700 lines
19 KiB
Plaintext
700 lines
19 KiB
Plaintext
.\" $NetBSD: trans_serv.nr,v 1.2 1998/01/09 06:34:34 perry Exp $
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.\"
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.NC "Transport Service Interface"
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.sh 1 "General"
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.pp
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It is assumed that the reader is acquainted with the
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set of system calls and library routines that
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compose the
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Berkeley
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Unix interprocess communication service (IPC).
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To every extent possible
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the ARGO transport service is provided by the same IPC mechanisms
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that support
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the transport-level services
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included in the
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AOS distribution.
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In some instances, the interface
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provided by AOS does not support
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the services required by ISO 8073,
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so system calls were added to support these services.
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It is felt that this is superior to modifying
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existing system calls, in order to avoid the
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recoding of existing Unix utilities.
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.pp
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What follows is a description of the system calls
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that are used to provide the transport service.
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According to Unix custom,
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the return value of a system call is 0
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if the call succeeds and -1 if
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the call fails for any reason.
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In the latter case,
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the global variable
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\fIerrno\fR contains more information
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about the error that caused the failure.
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In the descriptions of all the system calls for which
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this custom is followed,
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the return value is named
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\fIstatus\fR.
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.sh 1 "Connection establishment"
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.pp
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Establishing a TP connection is similar to
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establishing a connection using any other
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transport protocol supported by Unix.
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The same system calls are used, and the passive open
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is required.
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Some of the parameters to the system calls differ.
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.pp
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The following call creates a communication endpoint called a
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\fIsocket\fR.
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It returns
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a positive integer called a
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\fIsocket descriptor\fR,
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which
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will be a parameter in all communication primitives.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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s = socket( af, type, protocol )
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.T&
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l l l.
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+int+s,af,type,protocol;
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.TE
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\fR
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.)b
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.pp
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The \fIaf\fR parameter describes the format of addresses
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used in this communication.
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Existing formats include AF_INET (DoD Internet addresses),
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AF_PUP (Xerox PUP-I Internet addresses), and AF_UNIX
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(addresses are Unix file names, for intra-machine IPC only).
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TP runs in either the Internet domain or the ISO domain (AF_ISO).
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When using the Internet domain, the network layer is the DoD Internet IP
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with Internet-style addresses. The ISO domain uses the ISO
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network service and ISO-style addresses\**.
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.(f
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\**ISO/DP 8348/DAD2 Addendum to the Network
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Service Definition Covering Network Layer Addressing.
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.)f
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Regardless of the address family used, an address takes the
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general form,
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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struct sockaddr {
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.T&
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l l l l.
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+u_char+sa_len;+/* length of sockaddr */
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+u_char+sa_family;+/* address family */
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+char+sa_data[14];+/* space for an address */
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}+
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.TE
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\fR
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.)b
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.lp
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.i
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A sockaddr is no longer required to be precisely 16 bytes long.
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The allocation of 14 bytes for sa_data is intended for backwards
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compatibility.
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.r
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.sp 1
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When viewed as an Internet address, it takes the form
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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struct sockaddr_in {
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.T&
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l l l l.
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+u_char+sin_len;+/* address length */
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+u_char+sin_family;+/* address family */
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+u_short+sin_port;+/* internet port */
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+struct in_addr+sin_addr;+/* network addr A.B.C.D */
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+char+sin_zero[8];+/* unused */
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}
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.TE
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\fR
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.)b
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.sp 1
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When viewed as an ISO address, as supplied by the
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university of wisconsin, it takes the form
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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struct sockaddr_iso {
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.T&
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l l l l.
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+u_char+siso_len;+/* address length */
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+u_char+siso_family;+/* address family */
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+u_short+siso_tsuffix;+/* transport suffix */
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+struct iso_addr+siso_addr;+/* ISO NSAP addr */
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+char+siso_zero[2];+/* unused */
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}
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.TE
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\fR
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.)b
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The address described by a \fIsockaddr_iso\fR structure
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is a TSAP-address (transport service access point address).
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It is made of an NSAP-address (network service access point address)
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and a TSAP selector (also called a transport suffix or
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transport selector, hereafter called a TSEL).
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The structure \fIsockaddr_iso\fR contains a 2-byte TSEL.
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This is for compatibility with Internet addressing.
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ARGO supports
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TSELs of length 1-64 bytes.
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TSELs of any length other than 2
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are called \*(lqextended TSELs\*(rq.
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They are described in detail in the section \fB\*(lqExtended TSELs\*(rq\fR.
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If extended TSELs are not requested, 2-byte TSELs are used by default.
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.pp
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Refer to Chapter Five for more information about ISO NSAP-addresses.
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.pp
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.i
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It is our intent at Berkeley to revamp the sockaddr_iso
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to use a more natural and uniform model, for ISO addresses.
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We cannot guarantee this modification to be complete by the
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time we are ready to have something for NIST to test.
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We hope to remove this notion of extended TSEL's as soon as
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possible, certainly by formal beta testing of 4.4.
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.r
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Since sockaddr can be 108 bytes long without breaking anything
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in the current Berkeley kernel, we should be able to eliminate
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extended TSEL's entirely by
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providing a sockaddr_iso along the lines of:
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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struct sockaddr_iso {
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.T&
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l l l l.
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+u_char+siso_len;+/* address length */
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+u_char+siso_family;+/* address family */
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+u_char+siso_slen;+/* session suffix length */
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+u_char+siso_tlen;+/* transport suffix length */
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+u_char+siso_nlen;+/* nsap length */
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+char+siso_data[22];+/* minimum nsap + tsel */
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}
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.TE
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\fR
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.)b
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.pp
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The \fItype\fR parameter in the \fIsocket()\fR call
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distinguishes
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datagram protocols, stream protocols, sequenced
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packet protocols, reliable datagram protocols, and
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"raw" protocols (in other words, the absence of a transport protocol).
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Unix provides manifest named constants for each of these types.
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TP supports the sequenced packet protocol abstraction, to which
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the manifest constant SOCK_SEQPACKET applies.
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.pp
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The \fIprotocol\fR
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parameter is an integer that identifies the protocol to be used.
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Unix provides a database of protocol names and their associated
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protocol numbers.
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Unix also provides user-level tools
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for searching the database.
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The tools take the form of library routines.
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A protocol number for TP has been chosen
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by the Internet NIC to allow TP to run in the Internet domain, and this
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has been added to the Unix network protocol database.
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The standard Internet database tools that serve TCP users
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can
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also serve user of TP
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in the Internet domain, if the TP protocol number is added to the
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proper Internet database file,
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\fC/etc/protocols\fR.
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This change must be made for TP to run in either the Internet or
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in the ISO domain.
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The ARGO package contains a set of tools and a database
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for use with TP in the ISO domain.
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This set of tools is described in the manual pages
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\fIisodir(5)\fR and
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\fIisodir(3)\fR.
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.pp
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When a socket is created, it is not given an address.
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Since a socket cannot be reached by a remote entity unless it has an address,
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the user must request that a socket be given an address by
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using the \fIbind()\fR system call:
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = bind( s, addr, addrlen )
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.T&
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l l l.
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+int+s;
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+struct sockaddr+*addr;
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+int+addrlen;
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.TE
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\fR
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.)b
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.pp
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The address is expected to be in the format specified by the
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\fIaf\fR parameter to the \fIsocket()\fR
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call that yielded the socket descriptor \fIs\fR.
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If the user
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passes an address parameter with a zero-valued transport suffix,
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the transport layer
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assigns an unused 2-byte transport selector.
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This is a 4.3 Unix convention; it is not part of any ISO standard.
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.pp
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The \fIconnect()\fR system call effects an active open.
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It is used to establish a connection with an entity that is
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passively waiting for connection requests, and whose
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transport address is known.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = connect( s, addr, addrlen )
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.T&
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l l l.
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+int+s;
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+struct sockaddr+*addr;
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+int+addrlen;
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.TE
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\fR
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.)b
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.pp
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The first parameter is a socket descriptor.
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The \fIaddr\fR parameter is a transport address in the format
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specified by the \fIaf\fR parameter to the \fIsocket()\fR
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call that yielded the socket descriptor \fIs\fR.
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.pp
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A passive open is accomplished with two system calls,
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\fIlisten()\fR followed by \fIaccept()\fR.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = listen( s, queuelen )
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.T&
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l l l.
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+int+s;
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+int+queuelen;
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.TE
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\fR
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.)b
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.pp
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The \fIqueuelen\fR argument specifies the maximum
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number of pending connection
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requests that will be queued for acceptance by this user.
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Connections are then accepted by the
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system call \fIaccept()\fR.
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There is no way to refuse connections.
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The functional equivalent of connection
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refusal is accomplished by accepting a connection and immediately
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disconnecting.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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new_s = accept( s, addr, addrlen )
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.T&
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l l l.
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+int+new_s, s;
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+struct sockaddr+*addr;
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+int+addrlen;
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.TE
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\fR
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.)b
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.pp
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The \fIaccept()\fR call completes the connection
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establishment. If a connection request from a prospective peer
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is pending on the socket described by \fIs\fR, it is removed and
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a new socket is created for use with this connection.
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A socket descriptor for the new socket is returned by the
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system call.
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If no connection requests are pending, this call blocks.
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If the \fIaccept()\fR call fails, -1 is returned.
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The transport address of the entity requesting the connection
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is returned in the \fIaddr\fR parameter, and the length
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of the address is returned in the \fIaddrlen\fR parameter.
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The address associated with the new socket is inherited
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from the socket on which the \fIlisten()\fR and \fIaccept()\fR were performed.
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.pp
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It is possible for the \fIaccept()\fR call to be interrupted
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by an asynchronous event such as the arrival of expedited
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data.
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When system calls are interrupted, Unix returns the value -1
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to the caller and puts the constant
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EINTR in the global variable \fIerrno\fR.
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This can create problems with the system call \fIaccept()\fR.
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In the case of incoming expedited data, the interruption does
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not indicate a problem, but the data may have arrived before
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the caller has received the new socket descriptor, which is the
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socket descriptor on which the expedited data are to be received.
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In order to prevent this problem from occurring, the caller must
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prevent the issuance of asynchronous indications until the
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\fIaccept()\fR
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call has returned.
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Asynchronous indications are discussed below, in
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the section titled
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"Indications from the transport layer to the transport user".
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.pp
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It is possible to discover the
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address bound to a
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socket with the
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\fIgetsockname()\fR system call.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = getsockname( s, addr, addrlen )
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.T&
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l l l.
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+int+s;
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+struct sockaddr+*addr;
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+int+addrlen;
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.TE
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\fR
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.)b
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.pp
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If the socket has a peer, that is, it is connected,
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the system call
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\fIgetpeername()\fR
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is used to discover the peer's address.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = getpeername( s, addr, addrlen )
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.T&
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l l l.
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+int+s;
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+struct sockaddr+*addr;
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+int+addrlen;
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.TE
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\fR
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.)b
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.lp
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The names returned by
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\fIgetsockname()\fR and \fIgetpeername()\fR
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do not contain extended TSELs.
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Extended TSELs can be retrieved with
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the \fIgetsockopt()\fR and
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\fIsetsockopt()\fR system calls, described below.
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.pp
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Unix supports several protocol-independent options
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and protocol-specific options
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associated with sockets.
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These options can be inspected and changed by using
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the \fIgetsockopt()\fR and
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\fIsetsockopt()\fR system calls.
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = getsockopt( s, level, option, value, valuelen )
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.T&
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l l l.
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+int+s, level, option;
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+char+*value;
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+int+*valuelen;
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.TE
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\fR
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.)b
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.(b
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\fC
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.TS
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tab(+);
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l s s s.
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status = setsockopt( s, level, option, value, valuelen )
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.T&
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l l l.
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+int+s, level, option;
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+char+*value;
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+int+valuelen;
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.TE
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\fR
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.)b
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.pp
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The \fIlevel\fR argument may indicate
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either
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that this option applies to sockets or that it applies to
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a specific protocol.
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The constants SOL_SOCKET, SOL_TRANSPORT, and SOL_NETWORK
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are possible values for the \fIlevel\fR argument.
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The \fIoption\fR argument is an integer that identifies
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the option chosen.
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.\" LIST THE OPTIONS HERE
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The options available to TP users provide the
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user with the ability to control various TP protocol options
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including but not limited to
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TP class, TPDU size negotiated, TPDU format used,
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acknowledgment and retransmission strategies.
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For a detail list of the options, see the manual page \fItp(4p)\fR.
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.sh 1 "Extended TSELs"
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.pp
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ARGO supports TSELs
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of length 1 byte - 64 bytes for sockets bound to addresses in the
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AF_ISO address family.
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The ARGO user program uses the
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\fIgetsockopt()\fR
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and
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\fIsetsockopt()\fR
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system calls to
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discover and assign extended TSELs.
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.pp
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To create a socket with an extended TSEL,
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the process
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.ip \(bu 5
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opens a socket with \fCsocket(AF_ISO, SOCK_SEQPACKET, ISOPROTO_TP)\fR
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.ip \(bu 5
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binds an NSAP-address to the socket with \fIbind()\fR.
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The address bound may contain a 2-byte selector (\fIiso_tsuffix\fR).
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.ip \(bu 5
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uses \fIsetsockopt()\fR with the command TPOPT_MY_TSEL,
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to assign a TSEL to the socket.
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.ip \(bu 5
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calls \fIlisten(), connect()\fR, or any other appopriate system calls
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to use the socket as desired.
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.lp
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To connect to a transport entity that is bound to a TSAP-address with
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an extended TSEL, the
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process
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.ip \(bu 5
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opens a socket with \fCsocket(AF_ISO, SOCK_SEQPACKET, ISOPROTO_TP)\fR
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.ip \(bu 5
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uses \fIsetsockopt()\fR, with the command TPOPT_PEER_TSEL,
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to assign a PEER TSEL to the socket.
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This TSEL is used by the transport entity
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for all subsequent connect requests made on this socket,
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unless the peer TSEL is changed by another call to
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\fIsetsockopt()\fR employing the command TPOPT_PEER_TSEL.
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.lp
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To discover the TSEL of the peer of a connected socket,
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the process
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.ip \(bu 5
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uses \fIgetsockopt()\fR with the command TPOPT_PEER_TSEL.
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.lp
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To discover the TSEL of socket's own address,
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the process
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.ip \(bu 5
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uses \fIgetsockopt()\fR with the command TPOPT_MY_TSEL.
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.sh 1 "Data transfer"
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.pp
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Earlier BSD-based systems have provided system calls for data transfer
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having bugs and semantics that are problematic for TP.
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These should be correct as presented in the test system.
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The problem was in the manner in which the kernel
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handled interrupted system calls.
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The send and receive primitives
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may be interrupted by signals.
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A signal is the mechanism used to indicate
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the presence of expedited data or out-of-band data.
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If the send primitive as interrupted before completion,
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the user could not determine how many octets of data were sent.
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All forms of the existing interface
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(\fIsend()\fR,
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\fIrecv()\fR,
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\fIsendmsg()\fR,
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\fIrecvmsg()\fR,
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\fIsendto()\fR,
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\fIrecvfrom()\fR,
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\fIwrite()\fR,
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\fIread\fR,
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\fIwritev()\fR,
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and \fIreadv()\fR system calls)
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return an octet count
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when the system call completes, and to return a short count
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if the system call is interrupted.
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.pp
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|
The system calls sendmsg and recvmsg
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have been revised to make them more convenient for receipt of
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out of band data.
|
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.(b
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|
\fC
|
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.TS
|
|
tab(+);
|
|
l s s s.
|
|
cc = sendmsg( s, msg, flags )
|
|
.T&
|
|
l l l.
|
|
+int+s;
|
|
+istruct msghdr+msg;
|
|
+unsigned int+flags;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
cc = recvmsg( s, msg, flags )
|
|
.T&
|
|
l l l.
|
|
+int+s;
|
|
+istruct msghdr+msg;
|
|
+unsigned int+flags;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
The reader should now consult the manual page for recvmsg
|
|
for an explanation of the elements of the msghdr structure,
|
|
and how the calls may be used to glean user-connection-request data.
|
|
.pp
|
|
The \fIflags\fR parameter serves several purposes.
|
|
The TP specification requires that TSDUs be unlimited in size.
|
|
System calls cannot pass unlimited amounts of data between the user
|
|
and the kernel, so
|
|
there cannot be a one-to-one correspondence between TSDUs and
|
|
system calls.
|
|
The \fIflags\fR
|
|
parameter is used to mark the end-of-TSDU on sending data.
|
|
When receiving,
|
|
TP sets this bit
|
|
in the flags element of the msghdr structure
|
|
when the end of a TSDU is consumed.
|
|
This way one TSDU can span several system calls.
|
|
It is possible for the peer to send an empty TPDU with the end-of-TSDU
|
|
flag set, in which case the transport user
|
|
may receive zero octets with the end-of-TSDU flag set.
|
|
.pp
|
|
The \fIflags\fR parameter also serves to distinguish data transfer primitives
|
|
from expedited data transfer primitives.
|
|
The flag bit MSG_OOB is provided for "out of band data" in the
|
|
DoD Internet protocols. It is also used to provide the expedited data service
|
|
of the ISO protocols.
|
|
The transport layer will deliver one expedited datum (there will be a
|
|
one-to-one correspondence between expedited TSDUs and XPD TPDUs)
|
|
at a time.
|
|
The user must receive the datum before the transport
|
|
layer will accept more expedited data.
|
|
Each expedited datum my contain up to 16 octets.
|
|
.pp
|
|
.sh 1 "Disconnection"
|
|
.pp
|
|
The \fIclose\fR system call will disconnect any association
|
|
between two TP entities.
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
status = close( s )
|
|
.T&
|
|
l l l.
|
|
+int+s;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
The argument \fIs\fR is a socket descriptor.
|
|
If a Unix user process terminates, Unix will close all files and
|
|
sockets associated with the process, which means all transport
|
|
connections associated with the process will be disconnected.
|
|
.sh 1 "Indications from the transport layer to the transport user"
|
|
.pp
|
|
The above set of system calls allows you to establish
|
|
a connection, transfer data, and disconnect.
|
|
The
|
|
presence or reception of expedited data is indicated
|
|
by TP setting the MSG_OOB bit in the flags element of the msg structure.
|
|
A disconnection initiated by the peer or by one of the
|
|
cooperating TP entities can be signalled by a control message,
|
|
although we have not yet implemented this.
|
|
.pp
|
|
The Unix signal mechanism may be used to provide these
|
|
service elements, as well.
|
|
When an expedited data TSDU arrives, the TP may interrupt
|
|
the user with a SIGURG signal ("urgent condition present on socket").
|
|
The user must have previously registered a procedure to handle
|
|
the signal by using the \fIsigvec()\fR system call or the
|
|
\fIsignal()\fR library routine provided for that purpose.
|
|
The signal handler takes the form
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
int sighandler( signal_number)
|
|
.T&
|
|
l l l.
|
|
+int+signal_number;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
The \fIsignal_number\fR argument will be the well-known constant SIGURG.
|
|
There are two reasons for
|
|
the transport layer to issue
|
|
a SIGURG:
|
|
expedited data
|
|
are present or
|
|
disconnection was initiated by a transport entity or by the peer.
|
|
Should the user have more than one transport connection open,
|
|
another system call is used to determine to which socket(s)
|
|
the urgent condition applies.
|
|
This is the \fIselect()\fR system call, described below.
|
|
.pp
|
|
When the SIGURG indicates a disconnection, there may be
|
|
user data from the peer present.
|
|
TP saves the disconnect data for the user to receive via the
|
|
\fIgetsockopt()\fR system call, or through the
|
|
.IR recvmsg ()
|
|
ancillary data mechanism.
|
|
.\"
|
|
.\"If the user does not receive the disconnect data before the
|
|
.\"reference timer expires, the data will be discarded and the
|
|
.\"socket will be closed.
|
|
.pp
|
|
Transport service users may use more than one transport
|
|
connection at a time.
|
|
The \fIselect()\fR system call facilitates this.
|
|
.(b
|
|
\fC
|
|
.TS
|
|
tab(+);
|
|
l s s s.
|
|
#include <sys/types.h>
|
|
+
|
|
nfound = select( num_to_scan, recvmask, sendmask,
|
|
+exceptmask, timeout )
|
|
.T&
|
|
l l l.
|
|
+int+nfound, num_to_scan;
|
|
+fd_set+*recvmask, *sendmask, *exceptmask;
|
|
+time+timeout;
|
|
.TE
|
|
\fR
|
|
.)b
|
|
.pp
|
|
This system call takes as parameters a set of masks
|
|
that specify a subset of the socket descriptors that are in
|
|
use by the user program.
|
|
\fISelect()\fR inspects the sockets to see if they have data
|
|
to be received, can service a send without blocking, or
|
|
have an exceptional condition pending, respectively.
|
|
The masks will be set upon return to indicate the socket descriptors
|
|
for which the respective conditions exist.
|
|
The \fInum_to_scan\fR argument limits the number of sockets that are
|
|
inspected.
|
|
The call will return within the amount of time given in the
|
|
\fItimeout\fR parameter, or, if the parameter is zero, \fIselect()\fR
|
|
will block indefinitely.
|
|
.\" FIGURE
|
|
.so ../wisc/figs/TS_primitives.nr
|
|
.pp
|
|
.CF
|
|
summarizes the mapping of the transport service primitives
|
|
to Unix facilities.
|