TP(4) NetBSD Kernel Interfaces Manual TP(4)
NAME
tp -- ISO Transport Protocol
SYNOPSIS
#include <sys/socket.h> #include <netiso/iso_errno.h> #include <netiso/tp_param.h> #include <netiso/tp_user.h> int socket([AF_INET, AF_ISO], SOCK_SEQPACKET, 0);
DESCRIPTION
The TP protocol provides reliable, flow-controlled, two-way transmission of data and record boundaries. It is a byte-stream protocol and is accessed according to the SOCK_SEQPACKET abstraction. The TP protocol makes use of a standard ISO address format, including a Network Service Access Point, and a Transport Service Entity Selector. Subclass 4 may make use of the Internet address format. Sockets using the TP protocol are either ``active'' or ``passive''. Active sockets initiate connections to passive sockets. By default TCP sockets are created active; to create a passive socket the listen(2) sys- tem call must be used after binding the socket with the bind(2) system call. Only passive sockets may use the accept(2) call to accept incoming connections. Only active sockets may use the connect(2) call to initiate connections. Passive sockets may ``underspecify'' their location to match incoming connection requests from multiple networks. This technique, termed ``wildcard addressing'', allows a single server to provide service to clients on multiple networks. To create a socket which listens on all networks, the NSAP portion of the bound address must be void (of length zero). The Transport Selector may still be specified at this time; if the port is not specified the system will assign one. Once a connection has been established the socket's address is fixed by the peer entity's location. The address assigned the socket is the address associated with the network interface through which packets are being transmitted and received. The ISO Transport Protocol implemented for AOS R2 at the University of Wisconsin - Madison, and modified for inclusion in the Berkeley Software Distribution, includes classes 0 and 4 of the ISO transport protocols as specified in the June 1986 version of IS 8073. Class 4 of the protocol provides reliable, sequenced, flow-controlled, two-way transmission of data packets with an alternative stop-and-wait data path called the "expedited data" service. Class 0 is essentially a null transport proto- col, which is used when the underlying network service provides reliable, sequenced, flow-controlled, two-way data transmission. Class 0 does not provide the expedited data service. The protocols are implemented as a single transport layer entity that coexists with the Internet protocol suite. Class 0 may be used only in the ISO domain. Class 4 may be used in the Internet domain as well as in the ISO domain. Two system calls were modified from the previous release of the Berkeley Software Distribution to permit the support of the end-of-transport-ser- vice-data-unit (EOTSDU) indication, and for the receipt and transmission of user connect, confirm, and disconnect data. See sendmsg(2) and recvmsg(2), and further discussion below for the formats of the data in the ancillary data buffer. If the EOTSDU is not needed, the normal read(2) and write(2) system calls may be used. Through the getsockopt(2) and setsockopt(2) system calls, TP supports several options to control such things as negotiable options in the pro- tocol and protocol strategies. The options are defined in <netiso/tp_user.h>, and are described below. In the tables below, the options marked with a pound sign `#' may be used with setsockopt(2) after a connection is established. Others must be used before the connection is established, in other words, before calling connect(2) or accept(2). All options may be used with getsockopt(2) before or after a connection is established. TPOPT_CONN_DATA (char *) [none] Data to send on connect(2). The passive user may issue a getsockopt(2) call to retrieve a connection request's user data, after having done the accept(2) system call without implying confirmation of the con- nection. The data may also be retrieved by issuing a recvmsg(2) request for ancillary data only, without implying con- firmation of the connection. The returned cmsghdr will contain SOL_TRANSPORT for the cmsg_level and TPOPT_CONN_DATA for cmsg_type. TPOPT_DISC_DATA # (char *) [none] Data to send on close(2). Disconnect data may be sent by the side initiating the close but not by the pas- sive side ("passive" with respect to the closing of the connection), so there is no need to read discon- nect data after calling close(2). This may be sent by a setsockopt(2) system call, or by issuing a sendmsg(2) request specifying ancillary data only. The user-provided cmsghdr must contain SOL_TRANSPORT for cmsg_level and TPOPT_DISC_DATA for cmsg_type. Sending of disconnect data will in of itself tear down (or reject) the connection. TPOPT_CFRM_DATA # (char *) [none] Data to send when confirming a connection. This may also be sent by a setsockopt(2) system call, or by issuing a sendmsg(2) request, as above. Sending of connect confirm data will cause the connection to be confirmed rather than rejected. TPOPT_PERF_MEAS # Boolean. When true, performance measurements will be kept for this connection. When set before a connection is established, the active side will use a locally defined parameter on the connect request packet; if the peer is another ARGO implementation, this will cause performance measurement to be turned on on the passive side as well. TPOPT_PSTATISTICS No associated value on input. On output, struct tp_pmeas. This command is used to read the performance statis- tics accumulated during a connection's lifetime. It can only be used with getsockopt(2). The structure it returns is described in <netiso/tp_stat.h>. TPOPT_FLAGS unsigned integer. [0x0] This command can only be used with getsockopt(2). See the description of the flags below. TPOPT_PARAMS struct tp_conn_param Used to get or set a group parameters for a connec- tion. The struct tp_conn_param is the argument used with the getsockopt(2) or setsockopt(2) system call. It is described in <netiso/tp_user.h>. The fields of the tp_conn_param structure are described below. Values for TPOPT_PARAMS: p_Nretrans nonzero short integer [1] Number of times a TPDU will be retransmitted before the local TP entity closes a connection. p_dr_ticks nonzero short integer [various] Number of clock ticks between retransmissions of discon- nect request TPDUs. p_dt_ticks nonzero short integer [various] Number of clock ticks between retransmissions of data TPDUs. This parameter applies only to class 4. p_cr_ticks nonzero short integer [various] Number of clock ticks between retransmissions of connec- tion request TPDUs. p_cc_ticks nonzero short integer [various] Number of clock ticks between retransmissions of connec- tion confirm TPDUs. This parameter applies only to class 4. p_x_ticks nonzero short integer [various] Number of clock ticks between retransmissions of expe- dited data TPDUs. This parameter applies only to class 4. p_sendack_ticks nonzero short integer [various] Number of clock ticks that the local TP entity will wait before sending an acknowledgment for normal data (not applicable if the acknowledgement strategy is TPACK_EACH). This parameter applies only to class 4. p_ref_ticks nonzero short integer [various] Number of clock ticks for which a reference will be con- sidered frozen after the connection to which it applied is closed. This parameter applies to classes 4 and 0 in the ARGO implementation, despite the fact that the frozen reference function is required only for class 4. p_inact_ticks nonzero short integer [various] Number of clock ticks without an incoming packet from the peer after which TP close the connection. This parameter applies only to class 4. p_keepalive_ticks nonzero short integer [various] Number of clock ticks between acknowledgments that are sent to keep an inactive connection open (to prevent the peer's inactivity control function from closing the con- nection). This parameter applies only to class 4. p_winsize short integer between 128 and 16384. [4096 bytes] The buffer space limits in bytes for incoming and outgo- ing data. There is no way to specify different limits for incoming and outgoing paths. The actual window size at any time during the lifetime of a connection is a function of the buffer size limit, the negotiated maxi- mum TPDU size, and the rate at which the user program receives data. This parameter applies only to class 4. p_tpdusize unsigned char between 0x7 and 0xd. [0xc for class 4] [0xb for class 0] Log 2 of the maximum TPDU size to be negotiated. The TP standard (ISO 8473) gives an upper bound of 0xd for class 4 and 0xb for class 0. The ARGO implementation places upper bounds of 0xc on class 4 and 0xb on class 0. p_ack_strat TPACK_EACH or TPACK_WINDOW. [TPACK_WINDOW] This parameter applies only to class 4. Two acknowledg- ment strategies are supported: TPACK_EACH means that each data TPDU is acknowledged with an AK TPDU. TPACK_WINDOW means that upon receipt of the packet that represents the high edge of the last window advertised, an AK TPDU is generated. p_rx_strat 4 bit mask [TPRX_USE_CW | TPRX_FASTSTART] over connec- tionless network protocols] [TPRX_USE_CW over connec- tion-oriented network protocols] This parameter applies only to class 4. The bit mask may include the following values: TPRX_EACH: When a retransmission timer expires, retrans- mit each packet in the send window rather than just the first unacknowledged packet. TPRX_USE_CW: Use a "congestion window" strategy borrowed from Van Jacobson's congestion window strategy for TCP. The congestion window size is set to one whenever a retransmission occurs. TPRX_FASTSTART: Begin sending the maximum amount of data permitted by the peer (subject to availability). The alternative is to start sending slowly by pretending the peer's window is smaller than it is, and letting it slowly grow up to the peer window's real size. This is to smooth the effect of new connections on a congested network by preventing a transport connection from sud- denly overloading the network with a burst of packets. This strategy is also due to Van Jacobson. p_class 5 bit mask [TP_CLASS_4 | TP_CLASS_0] Bit mask including one or both of the values TP_CLASS_4 and TP_CLASS_0. The higher class indicated is the pre- ferred class. If only one class is indicated, negotia- tion will not occur during connection establishment. p_xtd_format Boolean. [false] Boolean indicating that extended format is negotiated. This parameter applies only to class 4. p_xpd_service Boolean. [true] Boolean indicating that the expedited data transport service will be negotiated. This parameter applies only to class 4. p_use_checksum Boolean. [true] Boolean indicating the use of checksums will be negoti- ated. This parameter applies only to class 4. p_use_nxpd Reserved for future use. p_use_rcc Reserved for future use. p_use_efc Reserved for future use. p_no_disc_indications Boolean. [false] Boolean indicating that the local TP entity will not issue indications (signals) when a TP connection is dis- connected. p_dont_change_params Boolean. [false] If true the TP entity will not override any of the other values given in this structure. If the values cannot be used, the TP entity will drop, disconnect, or refuse to establish the connection to which this structure per- tains. p_netservice One of { ISO_CLNS, ISO_CONS, ISO_COSNS, IN_CLNS }. [ISO_CLNS] Indicates which network service is to be used. ISO_CLNS indicates the connectionless network service provided by CLNP (ISO 8473). ISO_CONS indicates the connection-oriented network ser- vice provided by X.25 (ISO 8208) and ISO 8878. ISO_COSNS indicates the connectionless network service running over a connection-oriented subnetwork service: CLNP (ISO 8473) over X.25 (ISO 8208). IN_CLNS indicates the DARPA Internet connectionless net- work service provided by IP (RFC 791). p_dummy Reserved for future use. The TPOPT_FLAGS option is used for obtaining various boolean-valued options. Its meaning is as follows. The bit numbering used is that of the RT PC, which means that bit 0 is the most significant bit, while bit 8 is the least significant bit. Values for TPOPT_FLAGS: Bits Description [Default] 0 TPFLAG_NLQOS_PDN: set when the quality of the network service is similar to that of a public data network. 1 TPFLAG_PEER_ON_SAMENET: set when the peer TP entity is considered to be on the same network as the local TP entity. 2 Not used. 3 TPFLAG_XPD_PRES: set when expedited data are present [0] 4..7 Reserved.
ERRORS
The TP entity returns errno error values as defined in <sys/errno.h> and <netiso/iso_errno.h>. If the TP entity encounters asynchronous events that will cause a trans- port connection to be closed, such as timing out while retransmitting a connect request TPDU, or receiving a DR TPDU, the TP entity issues a SIGURG signal, indicating that disconnection has occurred. If the signal is issued during a system call, the system call may be interrupted, in which case the errno value upon return from the system call is EINTR. If the signal SIGURG is being handled by reading from the socket, and it was an accept(2) that timed out, the read may result in ENOTSOCK, because the accept(2) call had not yet returned a legitimate socket descriptor when the signal was handled. ETIMEDOUT (or a some other errno value appropri- ate to the type of error) is returned if SIGURG is blocked for the dura- tion of the system call. A user program should take one of the following approaches: Block SIGURG If the program is servicing only one connection, it can block or ignore SIGURG during connection establishment. The advantage of this is that the errno value returned is somewhat meaningful. The disadvantage of this is that if ignored, disconnection and expedited data indications could be missed. For some programs this is not a problem. Handle SIGURG If the program is servicing more than one connection at a time or expedited data may arrive or both, the program may elect to ser- vice SIGURG. It can use the getsockopt(...TPOPT_FLAGS...) sys- tem call to see if the signal was due to the arrival of expedited data or due to a disconnection. In the latter case, getsockopt(2) will return ENOTCONN.
SEE ALSO
netstat(1), clnp(4), cltp(4), iso(4), tcp(4), ifconfig(8)
BUGS
The protocol definition of expedited data is slightly problematic, in a way that renders expedited data almost useless, if two or more packets of expedited data are sent within time epsilon, where epsilon depends on the application. The problem is not of major significance since most appli- cations do not use transport expedited data. The problem is this: the expedited data acknowledgment TPDU has no field for conveying credit, thus it is not possible for a TP entity to inform its peer that "I received your expedited data but have no room to receive more." The TP entity has the choice of acknowledging receipt of the XPD TPDU: when the user receives the XPD TSDU which may be a fairly long time, which may cause the sending TP entity to retransmit the packet, and possibly to close the con- nection after retransmission, or when the TP entity receives it so the sending entity does not retransmit or close the connec- tion. If the sending user then tries to send more expedited data ``soon'', the expedited data will not be acknowledged (until the receiving user receives the first XPD TSDU). The ARGO implementation acknowledges XPD TPDUs immediately, in the hope that most users will not use expedited data frequently enough for this to be a problem. NetBSD 6.0 April 19, 1994 NetBSD 6.0
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