw(24p) | cw(36p) | cw(54p) sw(48p) | cw(54p) sw(48p) , ^ | ^ | ^ | ^ | ^ | c | c | c | c. Time\(hyout number Time\(hyout value Started when State of the logical channel Normally terminated when T{ Actions to be taken the first time the time\(hyout expires T} T{ Actions to be taken the second time the time\(hyout expires T} Local side Remote side Local side Remote side _ .T& cw(24p) | cw(24p) | lw(30p) | cw(24p) | lw(36p) | lw(54p) | lw(48p) | lw(54p) | lw(48p) . T10 \ 60 s T{ DCE issues a \fIrestart indication\fR T} r3 T{ DCE leaves the r3 state (i.e., the \fIrestart confirmation\fR or \fIrestart request\fR is received) T} T{ DCE remains in r3, signals a \fIrestart indication\fR (local procedure error\ ##\ 52) again, and restarts time\(hyout\ T10 T} T{ For permanent virtual circuits, DCE may enter the d3\ state signalling a \fIreset indication\fR (remote procedure error\ ##\ 52) T} T{ DCE enters the r1 state and may issue a \fIdiagnostic\fR packet (##\ 52) T} T{ For permanent virtual circuits, DCE may enter the d3\ state signalling a \fIreset indication\fR (remote procedure error\ ##\ 52) T} _ .T& cw(24p) | cw(24p) | lw(30p) | cw(24p) | lw(36p) | lw(54p) | lw(48p) | lw(54p) | lw(48p) . T11 180 s T{ DCE issues an \fIincoming call\fR T} p3 T{ DCE leaves the p3 state (e.g., the \fIcall accepted\fR , \fIclear request\fR or \fIcall request\fR is received) T} T{ DCE enters the p7 state signalling a \fIclear indication\fR (local procedure error\ ##\ 49) T} T{ DCE enters the p7 state signalling a \fIclear indication\fR (remote procedure error\ ##\ 49) T} _ .T& cw(24p) | cw(24p) | lw(30p) | cw(24p) | lw(36p) | lw(54p) | lw(48p) | lw(54p) | lw(48p) . T12 \ 60 s T{ DCE issues a \fIreset indication\fR T} d3 T{ DCE leaves the d3 state (e.g., the \fIreset confirmation\fR or \fIreset request\fR is received) T} T{ DCE remains in d3, signals a \fIreset indication\fR (local procedure error\ ##\ 51) again, and restarts time\(hyout\ T12 T} T{ DCE may enter the d3 state signalling a \fIreset indication\fR (remote procedure error\ ##\ 51) T} T{ For virtual calls, DCE enters the p7\ state signalling a \fIclear indication\fR (local procedure error\ ##\ 51). For permanent virtual circuits, DCE enters the d1\ state and may issue a \fIdiagnostic\fR packet\ (##\ 51) T} T{ For virtual calls, DCE enters the p7\ state signalling a \fIclear indication\fR (remote procedure error\ ##\ 51). For permanent virtual circuits, DCE may enter the d3\ state signalling a \fIreset indication\fR (remote procedure error\ ##\ 51) T} _ .T& cw(24p) | cw(24p) | lw(30p) | cw(24p) | lw(36p) | lw(54p) | lw(48p) | lw(54p) | lw(48p) . T13 \ 60 s T{ DCE issues a \fIclear indication\fR T} p7 T{ DCE leaves the p7\ state (e.g., the \fIclear confirmation\fR or \fIclear request\fR is received) T} T{ DCE remains in p7, signals a \fIclear indication\fR (local procedure error\ ##\ 50) again, and restarts the time\(hyout\ T13 T} T{ DCE enters the p1\ state and may issue a \fIdiagnostic\fR packet\ (##\ 50) T} _ .TE .nr PS 9 .RT .ad r \fBTABLEAU D\(hy1/X.25 [T60.25] (\*`a l'italienne), p. 30\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [T61.25]\fR .ce TABLE\ D\(hy2/X.25 .ce \fBDTE Time\(hylimits\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(24p) | cw(24p) | cw(36p) | cw(24p) | cw(60p) | cw(60p) . Time\(hyout number Time\(hylimit value Started when State of the logical channel Normally terminated when T{ Preferred action to be taken when time\(hylimit expires T} _ .T& cw(24p) | cw(24p) | lw(36p) | cw(24p) | lw(60p) | lw(60p) . T20 180 s T{ DTE issues a \fIrestart request\fR T} r2 T{ DTE leaves the r2 state (i.e., the \fIrestart confirmation\fR or \fIrestart indication\fR is received) T} T{ To retransmit the \fIrestart request\fR (see Note\ 1) T} _ .T& cw(24p) | cw(24p) | lw(36p) | cw(24p) | lw(60p) | lw(60p) . T21 200 s T{ DTE issues a \fIcall request\fR T} p2 T{ DTE leaves the p2 state (e.g., the \fIcall connected, clear indication\fR or \fIincoming call\fR is received) T} T{ To transmit a \fIclear request\fR T} _ .T& cw(24p) | cw(24p) | lw(36p) | cw(24p) | lw(60p) | lw(60p) . T22 180 s T{ DTE issues a \fIreset request\fR T} d2 T{ DTE leaves the d2 state (e.g., the \fIreset confirmation\fR or \fIreset indication\fR is received) T} T{ For virtual calls, to retransmit the \fIreset request\fR or to transmit a \fIclear request.\fR For virtual permanent call circuits, to retransmit the \fIreset request\fR (see Note\ 2) T} _ .T& cw(24p) | cw(24p) | lw(36p) | cw(24p) | lw(60p) | lw(60p) . T23 180 s T{ DTE issues a \fIclear request\fR T} p6 T{ DTE leaves the p6 state (e.g., the \fIclear confirmation\fR or \fIclear indication\fR is received) T} T{ To retransmit the \fIclear request\fR (see Note\ 2) T} _ .T& cw(24p) | cw(24p) | lw(36p) | cw(24p) | lw(60p) | lw(60p) . T28 (see Note\ 3) 300 s T{ DTE issues a \fIregistration request\fR T} any T{ DTE receives the \fIregistration confirmation\fR or a \fIdiagnostic\fR packet T} T{ May retransmit the \fIregistration request,\fR but should at some point recognize that the \fIon\(hyline facility registration\fR facility is not offered \fINote\ 1\fR \ \(em\ After unsuccessful retries, recovery decisions should be taken at higher layers. .parag \fINote\ 2\fR \ \(em\ After unsuccessful retries, the logical channel should be considered out of order. The restart procedure should be invoked for recovery if reinitialization of all logical channels is acceptable. .parag \fINote\ 3\fR \ \(em\ The DTE timers T24 through T27 have been assigned by ISO in the specification of the packet layer for X.25\ DTEs. To avoid ambiguity and confusion, the time\(hyout number has therefore been assigned\ T28. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTABLEAU D\(hy2/X.25 [T61.25], p. 31\fR .sp 1P .RT .ad b .RT .LP .rs .sp 8P .ad r Blanc .ad b .RT .LP .bp .ce 1000 ANNEX\ E .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBCoding of X.25 network generated diagnostic fields\fR .sp 1P .RT .ce 0 .ce 1000 \fBin clear, reset and restart indication, registration confirmation\fR .ce 0 .ce 1000 \fBand diagnostic packets\fR .ce 0 .LP .ce \fBH.T. [1T62.25]\fR .ce TABLE\ E\(hy1/X.25 .ce \fI(see Notes 1, 2 and 3)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(126p) | cw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) | cw(30p) , ^ | c | c | c | c | c | c | c | c | ^ . Diagnostics Bits Decimal 8 7 6 5 4 3 2 1 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ \fINo additional information\fR T} 0 0 0 0 0 0 0 0\fR \ \ 0 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Invalid P(S) 0 0 0 0 0 0 0 1\fR \ \ 1 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Invalid P(R) 0 0 0 0 0 0 1 0\fR \ \ 2 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 0 0 0 1 1 1 1\fR \ 15 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . \fIPacket type invalid\fR 0 0 0 1 0 0 0 0\fR \ 16 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state r1 0 0 0 1 0 0 0 1\fR \ 17 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state r2 0 0 0 1 0 0 1 0\fR \ 18 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state r3 0 0 0 1 0 0 1 1\fR \ 19 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p1 0 0 0 1 0 1 0 0\fR \ 20 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p2 0 0 0 1 0 1 0 1\fR \ 21 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p3 0 0 0 1 0 1 1 0\fR \ 22 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p4 0 0 0 1 0 1 1 1 \ 23 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p5 0 0 0 1 1 0 0 0\fR \ 24 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p6 0 0 0 1 1 0 0 1 \ 25 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state p7 0 0 0 1 1 0 1 0\fR \ 26 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state d1 0 0 0 1 1 0 1 1 \ 27 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state d2 0 0 0 1 1 1 0 0\fR \ 28 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For state d3 0 0 0 1 1 1 0 1 \ 29 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 0 0 1 1 1 1 1\fR \ 31 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . \fIPacket not allowed\fR 0 0 1 0 0 0 0 0\fR \ 32 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Unidentifiable packet 0 0 1 0 0 0 0 1\fR \ 33 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Call on one\(hyway logical channel T} 0 0 1 0 0 0 1 0\fR \ 34 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Invalid packet type on a permanent virtual circuit T} 0 0 1 0 0 0 1 1\fR \ 35 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Packet on unassigned logical channel T} 0 0 1 0 0 1 0 0\fR \ 36 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Reject not subscribed to 0 0 1 0 0 1 0 1\fR \ 37 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Packet too short 0 0 1 0 0 1 1 0\fR \ 38 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Packet too long 0 0 1 0 0 1 1 1\fR \ 39 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Invalid general format identifier T} 0 0 1 0 1 0 0 0\fR \ 40 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Restart or registration packet with nonzero in bits\ 1 to\ 4 of octet\ 1, or bits\ 1 to\ 8 of octet\ 2 T} 0 0 1 0 1 0 0 1\fR \ 41 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Packet type not compatible with facility T} 0 0 1 0 1 0 1 0\fR \ 42 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Unauthorized interrupt confirmation T} 0 0 1 0 1 0 1 1\fR \ 43 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Unauthorized interrupt 0 0 1 0 1 1 0 0\fR \ 44 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Unauthorized reject 0 0 1 0 1 1 0 1\fR \ 45 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 0 1 0 1 1 1 1\fR \ 47 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . \fITime expired\fR 0 0 1 1 0 0 0 0\fR \ 48 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For incoming call 0 0 1 1 0 0 0 1\fR \ 49 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For clear indication 0 0 1 1 0 0 1 0\fR \ 50 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For reset indication 0 0 1 1 0 0 1 1\fR \ 51 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For restart indication 0 0 1 1 0 1 0 0\fR \ 52 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . For call deflection 0 0 1 1 0 1 0 1\fR \ 53 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 0 1 1 1 1 1 1\fR \ 63 _ .TE .nr PS 9 .RT .ad r \fBTableau E\(hy1/X.25 [1T62.25], p. 32\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T62.25]\fR .ce TABLE\ E\(hy1/X.25 \fI(cont.)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(126p) | cw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) sw(12p) sw(6p) | cw(30p) , ^ | c | c | c | c | c | c | c | c | ^ . Diagnostics Bits Decimal 8 7 6 5 4 3 2 1 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ \fICall set\(hyup, call clearing or registration\fR \fIproblem\fR T} 0 1 0 0 0 0 0 0\fR \ 64 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Facility/registration code not allowed T} 0 1 0 0 0 0 0 1\fR \ 65 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Facility parameter not allowed T} 0 1 0 0 0 0 1 0\fR \ 66 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Invalid called DTE address 0 1 0 0 0 0 1 1\fR \ 67 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Invalid calling DTE address 0 1 0 0 0 1 0 0\fR \ 68 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Invalid facility/registration length T} 0 1 0 0 0 1 0 1\fR \ 69 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Incoming call barred 0 1 0 0 0 1 1 0\fR \ 70 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . No logical channel available 0 1 0 0 0 1 1 1\fR \ 71 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Call collision 0 1 0 0 1 0 0 0\fR \ 72 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Duplicate facility requested 0 1 0 0 1 0 0 1\fR \ 73 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Non zero address length 0 1 0 0 1 0 1 0\fR \ 74 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Non zero facility length 0 1 0 0 1 0 1 1\fR \ 75 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Facility not provided when expected T} 0 1 0 0 1 1 0 0\fR \ 76 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Invalid CCITT\(hyspecified DTE facility T} 0 1 0 0 1 1 0 1\fR \ 77 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Maximum number of call redirections or call deflections exceeded T} 0 1 0 0 1 1 1 0\fR \ 78 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 1 0 0 1 1 1 1\fR \ 79 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . \fIMiscellaneous\fR 0 1 0 1 0 0 0 0\fR \ 80 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Improper cause code from DTE 0 1 0 1 0 0 0 1\fR \ 81 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Not aligned octet 0 1 0 1 0 0 1 0\fR \ 82 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Inconsistent Q bit setting 0 1 0 1 0 0 1 1\fR \ 83 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . NUI problem 0 1 0 1 0 1 0 0\fR \ 84 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 1 0 1 1 1 1 1\fR \ 95 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . \fINot assigned\fR 0 1 1 0 0 0 0 0\fR \ 96 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 1 1 0 1 1 1 1\fR 111 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ \fIInternational problem\fR T} 0 1 1 1 0 0 0 0\fR 112 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Remote network problem 0 1 1 1 0 0 0 1\fR 113 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ International protocol problem T} 0 1 1 1 0 0 1 0\fR 114 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ International link out of order T} 0 1 1 1 0 0 1 1\fR 115 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . International link busy 0 1 1 1 0 1 0 0\fR 116 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Transit network facility problem T} 0 1 1 1 0 1 0 1\fR 117 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Remote network facility problem T} 0 1 1 1 0 1 1 0\fR 118 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . International routing problem 0 1 1 1 0 1 1 1\fR 119 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Temporary routing problem 0 1 1 1 1 0 0 0\fR 120 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . Unknown called DNIC 0 1 1 1 1 0 0 1\fR 121 .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ Maintenance action (see Note\ 4) T} 0 1 1 1 1 0 1 0\fR 122 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 0 1 1 1 1 1 1 1\fR 127 _ .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . T{ \fIReserved for network specific diagnostic information\fR T} 1 0 0 0 0 0 0 0\fR 128 .T& lw(72p) . .T& lw(126p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(12p) | cw(6p) | cw(30p) . 1 1 1 1 1 1 1 1\fR T{ 255 \fINote\ 1\fR \ \(em\ Not all diagnostic codes need apply to a specific network, but those used are as coded in the table. .parag \fINote\ 2\fR \ \(em\ A given diagnostic need not apply to all packet types (i.e., \fIreset indication, clear indication, restart indication, registration\fR \fIconfirmation\fR and \fIdiagnostic\fR packets). .parag \fINote\ 3\fR \ \(em\ The first diagnostic in each grouping is a generic diagnostic and can be used in place of the more specific diagnostics within the grouping. The decimal\ 0 diagnostic code can be used in situations where no additional information is available. .parag \fINote\ 4\fR \ \(em\ This diagnostic may also apply to a maintenance action within a national network. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau E\(hy1/X.25 [2T62.25], p. 33\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [T63.25]\fR .ce ANNEX\ F .ce (to Recommendation X.25) .ce \fBApplicability of the on\(hyline facility registration\fR .ce \fBfacility to other facilities\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Name of facility or interface parameter T} T{ Reference to definition (\(sc) T} T{ Negotiable in \fIregistration request\fR and \fIregistration\fR \fIconfirmation\fR packets T} T{ Indication in \fIregistration confirmation\fR packets whether the facility is supported by the DCE T} T{ Negotiable only when every logical channel used for virtual calls is in state\ p1 T} _ .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Extended packet sequence numbering T} 6.2\ Yes (see Note 1) Yes (see Note 1) Yes .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . D bit modification 6.3\ Yes Yes Yes .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Packet retransmission 6.4\ Yes Yes Yes .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Incoming calls barred 6.5\ Yes No No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Outgoing calls barred 6.6\ Yes No No .T& lw(90p) | cw(30p) | cw(72p) | lw(36p) . T{ One\(hyway logical channel outgoing T} 6.7\ (see Note 2) .T& lw(90p) | cw(30p) | cw(72p) | lw(36p) . T{ One\(hyway logical channel incoming T} 6.8\ (see Note 2) .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Non\(hystandard default packet sizes T} 6.9\ Yes Yes No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Non\(hystandard default window sizes T} 6.10 Yes Yes No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Default throughput classes assignment T} 6.11 Yes Yes No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Flow control parameter negotiation T} 6.12 Yes No No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Throughput class negotiation 6.13 Yes No No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Closed user group related facilities T} 6.14 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Bilateral closed user group related facilities T} 6.15 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Fast select 6.16 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Fast select acceptance 6.17 Yes No No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Reverse charging 6.18 No Yes \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Reverse charging acceptance 6.19 Yes Yes No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Local charging prevention 6.20 No Yes \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . NUI related facilities 6.21 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Charging information 6.22 .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . \ (per interface basis) Yes Yes No .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . \ (per call basis) No Yes \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . RPOA related facilities .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . \ RPOA subscription 6.23.1 (see Note 1) (see Note 1) (see Note 1) .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . \ RPOA selection 6.23.2 No Yes \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Hunt group 6.24 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . Call redirection 6.25.1 (see Note 1) (see Note 1) (see Note 1) .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Call deflection related facilities T} 6.25.2 (see Note 1) (see Note 1) (see Note 1) .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Call redirection or call deflection notification T} 6.25.3 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Called line address modified notification T} 6.26 No No \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Transit delay selection and indication T} 6.27 No Yes \(em .T& lw(90p) | cw(30p) | cw(36p) | cw(36p) | cw(36p) . T{ Allocation of logical channel type range T} Annex A Yes Yes T{ Yes \fINote\ 1\fR \ \(em\ Further study is needed. .parag \fINote\ 2\fR \ \(em\ Negotiation of one\(hyway logical channel ranges is accomplished by allocation of logical channel type ranges negotiation. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau Annexe F [T63.25], p. 34\fR .sp 1P .RT .ad b .RT .LP .bp .ce 1000 ANNEX\ G .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBCCITT\(hyspecified DTE facilities to support the OSI\fR .sp 1P .RT .ce 0 .ce 1000 \fBNetwork service\fR .ce 0 .LP G.1 \fIIntroduction\fR .sp 1P .RT .PP The facilities described in this annex are intended to support end\(hyto\(hyend signalling required by the OSI Network service . They follow the CCITT\(hyspecified DTE facility marker defined in \(sc\ 7.1. These facilities are passed unchanged between the two packet mode DTEs involved. .PP Procedures for use of these facilities by DTEs are specified in ISO\ 8208. Subsequent provision of X.25 facilities to be acted on by public data networks is for further study. Coding of the facilities in this annex is defined here in order to facilitate a consistent facility coding scheme in such future evolution. .RT .sp 1P .LP G.2 \fICoding of the facility code fields\fR .sp 9p .RT .PP Table G\(hy1/X.25 gives the coding of the facility code field for each CCITT\(hyspecified DTE facility and the packet types in which they may be present. These facilities are conveyed after the CCITT\(hyspecified DTE facility marker. .RT .ce \fBH.T. [T64.25]\fR .ce TABLE\ G\(hy1/X.25 .ce \fBCoding of the facility code field\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(48p) | cw(22p) sw(22p) sw(16p) sw(22p) sw(22p) sw(16p) | cw(9p) sw(9p) sw(9p) sw(3p) sw(9p) sw(9p) sw(9p) sw(3p) , ^ | c | c | c | c | c | c | c s s s s s s s ^ | ^ | ^ | ^ | ^ | ^ | ^ | c | c | c | c | c | c | c | c. Facility T{ Packet types in which the facility may be used T} Facility code Call request Incoming call Call accepted Call connec ted Clear request Clear indication Bits 8 7 6 5 4 3 2 1 _ .T& lw(48p) | cw(22p) | cw(22p) | lw(16p) | lw(22p) | cw(22p) | lw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . Calling address extension X X X (see Note) 1 1 0 0 1 0 1 1 _ .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . Called address extension X X X X X X 1 1 0 0 1 0 0 1 _ .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . T{ Quality of service negotiation: T} .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . Minimum throughput class X X X (see Note) 0 0 0 0 1 0 1 0 .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . T{ End\(hyto\(hyend transit delay T} X X X X X (see Note) 1 1 0 0 1 0 1 0 .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . Priority X X X X X (see Note) 1 1 0 1 0 0 1 0 .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . Protection X X X X X (see Note) 1 1 0 1 0 0 1 1 _ .T& lw(48p) | cw(22p) | cw(22p) | cw(16p) | cw(22p) | cw(22p) | cw(16p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) | cw(9p) | cw(9p) | cw(9p) | cw(3p) . Expedited data negotiation X X X X X (see Note) 0 0 0 0 1 0 1 T{ 1 \fINote\fR \ \(em\ Only when the \fIcall deflection selection\fR \| facility is used (see \(sc\ 6.25.2.2.). .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable G\(hy1/X.25 [T64.25], p.\fR .sp 1P .RT .ad b .RT .LP .bp .sp 2P .LP G.3 \fICoding of the facility parameter field\fR .sp 1P .RT .sp 1P .LP G.3.1 \fICalling address extension facility\fR .sp 9p .RT .PP The octet following the facility code field indicates the length of the facility parameter field in octets. It has a value of \fIn\fR \ +\ 1, where \fIn\fR is the number of octets necessary to hold the calling address extension. The facility parameter field follows the length and contains the calling address extension. .PP The first octet of the facility parameter field indicates, in bits 8 and\ 7, the use of the calling address extension, as shown in Table\ G\(hy2/X.25. .RT .LP .sp 2 .ce \fBH.T. [T65.25]\fR .ce TABLE\ G\(hy2/X.25 .ce \fBCoding of bits 8 and 7 in the first octet\fR .ce \fBof the calling extension facility parameter field\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(36p) sw(36p) | cw(156p) , c | c | ^ . Bits T{ Use of calling address extension T} 8 7 _ .T& cw(36p) | cw(36p) | lw(156p) . 0 0 T{ To carry a calling address assigned according to Recommendation\ X.213/ISO 8348 AD2 T} .T& cw(36p) | cw(36p) | lw(156p) . 0 1 Reserved .T& cw(36p) | cw(36p) | lw(156p) . 1 0 T{ Other (to carry a calling address not assigned according to Recommendation\ X.213/ISO 8348 AD2) T} .T& cw(36p) | cw(36p) | lw(156p) . 1 1 Reserved _ .TE .nr PS 9 .RT .ad r \fBTable G\(hy2/X.25 [T65.25], p.\fR .sp 1P .RT .ad b .RT .PP .sp 2 Bits 6, 5, 4, 3, 2 and 1 of this octet indicates the number of semi\(hyoctets (up to a maximum of 40) in the calling address extension. This address length indicator is binary coded, where bit\ 1 is the low\(hyorder bit. .PP The following octets contain the calling address extension. .PP If bits 8 and 7 of the first octet of the facility parameter field are coded \*Q00\*U, the following octets are encoded using the preferred binary encoding (PBE) defined in Recommendation\ X.213. Starting from the high\(hyorder digit of the Initial Domain Part (IDP), the address is coded in octet\ 2 and consecutive octets of the facility parameter field. Each digit, with padding digits applied as necessary, is coded in a semi\(hyoctet in binary coded decimal, where bit\ 5 or\ 1 is the low\(hyorder bit of the digit. In each octet, the higher\(hyorder bit is coded in bits\ 8, 7, 6 and\ 5. The Domain Specific Part (DSP) of the calling OSI NSAP follows the IDP and is coded in decimal of binary, according to the PBE. For example, if the syntax of the DSP is decimal, each digit is coded in binary coded decimal (with the same rules applying to the DSP as to the IDP above). If the syntax of the DSP is binary, each octet of the calling address extension contains an octet of the DSP. .PP If bits 8 and 7 of the first octet of the facility parameter field are coded \*Q10\*U, each digit of the calling address extension is coded in a semi\(hyoctet in binary coded decimal, where bit\ 5 or\ 1 is the low\(hyorder bit of the digit. Starting from the high\(hyorder digit, the address is coded in octet\ 2 and consecutive octets of the facility parameter field with two digits per octet. In each octet, the higher order digit is coded in bits\ 8, 7, 6 and\ 5. .PP When necessary, the facility parameter field shall be rounded up to an integral number of octets by inserting zeros in bits\ 4, 3, 2 and\ 1 of the last octet of the field. .bp .RT .sp 1P .LP G.3.2 \fICalled address extension facility\fR .sp 9p .RT .PP The octet following the facility code field indicates the length of the facility parameter field in octets. It has a value of \fIn\fR \ +\ 1, where\ \fIn\fR is the number of octets necessary to hold the called address extension. The facility parameter field follows the length and indicates the called address extension. .PP The first octet of the facility parameter field indicates, in bits\ 8 and\ 7, the use of the called address extension, as shown in Table\ G\(hy3/X.25. .RT .ce \fBH.T. [T66.25]\fR .ce TABLE\ G\(hy3/X.25 .ce \fBCoding of bits 8 and 7 in the first octet\fR .ce \fBof the called extension facility parameter field\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(36p) sw(36p) | cw(156p) , c | c | ^ . Bits T{ Use of called address extension T} 8 7 _ .T& cw(36p) | cw(36p) | lw(156p) . 0 0 T{ To carry a called address assigned according to Recommendation\ X.213/ISO 8348 AD2 T} .T& cw(36p) | cw(36p) | lw(156p) . 0 1 Reserved .T& cw(36p) | cw(36p) | lw(156p) . 1 0 T{ Other (to carry a called address not assigned according to Recommendation\ X.213/ISO 8348 AD2) T} .T& cw(36p) | cw(36p) | lw(156p) . 1 1 Reserved _ .TE .nr PS 9 .RT .ad r \fBTable G\(hy3/X.25 [T66.25], p.\fR .sp 1P .RT .ad b .RT .PP Bits 6, 5, 4, 3, 2 and 1 of this octet indicates the number of semi\(hyoctets (up to a maximum of 40) in the called address extension. This address length indicator is binary coded, where bit\ 1 is the low\(hyorder bit. .PP The following octets contain the called address extension. .PP If bits 8 and 7 of the first octet of the facility parameter field are coded \*Q00\*U, the following octets are encoded using the preferred binary encoding (PBE) defined in Recommendation\ X.213. Starting from the high\(hyorder digit of the Initial Domain Part (IDP), the address is coded in octet\ 2 and consecutive octets of the facility parameter field. Each digit, with padding digits applied as necessary, is coded in a semi\(hyoctet in binary coded decimal, where bit\ 5 or\ 1 is the low\(hyorder bit of the digit. In each octet, the higher\(hyorder bit is coded in bits\ 8, 7, 6 and\ 5. The Domain Specific Part (DSP) of the called OSI NSAP follows the IDP and is coded in decimal of binary, according to the PBE. For example, if the syntax of the DSP is decimal, each digit is coded in binary coded decimal (with the same rules applying to the DSP as to the IDP above). If the syntax of the DSP is binary, each octet of the called address extension contains an octet of the DSP. .PP If bits 8 and 7 of the first octet of the facility parameter field are coded \*Q10\*U, each digit of the called address extension is coded in a semi\(hyoctet in binary coded decimal, where bit\ 5 or\ 1 is the low\(hyorder bit of the digit. Starting from the high\(hyorder digit, the address is coded in octet\ 2 and consecutive octets of the facility parameter field with two digits per octet. In each octet, the higher order digit is coded in bits\ 8, 7, 6 and\ 5. .PP When necessary, the facility parameter field shall be rounded up to an integral number of octets by inserting zeros in bits\ 4, 3, 2 and\ 1 of the last octet of the field. .RT .sp 2P .LP G.3.3 \fIQuality of service negotiation facilities\fR .sp 1P .RT .sp 1P .LP G.3.3.1 \fIMinimum throughput class facility\fR .sp 9p .RT .PP The minimum throughput class for the direction of data transmission from the calling DTE is indicated in bits\ 4, 3, 2 and\ 1. The minimum throughput class for the direction of data transmission from the called DTE is indicated in bits\ 8, 7, 6 and\ 5. .PP The four bits indicating each throughput class are binary coded and correspond to throughput classes as indicated in Table\ 30/X.25. .bp .RT .sp 1P .LP G.3.3.2 \fIEnd\(hyto\(hyend transit delay facility\fR .sp 9p .RT .PP The octet following the facility code field indicates the length in octets of the facility parameter field and has the value\ 2, 4 or\ 6. .PP The first and second octets of the facility parameter field contain the cumulative transit delay. The third and fourth octets are optional and, when present, contain the requested end\(hyto\(hyend transit delay. If the third and fourth octets are present, then the fifth and sixth octets are also optional. The fifth and sixth octets, when present, contain the maximum acceptable end\(hyto\(hyend transit delay. The optional octets are not present in \fIcall accepted\fR and \fIcall connected\fR packets. .PP Transit delay is expressed in milliseconds and is binary\(hycoded, with bit\ 8 of the first of a pair of octets being the high\(hyorder bit and bit\ 1 of the second of a pair of octets being the low\(hyorder bit. The value of all ones for cumulative transit delay indicates that the cumulative transit delay is unknown or exceeds\ 65\|534 milliseconds. .RT .sp 1P .LP G.3.3.3 \fIPriority facility\fR .sp 9p .RT .PP The octet following the facility code field indicates the length, in octets, of the facility parameter field. This may take the value 1, 2, 3, 4, 5 or\ 6. .PP The first, second and third octets of the facility parameter field contain the target (\fIcall request\fR packet), available (\fIincoming call\fR packet) or selected (\fIcall accepted\fR and \fIcall connected\fR packets) values for the priority of data on connection, priority to gain a connection and priority to keep a connection, respectively. The fourth, fifth and sixth octets of the facility parameter field in \fIcall request\fR and \fIincoming call\fR packets contain the lowest acceptable values for the priority of data on connection, priority to gain a connection and priority to keep a connection, respectively. When the facility is present in \fIcall request\fR and \fIincoming call\fR packets, octet\ 2 through\ 6 of the facility parameter field are optional. For example, if the only values to be specified are the target and lowest acceptable values for priority to gain a connection, then the facility parameter field will contain at least 5\ octets with octets 1, 3 and 4 containing the value \*Qunspecified\*U, and octets\ 2 and\ 5 containing the specified values. When the facility is present in the \fIcall accepted\fR and \fIcall connected\fR packets, octets\ 2 and\ 3 are optional. .PP The potential range of specified values for each sub\(hyparameter is 0 (lowest priority) to 254 (highest priority). The value 255 (1111\ 1111) indicates \*Qunspecified\*U. .RT .sp 1P .LP G.3.3.4 \fIProtection facility\fR .sp 9p .RT .PP The octet following the facility code indicates the length, in octets, of the facility parameter field. .PP The two highest order bits of the first octet (i.e., bits 8 and 7) of the facility parameter field specify the protection format code as indicated in Table\ G\(hy4/X.25. .RT .ce \fBH.T. [T67.25]\fR .ce TABLE\ G\(hy4/X.25 .ce \fBCoding of the two highest order bits in the first .ce octet of the protection format code\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(36p) sw(36p) | cw(156p) , c | c | ^ . Bits Protection format code 8 7 _ .T& cw(36p) | cw(36p) | lw(156p) . 0 0 Reserved .T& cw(36p) | cw(36p) | lw(156p) . 0 1 Source address specific .T& cw(36p) | cw(36p) | lw(156p) . 1 0 Destination address specific .T& cw(36p) | cw(36p) | lw(156p) . 1 1 Globally unique _ .TE .nr PS 9 .RT .ad r \fBTable G\(hy4/X.25 [T67.25], p.\fR .sp 1P .RT .ad b .RT .LP .bp .PP The remaining six bits of the octet are reserved and must be set to zero. .PP The second octet of the facility parameter field specifies the length \*Qn\*U, in octets, of the target (\fIcall request\fR packet), available (\fIincoming call\fR packet) or selected (\fIcall accepted\fR and \fIcall connected\fR packets) protection level. The actual value is placed in the following \*Qn\*U octets. Optionally, the \*Qn\ +\ 3\*U octet of the facility parameter field specifies the length \*Qm\*U, in octets, of the lowest acceptable protection level in \fIcall request\fR and \fIincoming call\fR packets. The actual value is placed in the following \*Qm\*U octets. The optional octets are not present in \fIcall accepted\fR and \fIcall connected\fR packets. .PP \fINote\fR \ \(em\ The values of \*Qn\*U and \*Qm\*U are bounded firstly by the overall length of the facility (first octet), and secondly by each other. .RT .sp 1P .LP G.3.4 \fIExpedited data negotiation facility\fR .sp 9p .RT .PP The coding of the facility parameter field is: .PP bit\ 1\ =\ 0 for no use of expedited data .PP bit\ 1\ =\ 1 for use of expedited data .PP \fINote\fR \ \(em\ Bits\ 8, 7, 6, 5, 4, 3 and\ 2 may be assigned to other facilities in the future; presently, they are set to zero. .RT .LP .rs .sp 36P .ad r Blanc .ad b .RT .LP .bp .ce 1000 ANNEX\ H .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBSubscription\(hytime optional user facilities that may be associated\fR .sp 1P .RT .ce 0 .ce 1000 \fBwith a network user identifier in conjunction with\fR .ce 0 .ce 1000 \fBthe NUI override facility\fR .ce 0 .ce 1000 (see \(sc 6.21.2) .ce 0 .ce \fBH.T. [T68.25]\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(168p) | cw(60p) . T{ Subscription\(hytime optional user facility T} May be associated with an NUI _ .T& lw(168p) | cw(60p) . T{ On\(hyline facility registration T} No .T& lw(168p) | cw(60p) . T{ Extended packet sequence numbering T} No .T& lw(168p) | cw(60p) . D bit modification No .T& lw(168p) | cw(60p) . Packet retransmission No .T& lw(168p) | cw(60p) . Incoming calls barred No .T& lw(168p) | cw(60p) . Outgoing calls barred No .T& lw(168p) | cw(60p) . T{ One\(hyway logical channel outgoing T} No .T& lw(168p) | cw(60p) . T{ One\(hyway logical channel incoming T} No .T& lw(168p) | cw(60p) . T{ Non\(hystandard default packet sizes T} Yes .T& lw(168p) | cw(60p) . T{ Non\(hystandard default window sizes T} Yes .T& lw(168p) | cw(60p) . T{ Default throughput classes assignment T} Yes .T& lw(168p) | cw(60p) . T{ Flow control parameter negotiation (subscription\(hytime) T} Yes .T& lw(168p) | cw(60p) . T{ Throughput class negotiation (subscription\(hytime) T} Yes .T& lw(168p) | cw(60p) . T{ Closed user group related facilities T} .T& lw(168p) | cw(60p) . \ \ Closed user group Yes .T& lw(168p) | cw(60p) . T{ \ \ Closed user group with outgoing access T} Yes .T& lw(168p) | cw(60p) . T{ \ \ Closed user group with incoming access T} No .T& lw(168p) | cw(60p) . T{ \ \ Incoming calls barred within a closed user group T} No .T& lw(168p) | cw(60p) . T{ \ \ Outgoing calls barred within a closed user group T} No .T& lw(168p) | cw(60p) . T{ Bilateral closed user group related facilities T} .T& lw(168p) | cw(60p) . T{ \ \ Bilateral closed user group T} Yes .T& lw(168p) | cw(60p) . T{ \ \ Bilateral closed user group with outgoing access T} Yes .T& lw(168p) | cw(60p) . Fast select acceptance No .T& lw(168p) | cw(60p) . Reverse charging acceptance No .T& lw(168p) | cw(60p) . Local charging prevention No .T& lw(168p) | cw(60p) . T{ Charging information (subscription\(hytime) T} Yes .T& lw(168p) | cw(60p) . RPOA subscription Yes .T& lw(168p) | cw(60p) . Hunt group No .T& lw(168p) | cw(60p) . T{ Call redirection and call deflection related facilities T} .T& lw(168p) | cw(60p) . \ \ Call redirection No .T& lw(168p) | cw(60p) . T{ \ \ Call deflection subscription T} No .T& lw(168p) | cw(60p) . T{ \ \ \*QTOA/NPI address\*U subscription T} No _ .TE .nr PS 9 .RT .ad r \fBTable [T68.25], p.\fR .sp 1P .RT .ad b .RT .LP .rs .sp 6P .ad r Blanc .ad b .RT .LP .bp .ce 1000 APPENDIX\ I .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBExamples of \fR \fBdata link layer transmitted bit patterns\fR .sp 1P .RT .ce 0 .ce 1000 \fBby the DCE and the DTE\fR \v'1P' .ce 0 .PP This appendix is provided for explanatory purposes and indicates the bit patterns that will exist in the physical layer for some of the unnumbered frames. It is included for the purpose of furthering the understanding of the transparency mechanism and the frame check sequence implementation. .sp 1P .RT .PP I.1 The following are examples of the bit patterns that will be transmitted by a DCE for some unnumbered frames. .sp 1P .RT .sp 1P .LP \fIExample 1 : SABM command frame with address = A, P = 1\fR \v'3p' .sp 9p .RT .LP First bit transmitted Last bit transmitted \fB\(da\fR \fB\(da\fR .sp 1P .LP 0111\ 1110 1100\ 0000 1111\ 1(0\|\u3\d\u)\d)100 1101\ 1010\ 0011\ 0111 0111\ 1110 Flag Address\ =\ A SABM(P\ =\ 1) Frame check sequence Flag \fIExample 2 : UA response frame with address = B, F = 1\fR \v'3p' .sp 9p .RT .LP First bit transmitted Last bit transmitted \fB\(da\fR \fB\(da\fR .PP 0111\ 1110 1000\ 0000 1100\ 1110 1100\ 0001\ 1110\ 1010 0111\ 1110 Flag Address\ =\ B UA(F\ =\ 1) Frame check sequence Flag I.2 The following are examples of the bit patterns that should be transmitted by a DTE for some unnumbered frames: .sp 1P .RT .sp 1P .LP \fIExample 1 : SABM command frame with address = B, P = 1\fR \v'3p' .sp 9p .RT .LP First bit transmitted Last bit transmitted \fB\(da\fR \fB\(da\fR .sp 1P .LP 0111\ 1110 1000\ 0000 1111\ 1(0\|\u3\d\u)\d)100 1101\ 0111\ 11(0\|\u3\d\u)\d)11\ 1011 0111\ 1110 Flag Address\ =\ B SABM(P\ =\ 1) Frame check sequence Flag \fIExample 2 : UA response frame with address = A, F = 1\fR \v'3p' .sp 9p .RT .LP First bit transmitted Last bit transmitted \fB\(da\fR \fB\(da\fR .LP 0111\ 1110 1100\ 0000 1100\ 1110 1100\ 1100\ 0010\ 0110 0111\ 1110 Flag Address\ =\ A UA(F\ =\ 1) Frame check sequence Flag .sp 2 \u3\d\u)\d Zero inserted for transparency. .bp .LP .PS 10 .ce 1000 APPENDIX\ II .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBAn explanation of how the values for N1\fR .sp 1P .RT .ce 0 .ce 1000 \fBin Section 2.4.8.5 are derived\fR .ce 0 .LP \fIIntroduction\fR .sp 1P .RT .PP This appendix provides a description of how the values given for the link level parameter\ N1 in \(sc\ 2.4.8.5 are derived. .RT .sp 1P .LP \fIDTE N1\fR .sp 9p .RT .PP Section 2.4.8.5 states that for universal operation a DTE should support a value of DTE\ N1 which is not less than 1080\ bits (135\ octets). .PP For universal operation, a DTE must be capable of accepting at least the largest packet that can be transmitted across a DTE/DCE interface when no options apply. This implies that the DTE may choose not to support, for example, any optional facilities for universal operations, but must support, for example, a data packet using the standard default packet size. Therefore, the determining factor for the maximum value of N1 that a DTE must support is the standard default packet size of a data packet rather than the size of a call setup packet. Thus, for universal operation a DTE should support a value of DTE\ N1 which is not less than 135\ octets, derived as shown in the following table. .RT .ce \fBH.T. [T69.25]\fR .ce TABLE\ II\(hy1/X.25 .ce \fBDerivation of the maximum value of N1 for a DTE\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(150p) | cw(78p) . Name of the field T{ Length of the field (octets) T} _ .T& lw(150p) | cw(78p) . Packet header (Layer 3) 3 _ .T& lw(150p) | cw(78p) . User data (Layer 3) 128 _ .T& lw(150p) | cw(78p) . Address (Layer 2) 1 _ .T& lw(150p) | cw(78p) . Control (Layer 2) 1 _ .T& lw(150p) | cw(78p) . FCS (Layer 2) 2 _ .T& lw(150p) | cw(78p) . TOTAL T{ 135 \fINote\fR \ \(em\ A DTE will need to support larger values of N1 when optional facilities will apply. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable II\(hy1/X.25 [T69.25], p.\fR .sp 1P .RT .ad b .RT .sp 1P .LP \fIDCE N1\fR .sp 9p .RT .PP Section 2.4.8.5 also states that all network shall offer to a DTE which requires it a value of DCE\ N1 which is greater than or equal to 2072\ bits (259\ octets) plus the length of the address field plus the length of the control field and plus the length of the FCS field. .PP When the maximum length of the data field of a data packet supported is less than or equal to the standard default value of 128\ octets, the determining factor (for the value of DCE\ N1) is the clear request packet rather than the data packet. Therefore, the network shall offer to a DTE, a value of DCE\ N1 which is not less than 263 or 264\ octets, derived as shown in the following table. .bp .RT .ce \fBH.T. [T70.25]\fR .ce TABLE\ II\(hy2/X.25 .ce \fBDerivation of the minimum value of N1 for a DCE\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(150p) | cw(78p) . Name of the field T{ Length of the field (octets) T} _ .T& lw(150p) | cw(78p) . Header (Layer 3) 3 _ .T& lw(150p) | cw(78p) . Clearing cause (Layer 3) 1 _ .T& lw(150p) | cw(78p) . Diagnostic code (Layer 3) 1 _ .T& lw(150p) | cw(78p) . DTE address length (Layer 3) 1 _ .T& lw(150p) | cw(78p) . DTE address(es) (Layer 3) 15 _ .T& lw(150p) | cw(78p) . Facility length (Layer 3) 1 _ .T& lw(150p) | cw(78p) . Facilities (Layer 3) 109 _ .T& lw(150p) | cw(78p) . Clear user data (Layer 3) 128 _ .T& lw(150p) | cw(78p) . Layer 3 \(em TOTAL 259 _ .T& lw(150p) | cw(78p) . Address (Layer 2) 1 _ .T& lw(150p) | cw(78p) . Control (Layer 2) 1 or 2* _ .T& lw(150p) | cw(78p) . Multilink procedure 2** _ .T& lw(150p) | cw(78p) . FCS (Layer 2) 2 _ .T& lw(150p) | lw(78p) . TOTAL T{ \fBor\fR 263 or 264* or 265** or 266*, ** *\fB*\fR \ If level 2 modulo 128 is supported. .parag **\ Multilink procedures (MLP) are supported. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable II\(hy2/X.25 [T70.25], p.\fR .sp 1P .RT .ad b .RT .PP .sp 2 When the maximum length of the user data field of a data packet supported is greater than the standard default value of 128\ octets, the determining factor (for the value of DCE\ N1) is the data packet rather than the clear request packet. Therefore, the network shall offer to a DTE, a value of DCE\ N1 which is greater than or equal to: .LP [the maximum length of the data packet + .LP the length of the address field (Layer 2) + .LP the length of the control field (Layer 2) + .LP the length of the FCS field (Layer 2)]. .bp .sp 1P .LP \fIGeneral DCE N1 calculations\fR .sp 9p .RT .PP The following table indicates the value of DCE N1 for each possible case. The table shows for each case, whether .RT .LP a) Layer 2 Modulo 128 is used, .LP b) Multilink Procedures are used, .LP c) Layer 3 Modulo 128 is used, and/or .LP d) the maximum length of the data field (p) in a data packet is greater than or equal to 256\ octets. .LP .sp 1 .ce \fBH.T. [T71.25]\fR .ce TABLE\ II\(hy3/X.25 .ce \fBVarious cases and corresponding minimum\fR .ce \fBN1 values for a DCE\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(30p) | cw(30p) | cw(30p) | cw(30p) | cw(108p) . Layer 2 Modulo 128 MLP Layer 3 Modulo 128 \fIp\fR \(>=" 256 DCE N1 (octets) _ .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(108p) . 259 + 4* _ .T& lw(30p) | cw(30p) | lw(30p) | lw(30p) | lw(108p) . X 259 + 4* + 2***** _ .T& lw(30p) | cw(30p) | lw(30p) | cw(30p) | lw(108p) . X p + 3** + 4* _ .T& lw(30p) | cw(30p) | lw(30p) | cw(30p) | lw(108p) . X X p + 3** + 4* + 2***** _ .T& lw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X 259 + 4* _ .T& lw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X 259 + 4* + 2***** _ .T& lw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X p + 3** + 1*** + 4* _ .T& lw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X X p + 3** + 1*** + 4* + 2***** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X 259 + 4* + 1**** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X 259 + 4* + 1**** + 2***** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X p + 3** + 1**** + 4* _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X X p + 3** + 1**** + 4* + 2***** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X 259 + 4* + 1**** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X X 259 + 4* + 1**** + 2***** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X X p + 3** + 1*** + 4* + 1**** _ .T& cw(30p) | cw(30p) | cw(30p) | cw(30p) | lw(108p) . X X X X T{ p + 3** + 1*** + 4* + 1**** + 2***** * The number of octets for modulo 128 layer 2 frame fields. .parag ** The number of octets for layer 3 packet header fields. .parag *** Additional octet for layer 3 modulo 128 operations. .parag **** Additional octet for layer 2 modulo 128 operations. .parag ***** Additional octets for MLP support. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTable II\(hy3/X.25 [T71.25], p.\fR .sp 1P .RT .ad b .RT .LP .bp .ce 1000 APPENDIX\ III .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBExamples of\fR \fBmultilink resetting procedures\fR .sp 1P .RT .ce 0 .LP III.1 \fIIntroduction\fR .sp 1P .RT .PP The following examples illustrate application of the multilink resetting procedures in the case of: .RT .LP a) MLP reset initiated by either the DCE or the DTE; and .LP b) MLP reset initiated by both the DCE and the DTE simultaneously. .sp 1P .LP III.2 \fIMLP reset initiated by either the DCE or the DTE\fR .sp 9p .RT .LP .rs .sp 40P .ad r \fBFigure III\(hy1/X.25, p.\fR .sp 1P .RT .ad b .RT .LP .bp .sp 1P .LP III.3 \fIMLP reset initiated by both the DCE and the DTE simultaneously\fR .sp 9p .RT .LP .rs .sp 47P .ad r \fBFigure III\(hy2/X.25, p.\fR .sp 1P .RT .ad b .RT .LP .bp .ce 1000 APPENDIX\ IV .ce 0 .ce 1000 (to Recommendation X.25) .sp 9p .RT .ce 0 .ce 1000 \fBInformation on addresses in call set\(hyup\fR .sp 1P .RT .ce 0 .ce 1000 \fBand clearing packets\fR .ce 0 .LP IV.1 \fIMain address and complementary address\fR .sp 1P .RT .PP A DTE address may include two components: a main address and a complementary address. .RT .sp 1P .LP IV.1.1 \fIMain address\fR .sp 9p .RT .PP When the A bit is set to 0, the main address is conforming to formats described in Recommendations\ X.121 and X.301 (including possible prefixes and/or escape codes). .PP When the A bit is set to 1, the main address is as described in Figure\ IV\(hy1/X.25. .RT .LP .rs .sp 7P .ad r \fBFigure IV\(hy1/X.25 [T72.25], p.\fR .sp 1P .RT .ad b .RT .PP The possible values and the semantic of these subfields are described in \(sc\ 5.2.1.2.2. .sp 1P .LP IV.1.2 \fIComplementary address\fR .sp 9p .RT .PP A complementary address is an address information additional to that defined in X.121 (see \(sc\ 6.8.1 of Recommendation\ X.301). .PP Some networks allow the DTE to include a complementary address. When a complementary address is permitted by the network, the DTE is not obliged to use this complementary address. The complementary address may be as long as possible in considering the maximum value of the DTE address length fields defined in \(sc\(sc\ 5.2.1.1.1 and 5.2.1.2.1. .PP When a complementary address is contained in a DTE address field of a packet transmitted by the network to the DTE, this complementary address is always passed transparently from the remote DTE: it means that the network never creates a complementary address from itself. .PP When a complementary address is invoked in the following sections, it is supposed that the network supports the use of complementary addresses. .PP When the A bit is set to 1 and a complementary address is present alone (i.e.,\ without main address) in DTE address field, it is preceded by the type of address and numbering plan identification subfields. .RT .sp 1P .LP IV.2 \fIAddresses in call request packet\fR .sp 9p .RT .PP In \fIcall request\fR packet, the called DTE address should be provided by the DTE except when the \fIbilateral closed user group selection\fR is provided in the facility field (see \(sc\ 6.15.3). Depending on the called network and the DTE, this called DTE address may be made of a main address then a complementary address, or of a main address alone. .bp .PP Depending on the network, the DTE may have the following possibilities for the called DTE address: .RT .LP i) The DTE may include either no calling DTE address, or a main address optionally followed by a complementary address. When a calling DTE address is provided by the DTE, the network is required to check its validity. If the calling DTE address is not valid, the network may either replace this invalid calling DTE address by a valid one, or clear the call. If the \fIhunt\fR \fIgroup\fR facility has been subscribed to by the calling DTE (see \(sc\ 6.24) and a specific address has been assigned to the calling DTE/DCE interface, the main address provided by the calling DTE may be the hunt group address or the specific address. .LP \fINote\fR \ \(em\ In this later case, some networks do not allow the calling DTE to indicate the hunt group address, but only the specific address. .LP ii) The DTE may include either no calling DTE address, or a calling complementary address. In this last case, when the A\ bit is set to 1, this complementary address shall be preceded by the type of address and numbering plan identification subfields. .sp 1P .LP IV.3 \fIAddresses in incoming call packets\fR .sp 9p .RT .PP In \fIincoming call\fR packet, the calling DTE address should be provided by the DCE except when the \fIbilateral closed user group selection\fR is provided in the facility field (see \(sc\ 6.15.3) or in one case described in \(sc\ 6.28. This calling DTE address always includes a main address. This main address is followed by a calling complementary address if such a complementary address had been provided by the calling DTE in the \fIcall request\fR packet (see \(sc\ IV.2), and the calling DTE address was considered as valid by the network at the calling DTE side. If the \fIhunt group\fR facility has been subscribed to by the calling DTE (see \(sc\ 6.24) and a specific address has been assigned to the calling DTE/DCE interface, the main address indicated in the calling DTE address may be the hunt group address (only if the calling DTE had indicated either its hunt group address or no main address, in the calling DTE address field of the \fIcall request\fR packet) or the specific address (regardless of the contents of the calling DTE address field in the \fIcall request\fR packet). .PP Depending on the network, the called DTE address may be made of: .RT .LP i) The main called address optionally followed by the called complementary address if this complementary address had been provided by the calling DTE. If the \fIhunt group\fR facility has been subscribed to by the called DTE (see \(sc\ 6.24) and a specific address has been assigned to the called DTE/DCE interface, the main address indicated in the called DTE address field may be the hunt group address (only if the calling DTE had indicated this hunt group address or no main address, in the calling DTE address field of the \fIcall\fR \fIrequest\fR packet) or the specific address (regardless of the contents of the calling DTE address field in the \fIcall request\fR packet). .LP ii) The called complementary address alone when provided by the calling DTE, or nothing if the calling DTE had not provided this called complementary address. When a called complementary address is alone and the A\ bit is set to 1, the called complementary is preceded by the type of address and numbering plan identification subfields. .sp 1P .LP IV.4 \fIAddresses in call accepted packets\fR .sp 9p .RT .PP Some networks do not allow any DTE addresses in \fIcall accepted\fR packets except a called DTE address in conjunction with the \fIcalled line\fR \fIaddress modified notification\fR facility when supported by the network and provided by the DTE. .PP Some other networks allow the DTE to include in the \fIcalled accepted\fR packet none, one or both of the two DTE addresses. When provided by the DTE, the calling DTE address in the \fIcall accepted\fR packet should be the same as the calling DTE address in the \fIincoming call\fR packet. When provided by the DTE, the called DTE address in the \fIcalled accepted\fR packet should be the same as the called DTE address in the \fIincoming call\fR packet, except if the \fIcalled\fR \fIline address modified notification\fR facility (when supported by the network) is also provided by the DTE. .bp .PP When the \fIcalled line address modified notification\fR facility (when supported by the network) is provided by the DTE in the \fIcall accepted\fR packet, the called DTE address may be made of one of the following exclusive network\(hydependent possibilities: .RT .LP i) A main DTE address identical to that of the \fIincoming call\fR packet, followed by a called complementary address different from that of the \fIincoming call\fR packet, or another main DTE address valid for the DTE/DCE interface optionally followed by any complementary address. .LP ii) A called complementary address, different from that which was possibly present in the called DTE address of the \fIincoming call\fR packet. In this case, when the A\ bit is set to 1, the called complementary address shall be preceded by the type of address and numbering plan identification subfields. .sp 1P .LP IV.5 \fIAddresses in call connected packets\fR .sp 9p .RT .PP Some networks do not provide any DTE address in \fIcall connected\fR packets except a called DTE address in conjunction with the \fIcalled line\fR \fIaddress modified notification\fR facility. .PP Some other networks always provide both DTE addresses in \fIcall\fR \fIconnected\fR packets. .PP Some other networks provide a DTE address in a \fIcall connected\fR packet only if this DTE address was present in the \fIcall ccepted\fR packet or in conjunction with the \fIcalled line address modified notification\fR facility. .PP In any case, when an address is provided by the network in the \fIcall\fR \fIconnected\fR packet, this address should be the same as that in the \fIcall\fR \fIrequest\fR packet except when the \fIcalled line address modified notification\fR facility is present in the facility field: in this case, the called DTE address contains always a main address optionally followed by a complementary address. .RT .sp 1P .LP IV.6 \fIAddresses in clear request packets\fR .sp 9p .RT .PP No DTE address is permitted in \fIclear request\fR packets except a called DTE address when the \fIcalled line address modified notification\fR facility (see \(sc\ 6.26) is used in this packet. In this case, the \fIclear request\fR packet is transmitted as a direct response to the \fIincoming call\fR packet and the called DTE address may be made of one of the following network\(hydependent possibilities: .RT .LP i) A main DTE address identical to that of the \fIincoming call\fR packet, followed by a called complementary address different from that of the \fIincoming call\fR packet, or another main DTE address valid for the DTE/DCE interface. .LP ii) A called complementary address, different from that which was possibly present in the called DTE address of the \fIincoming call\fR packet. In this case, when the A\ bit is set to 1, the called complementary address shall be preceded by the type of address and numbering plan identification subfields. .sp 1P .LP IV.7 \fIAddresses in clear indication packets\fR .sp 9p .RT .PP No DTE address is permitted in \fIclear indication\fR packets except when the \fIcalled line address modified notification\fR facility (see \(sc\ 6.26) is used in this packet. In this case, the \fIclear indication\fR packet is transmitted as a direct response to the \fIcall request\fR packet and the called DTE address contains always a main address optionally followed by a complementary address. .RT .sp 1P .LP IV.8 \fIAddresses in clear confirmation packets\fR .sp 9p .RT .PP DTE addresses are not present in \fIclear confirmation\fR packets. .RT .sp 1P .LP IV.9 \fIAddresses in call redirection and call deflection related\fR \fIfacilities\fR .sp 9p .RT .PP The alternative DTE address, indicated at subscription\(hytime (for the \fIcall redirection\fR facility) or in the \fIcall deflection selection\fR facility of the \fIclear request\fR packet (see \(sc\(sc\ 6.25.1 and 6.25.2), is composed of a main address optionally followed by a complementary address. .PP If a called complementary address was present in the \fIcall request\fR packet, some networks may add this called complementary address after the alternative DTE address. .RT .LP .bp .LP .bp