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Networking Services (XNS) Issue 5
Copyright © 1997 The Open Group

The Use of Options in XTI

Generalities

The functions t_accept(), t_connect(), t_listen(), t_optmgmt(), t_rcvconnect(), t_rcvudata(), t_rcvuderr() and t_sndudata() contain an opt argument of type struct netbuf as an input or output parameter. This argument is used to convey options between the transport user and the transport provider.

There is no general definition about the possible contents of options. There are general XTI options and those that are specific for each transport provider. Some options allow the user to tailor his communication needs, for instance by asking for high throughput or low delay. Others allow the fine-tuning of the protocol behaviour so that communication with unusual characteristics can be handled more effectively. Other options are for debugging purposes, or to request that certain operations should be performed.

Options values have meaning to, and are defined by, the protocol level in which they apply. In some cases, option values can be negotiated by a transport user. This includes the simple case where the transport user can simply enforce its use. Often, the transport provider or even the remote transport user may have the right to negotiate a value of lesser quality than a proposed one, that is, a delay may become longer, or a throughput may become lower.

It is useful to differentiate between options with end-to-end significance (sometimes referred to as association-related1 and those that are not. Association-related options are intimately related to the particular transport connection or datagram transmission. If the calling user specifies such an option, some ancillary information is transferred across the network in most cases. The interpretation and further processing of this information is protocol-dependent. For instance, in an ISO connection-mode communication, the calling user may specify quality-of-service parameters on connection establishment. These are first processed and possibly lowered by the local transport provider, then sent to the remote transport provider that may degrade them again, and finally conveyed to the called user that makes the final selection and transmits the selected values back to the caller.

Options without end-to-end significance do not contain information destined for the remote transport user. Some have purely local relevance, for example, an option that enables debugging. Others influence the transmission, for instance the option that sets the T_IP time-to-live field, or T_TCP_NODELAY (see Internet Protocol-specific Information ). Local options are negotiated solely between the transport user and the local transport provider. The distinction between these two categories of options is visible in XTI through the following relationship: on output, the functions t_listen() and t_rcvudata() return options with end-to-end significance only. The functions t_rcvconnect() and t_rcvuderr() may return options of both categories. On input, options of both categories may be specified with t_accept() and t_sndudata(). The functions t_connect() and t_optmgmt() can process and return both categories of options.

Options can be further distinguished between those which maintain a persistent value and those which are requests to perform actions to which the option values are effectively parameters. For each action that it supports and that maintains a persistent value, the transport provider has a default value. These defaults are sufficient for the majority of communication relations. Hence, a transport user should only request options actually needed to perform the task, and leave all others at their default value.

This chapter describes the general framework for the use of options. This framework is obligatory for all transport providers. The specific options that are legal for use with a specific transport provider are described in the provider-specific appendices (see ISO Transport Protocol Information and Internet Protocol-specific Information ). General XTI options are described in t_optmgmt .

The Format of Options

Options are conveyed via an opt argument of struct netbuf. Each option in the buffer specified is of the form struct t_opthdr possibly followed by an option value.

A transport provider embodies a stack of protocols. The level field of struct t_opthdr identifies the XTI level or a protocol of the transport provider such as T_TCP or ISO 8073:1986. The name field identifies the option within the level, and len contains its total length, that is, the length of the option header t_opthdr plus the length of the option value. The status field is used by the XTI level or the transport provider to indicate success or failure of a negotiation (see Retrieving Information about Options and t_optmgmt ).

Several options can be concatenated. The option user has, however to ensure that each options header and value part starts at a boundary appropriate for the architecture-specific alignment rules. The macros T_OPT_FIRSTHDR(nbp), T_OPT_NXTHDR(nbp, tohp), T_OPT_DATA(tohp) are provided for that purpose. These macros are defines in the man-page for t_optmgmt()( see t_optmgmt ).

T_OPT_FIRSTHDR is useful for finding an appropriately aligned start of the option buffer. T_OPT_NEXTHDR is useful for moving to the start of the next appropriately aligned option in the option buffer. Note that OPT_NEXTHDR is also available for backward compatibility requirements. T_OPT_DATA is useful for finding the start of the data part in the option buffer where the contents of its values start on an appropriately aligned boundary.

The length of the option buffer is given by opt.len. The alignment characters are included in the length.

The Elements of Negotiation

This section describes the general rules governing the passing and retrieving of options and the error conditions that can occur. Unless explicitly restricted, these rules apply to all functions that allow the exchange of options.

Multiple Options and Options Levels

When multiple options are specified in an option buffer on input, different rules apply to the levels that may be specified, depending on the function call. Multiple options specified on input to t_optmgmt() must address the same option level. Options specified on input to t_connect(), t_accept() and t_sndudata() can address different levels.

Illegal Options

Only legal options can be negotiated; illegal options cause failure. An option is illegal if the following applies:

If an illegal option is passed to XTI, the following will happen:

If the transport user passes multiple options in one call and one of them is illegal, the call fails as described above. It is, however, possible that some or even all of the submitted legal options were successfully negotiated. The transport user can check the current status by a call to t_optmgmt() with the T_CURRENT flag set (see t_optmgmt ).

Specifying an option level unknown to the transport provider does not cause failure in calls to t_connect(), t_accept() or t_sndudata(); the option is discarded in these cases. The function t_optmgmt() fails with [TBADOPT].

Specifying an option name that is unknown to or not supported by the protocol selected by the option level does not cause failure. The option is discarded in calls to t_connect(), t_accept() or t_sndudata(). The function t_optmgmt() returns T_NOTSUPPORT in the status field of the option.

Initiating an Option Negotiation

A transport user initiates an option negotiation when calling t_connect(), t_sndudata() or t_optmgmt() with the flag T_NEGOTIATE set.

The negotiation rules for these functions depend on whether an option request is an absolute requirement or not. This is explicitly defined for each option (see t_optmgmt and the protocol specific appendices where options are described for specific protocols). In case of an ISO transport provider, for example, the option that requests use of expedited data is not an absolute requirement. On the other hand, the option that requests protection could be an absolute requirement.

Note:
The notion "absolute requirement" originates from the quality-of-service parameters in ISO 8072:1986. Its use is extended here to all options.

If the proposed option value is an absolute requirement, three outcomes are possible:

If the proposed option value is not an absolute requirement, two outcomes are possible:

Unsupported options do not cause functions to fail or a connection to abort, since different vendors possibly implement different subsets of options. Furthermore, future enhancements of XTI might encompass additional options that are unknown to earlier implementations of transport providers. The decision whether or not the missing support of an option is acceptable for the communication is left to the transport user.

The transport provider does not check for multiple occurrences of the same option, possibly with different option values. It simply processes the options in the option buffer one after the other. However, the user should not make any assumption about the order of processing.

Not all options are independent of one another. A requested option value might conflict with the value of another option that was specified in the same call or is currently effective (see Option Management of a Transport Endpoint ). These conflicts may not be detected at once, but later they might lead to unpredictable results. If detected at negotiation time, these conflicts are resolved within the rules stated above. The outcomes may thus be quite different and depend on whether absolute or non-absolute requests are involved in the conflict.

Conflicts are usually detected at the time a connection is established or a datagram is sent. If options are negotiated with t_optmgmt(), conflicts are usually not detected at this time, since independent processing of the requested options must allow for temporal inconsistencies.

When called, the functions t_connect() and t_sndudata() initiate a negotiation of all options with end-to-end significance according to the rules of this section. Options not explicitly specified in the function calls themselves are taken from an internal option buffer that contains the values of a previous negotiation (see Option Management of a Transport Endpoint ).

Responding to a Negotiation Proposal

In connection-mode communication, some protocols give the peer transport users the opportunity to negotiate characteristics of the transport connection to be established. These characteristics are options with end-to-end significance. With the connection indication, the called user receives (via t_listen()) a proposal about the option values that should be effective for this connection. The called user can accept this proposal or weaken it by choosing values of lower quality (for example, longer delays than proposed). The called user can, of course, refuse the connection establishment altogether.

The called user responds to a negotiation proposal via t_accept(). If the called transport user tries to negotiate an option of higher quality than proposed, the outcome depends on the protocol to which that option applies. Some protocols may reject the option, some protocols take other appropriate action described in protocol-specific appendices. If an option is rejected, the following error occurs:


The connection fails; a T_DISCONNECT event occurs. It depends on timing and implementation conditions whether the t_accept() call still succeeds or fails with [TLOOK].

If multiple options are submitted with t_accept() and one of them is rejected, the connection fails as described above. Options that could be successfully negotiated before the erroneous option was processed retain their negotiated value. There is no roll-back mechanism (see Option Management of a Transport Endpoint ).

The response options can be specified with the t_accept() call. Alternatively, they can be specified by calling t_optmgmt() and passing it the file descriptor that will subsequently be passed as resfd to t_accept() to identify the responding endpoint (see Option Management of a Transport Endpoint . In case of conflict between option settings made by calls to t_optmgmt() and t_accept() at different times, the latest settings when t_accept() is called shall prevail. Note that the response to a negotiation proposal is activated when t_accept() is called. A t_optmgmt() call with erroneous option values as described above shall succeed; the connection aborts at the time t_accept() is called.

The connection also fails if the selected option values lead to contradictions.

The function t_accept() does not check for multiple specification of an option (see Initiating an Option Negotiation ). Unsupported options are ignored.

Retrieving Information about Options

This section describes how a transport user can retrieve information about options. To be explicit, a transport user must be able to:

To this end, the functions t_connect(), t_listen(), t_optmgmt(), t_rcvconnect(), t_rcvudata() and t_rcvuderr() take an output argument opt of struct netbuf. The transport user has to supply a buffer where the options shall be written to; opt.buf must point to this buffer, and opt.maxlen must contain the buffer's size. The transport user can set opt.maxlen to zero to indicate that no options are to be retrieved.

Which options are returned depend on the function call involved:

t_connect() (synchronous mode) and t_rcvconnect()

The functions return the values of all options with end-to-end significance that were received with the connection response and the negotiated values of those options without end-to-end significance that had been specified on input. However, options specified on input in the t_connect() call that are not supported or refer to an unknown option level are discarded and not returned on output.


The status field of each option returned with t_connect() or t_rcvconnect() indicates if the proposed value (T_SUCCESS) or a degraded value (T_PARTSUCCESS) has been negotiated. The status field of received ancillary information (for example, T_IP options) that is not subject to negotiation is always set to T_SUCCESS.

t_listen()
The received options with end-to-end significance are related to the incoming connection (identified by the sequence number), not to the listening endpoint. (However, the option values currently effective for the listening endpoint can affect the values retrieved by t_listen(), since the transport provider might be involved in the negotiation process, too.) Thus, if the same options are specified in a call to t_optmgmt() with action T_CURRENT, t_optmgmt() will usually not return the same values.

The number of received options may be variable for subsequent connection indications, since many options with end-to-end significance are only transmitted on explicit demand by the calling user (for example, T_IP options or ISO 8072:1986 throughput). It is even possible that no options at all are returned.

The status field is irrelevant.

t_rcvudata()
The received options with end-to-end significance are related to the incoming datagram, not to the transport endpoint fd. Thus, if the same options are specified in a call to t_optmgmt() with action T_CURRENT, t_optmgmt() will usually not return the same values.

The number of options received may vary from call to call.

The status field is irrelevant.

t_rcvuderr()
The returned options are related to the options input at the previous t_sndudata() call that produced the error. Which options are returned and which values they have depend on the specific error condition.

The status field is irrelevant.

t_optmgmt()
This call can process and return both categories of options. It acts on options related to the specified transport endpoint, not on options related to a connection indication or an incoming datagram. A detailed description is given in t_optmgmt .

Privileged and Read-only Options

Privileged options or option values are those that may be requested by privileged users only. The meaning of privilege is hereby implementation-defined.

Read-only options serve for information purposes only. The transport user may be allowed to read the option value but not to change it. For instance, to select the value of a protocol timer or the maximum length of a protocol data unit may be too subtle to leave to the transport user, though the knowledge about this value might be of some interest. An option might be read-only for all users or solely for non-privileged users. A privileged option might be inaccessible or read-only for non-privileged users.


An option might be negotiable in some XTI states and read-only in other XTI states. For instance, the ISO quality-of-service options are negotiable in the states T_IDLE and T_INCON and read-only in all other states (except T_UNINIT).

If a transport user requests negotiation of a read-only option, or a non-privileged user requests illegal access to a privileged option, the following outcomes are possible:

If multiple options are submitted to t_connect(), t_accept() or t_sndudata() and a read-only option is rejected, the connection or the datagram transmission fails as described. Options that could be successfully negotiated before the erroneous option was processed retain their negotiated values. There is no roll-back mechanism (see also Option Management of a Transport Endpoint ).

Option Management of a Transport Endpoint

This section describes how option management works during the lifetime of a transport endpoint.

Each transport endpoint is (logically) associated with an internal option buffer. When a transport endpoint is created, this buffer is filled with a system default value for each supported option. Depending on the option, the default may be `OPTION ENABLED', `OPTION DISABLED' or denote a time span, etc. These default settings are appropriate for most uses. Whenever an option value is modified in the course of an option negotiation, the modified value is written to this buffer and overwrites the previous one. At any time, the buffer contains all option values that are currently effective for this transport endpoint.

The current value of an option can be retrieved at any time by calling t_optmgmt() with the flag T_CURRENT set. Calling t_optmgmt() with the flag T_DEFAULT set yields the system default for the specified option.

A transport user can negotiate new option values by calling t_optmgmt() with the flag T_NEGOTIATE set. The negotiation follows the rules described in The Elements of Negotiation .

Some options may be modified only in specific XTI states and are read-only in other XTI states. Many options with end-to-end significance, for instance, may not be changed in the state T_DATAXFER, and an attempt to do so will fail (see Privileged and Read-only Options ). The legal states for each option are specified with its definition.

As usual, options with end-to-end significance take effect at the time a connection is established or a datagram is transmitted. This is the case if they contain information that is transmitted across the network or determine specific transmission characteristics. If such an option is modified by a call to t_optmgmt(), the transport provider checks whether the option is supported and negotiates a value according to its current knowledge. This value is written to the internal option buffer.

The final negotiation takes place if the connection is established or the datagram is transmitted. This can result in a degradation of the option value or even in a negotiation failure. The negotiated values are written to the internal option buffer.

Some options may be changed in the state T_DATAXFER, for example, those specifying buffer sizes. Such changes might affect the transmission characteristics and lead to unexpected side effects (for example, data loss if a buffer size was shortened) if the user does not care.

The transport user can explicitly specify both categories of options on input when calling t_connect(), t_accept() or t_sndudata(). The options are at first locally negotiated option-by-option, and the resulting values written to the internal option buffer. The modified option buffer is then used if a further negotiation step across the network is required, as for instance in connection-oriented ISO communication. The newly negotiated values are then written to the internal option buffer.

At any stage, a negotiation failure can lead to an abort of the transmission. If a transmission aborts, the option buffer will preserve the content it had at the time the failure occurred. Options that could be negotiated just before the error occurred are written back to the option buffer, whether the XTI call fails or succeeds.

It is up to the transport user to decide which options it explicitly specifies on input when calling t_connect(), t_accept() or t_sndudata(). The transport user need not pass options at all, by setting the len field of the function's input opt argument to zero. The current content of the internal option buffer is then used for negotiation without prior modification.

The negotiation procedure for options at the time of a t_connect(), t_accept() or t_sndudata() call always obeys the rules in Initiating an Option Negotiation and Responding to a Negotiation Proposal , whether the options were explicitly specified during the call or implicitly taken from the internal option buffer.

The transport user should not make assumptions about the order in which options are processed during negotiation.

A value in the option buffer is only modified as a result of a successful negotiation of this option. It is, in particular, not changed by a connection release. There is no history mechanism that would restore the buffer state existing prior to the connection establishment or the datagram transmission. The transport user must be aware that a connection establishment or a datagram transmission may change the internal option buffer, even if each option was originally initialised to its default value.

Supplements

This section contains supplementary remarks and a short summary.

The Option Value T_UNSPEC

Some options may not have a fully specified value all the time. An ISO transport provider, for instance, that supports several protocol classes, might not have a preselected preferred class before a connection establishment is initiated. At the time of the connection request, the transport provider may conclude from the destination address, quality-of-service parameters and other locally available information which preferred class it should use. A transport user asking for the default value of the preferred class option in state T_IDLE would get the value T_UNSPEC. This value indicates that the transport provider did not yet select a value. The transport user could negotiate another value as the preferred class, for example, T_CLASS2. The transport provider would then be forced to initiate a connection request with class 2 as the preferred class.

An XTI implementation may also return the value T_UNSPEC if it can currently not access the option value. This may happen, for example, in the state T_UNBND in systems where the protocol stacks reside on separate controller cards and not in the host. The implementation may never return T_UNSPEC if the option is not supported at all.

If T_UNSPEC is a legal value for a specific option, it may be used by the user on input, too. It is used to indicate that it is left to the provider to choose an appropriate value. This is especially useful in complex options as ISO throughput, where the option value has an internal structure (see T_TCO_THROUGHPUT in ISO Transport Protocol Information ). The transport user may leave some fields unspecified by selecting this value. If the user proposes T_UNSPEC, the transport provider is free to select an appropriate value. This might be the default value, some other explicit value, or T_UNSPEC.

Each option where it is legal to use T_UNSPEC specifies its use as part of its description.

The info Argument

The functions t_open() and t_getinfo() return values representing characteristics of the transport provider in the argument info. The value of info->options is used by t_alloc() to allocate storage for an option buffer to be used in an XTI call. The value is sufficient for all uses.

In general, info->options also includes the size of privileged options, even if these are not read-only for non-privileged users. Alternatively, an implementation can choose to return different values in info->options for privileged and non-privileged users.

The values in info->etsdu, info->tsdu, info->connect and info->discon may be modified as soon as the T_DATAXFER state is entered. Calling t_optmgmt() need not influence these values (see t_optmgmt ).

Summary

Portability Aspects

An application programmer who writes XTI programs faces two portability aspects:

Options are intrinsically coupled with a definite protocol or protocol profile. Making explicit use of them therefore degrades portability across protocol profiles.

Different vendors might offer transport providers with different option support. This is due to different implementations and product policies. The lists of options on the t_optmgmt() manual page and in the protocol-specific appendices are maximal sets but do not necessarily reflect common implementation practice. Vendors will implement subsets that suit their needs. Making careless use of options therefore endangers portability across different system platforms.

Every implementation of a protocol profile accessible by XTI can be used with the default values of options. Applications can thus be written that do not care about options at all.

An application program that processes options retrieved from an XTI function should discard options it does not know in order to lessen its dependence from different system platforms and future XTI releases with possibly increased option support.


Footnotes

1.
The term "association" is used to denote a pair of communicating transport users, that is, the communication has end-to-end significance.


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