Patent Publication Number: US-5257369-A

Title: Apparatus and method for providing decoupling of data exchange details for providing high performance communication between software processes

Description:
This is a continuation-in-part application of a U.S. patent application entitled &#34;Apparatus and Method for Providing Decoupling of Data Exchange Details for Providing High Performance Communications Between Software Processes&#34;, Ser. No. 07/386,584, filed Jul. 27, 1989 (pending). 
     BACKGROUND OF THE INVENTION 
     The invention pertains to the field of decoupled information exchange between software processes running on different or even the same computer where the software processes may use different formats for data representation and organization or may use the same formats and organization but said formats and organization may later be changed without requiring any reprogramming. Also, the software processes use &#34;semantic&#34; or field-name information in such a way that each process can understand and use data it has received from any foreign software process, regardless of semantic or field name differences. The semantic information is decoupled from data representation and organization information. 
     With the proliferation of different types of computers and software programs and the ever-present need for different types of computers running different types of software programs to exchange data, there has arisen a need for a system by which such exchanges of data can occur. Typically, data that must be exchanged between software modules that are foreign to each other comprises text, data and graphics. However, there occasionally arises the need to exchange digitized voice or digitized image data or other more exotic forms of information. These different types of data are called &#34;primitives.&#34; A software program can manipulate only the primitives that it is programmed to understand and manipulate. Other types of primitives, when introduced as data into a software program, will cause errors. 
     &#34;Foreign,&#34; as the term is used herein, means that the software modules or host computers involved in the exchange &#34;speak different languages.&#34; For example, the Motorola and Intel microprocessor widely used in personal computers and work stations use different data representations in that in one family of microprocessors the most significant byte of multibyte words is placed first while in the other family of processors the most significant byte is placed last. Further, in IBM computers text letters are coded in EBCDIC code while in almost all other computers text letters are coded in ASCII code. Also, there are several different ways of representing numbers including integer, floating point, etc. Further, foreign software modules use different ways of organizing data and use different semantic information, i.e., what each field in a data record is named and what it means. 
     The use of various formats for data representation and organization means that translations either to a common language or from the language of one computer or process to the language of another computer or process must be made before meaningful communication can take place. Further, many software modules between which communication is to take place reside on different computers that are physically distant from each other and connected only local area networks, wide area networks, gateways, satellites, etc. These various networks have their own widely diverse protocols for communication. Also, at least in the world of financial services, the various sources of raw data such as Dow Jones News or Telerate™ use different data formats and communication protocols which must be understood and followed to receive data from these sources. 
     In complex data situations such as financial data regarding equities, bonds, money markets, etc., it is often useful to have nesting of data. That is, data regarding a particular subject is often organized as a data record having multiple &#34;fields,&#34; each field pertaining to a different aspect of the subject. It is often useful to allow a particular field to have subfields and a particular subfield to have its own subfields and so on for as many levels as necessary. For purposes of discussion herein, this type of data organization is called &#34;nesting.&#34; The names of the fields and what they mean relative to the subject will be called the &#34;semantic information&#34; for purposes of discussion herein. The actual data representation for a particular field, i.e., floating point, integer, alphanumeric, etc., and the organization of the data record in terms of how many fields it has, which are primitive fields which contain only data, and which are nested fields which contain subfields, is called the &#34;format&#34; or &#34;type&#34; information for purposes of discussion herein. A field which contains only data (and has no nested subfields) will be called a &#34;primitive field,&#34; and a field which contains other fields will be called a &#34;constructed field&#34; herein. 
     There are two basic types of operations that can occur in exchanges of data between software modules. The first type of operation is called a &#34;format operation&#34; and involves conversion of the format of one data record (hereafter data records may sometimes be called &#34;a forms&#34;) to another format. An example of such a format operation might be conversion of data records with floating point and EBCDIC fields to data records having the packed representation needed for transmission over an ETHERNET™ local area network. At the receiving process end another format operation for conversion from the ETHERNET™ packet format to integer and ASCII fields at the receiving process or software module might occur. Another type of operation will be called herein a &#34;semantic-dependent operation&#34; because it requires access to the semantic information as well as to the type or format information about a form to do some work on the form such as to supply a particular field of that form, e.g., today&#39;s IBM stock price or yesterday&#39;s IBM low price, to some software module that is requesting same. 
     Still further, in today&#39;s environment, there are often multiple sources of different types of data and/or multiple sources of the same type of data where the sources overlap in coverage but use different formats and different communication protocols (or even overlap with the same format and the same communication protocol). It is useful for a software module (software modules may hereafter be sometimes referred to as &#34;applications&#34;) to be able to obtain information regarding a particular subject without knowing the network address of the service that provides information of that type and without knowing the details of the particular communication protocol needed to communicate with that information source. 
     A need has arisen therefore for a communication system which can provide an interface between diverse software modules, processes and computers for reliable, meaningful exchanges of data while &#34;decoupling&#34; these software modules and computers. &#34;Decoupling&#34; means that the software module programmer can access information from other computers or software processes without knowing where the other software modules and computers are in a network, the format that forms and data take on the foreign software, what communication protocols are necessary to communicate with the foreign software modules or computers, or what communication protocols are used to transit any networks between the source process and the destination process; and without knowing which of a multiple of sources of raw data can supply the requested data. Further, &#34;decoupling,&#34; as the term is used herein, means that data can be requested at one time and supplied at another and that one process may obtain desired data from the instances of forms created with foreign format and foreign semantic data through the exercise by a communication interface of appropriate semantic operations to extract the requested data from the foreign forms with the extraction process being transparent to the requesting process. 
     Various systems exist in the prior art to allow information exchange between foreign software modules with various degrees of decoupling. One such type of system is any electronic mail software which implements Electronic Document Exchange Standards including CCITT&#39;s X.409 standard. Electronic mail software decouples applications in the sense that format or type data is included within each instance of a data record or form. However, there are no provisions for recording or processing of semantic information. Semantic operations such as extraction or translation of data based upon the name or meaning of the desired field in the foreign data structure is therefore impossible. Semantic-Dependent Operations are very important if successful communication is to occur. Further, there is no provision in Electronic Mail Software by which subject-based addressing can be implemented wherein the requesting application simply asks for information by subject without knowing the address of the source of information of that type. Further, such software cannot access a service or network for which a communication protocol has not already been established. 
     Relational Database Software and Data Dictionaries are another example of software systems in the prior art for allowing foreign processes to share data. The shortcoming of this class of software is that such programs can handle only &#34;flat&#34; tables, records and fields within records but not nested records within records. Further, the above-noted shortcoming in Electronic Mail Software also exists in Relational Database Software. 
     SUMMARY OF THE INVENTION 
     According to the teachings of the invention, there is provided a method and apparatus for providing a structure to interface foreign processes and computers while providing a degree of decoupling heretofore unknown. 
     The data communication interface software system according to the teachings of the invention consists essentially of several libraries of programs organized into two major components, a communication component and a data-exchange component. Interface, as the term is used herein in the context of the invention, means a collection of functions which may be invoked by the application to do useful work in communicating with a foreign process or a foreign computer or both. Invoking functions of the interface may be by subroutine calls from the application or from another component in the communications interface according to the invention. 
     In the preferred embodiment, the functions of the interface are carried out by the various subroutines in the libraries of subroutines which together comprise the interface. Of course, those skilled in the art will appreciate that separate programs or modules may be used instead of subroutines and may actually be preferable in some cases. 
     Data format decoupling is provided such that a first process using data records or forms having a first format can communicate with a second process which has data records having a second, different format without the need for the first process to know or be able to deal with the format used by the second process. This form of decoupling is implemented via the data-exchange component of the communication interface software system. 
     The data-exchange component of the communication interface according to the teachings of the invention includes a forms-manager module and a forms-class manager module. The forms-manager module handles the creation, storage, recall and destruction of instances of forms and calls to the various functions of the forms-class manager. The latter handles the creation, storage, recall, interpretation, and destruction of forms-class descriptors which are data records which record the format and semantic information that pertain to particular classes of forms. The forms-class manager can also receive requests from the application or another component of the communication interface to get a particular field of an instance of a form when identified by the name or meaning of the field, retrieve the appropriate form instance, and extract and deliver the requested data in the appropriate field. The forms-class manager can also locate the class definition of an unknown class of forms by looking in a known repository of such class definitions or by requesting the class definition from the forms-class manager linked to the foreign process which created the new class of form. Semantic data, such as field names, is decoupled from data representation and organization in the sense that semantic information contains no information regarding data representation or organization. The communication interface of the invention implements data decoupling in the semantic sense and in the data format sense. In the semantic sense, decoupling is implemented by virtue of the ability to carry out semantic-dependent operations. These operations allow any process coupled to the communications interface to exchange data with any other process which has data organized either the same or in a different manner by using the same field names for data which means the same thing in the preferred embodiment. In an alternative embodiment semantic-dependent operations implement an aliasing or synonym conversion facility whereby incoming data fields having different names but which mean a certain thing are either relabeled with field names understood by the requesting process or are used as if they had been so relabeled. 
     The interface according to the teachings of the invention has a process architecture organized in 3 layers. 
     Architectural decoupling is provided by an information layer such that a requesting process can request data regarding a particular subject without knowing the network address of the server or process where the data may be found. This form of decoupling is provided by a subject-based addressing system within the information layer of the communication component of the interface. 
     Subject-based addressing is implemented by the communication component of the communication interface of the invention by subject mapping. The communication component receives &#34;subscribe&#34; requests from an application which specifies the subject upon which data is requested. A subject-mapper module in the information layer receives the request from the application and then looks up the subject in a database, table or the like. The database stores &#34;service records&#34; which indicate the various server processes that supply data on various subjects. The appropriate service record identifying the particular server process that can supply data of the requested type and the communication protocol (hereafter sometimes called the service discipline) to use in communicating with the identified server process is returned to the subject-mapper module. 
     The subject mapper has access to a plurality of communications library programs or subroutines on the second layer of the process architecture called the service layer. The routines on the service layer are called &#34;service disciplines.&#34; Each service discipline encapsulates a predefined communication protocol which is specific to a server process. The subject mapper then invokes the appropriate service discipline identified in the service record. 
     The service discipline is given the subject by the subject mapper and proceeds to establish communications with the appropriate server process. Thereafter, instances of forms containing data regarding the subject are sent by the server process to the requesting process via the service discipline which established the communication. 
     Service protocol decoupling is provided by the service layer. 
     Temporal decoupling is implemented in some service disciplines directed to page-oriented server processes such as Telerate™ by access to real-time data bases which store updates to pages to which subscriptions are outstanding. 
     A third layer of the distributed communication component is called the communication layer and provides configuration decoupling. This layer includes a DCC library of programs that receives requests to establish data links to a particular server and determines the best communication protocol to use for the link unless the protocol is already established by the request. The communication layer also includes protocol engines to encapsulate various communication protocols such as point-to-point, broadcast, reliable broadcast and the Intelligent Multicast™ protocol. Some of the functionality of the communication layer augments the functionality of the standard transport protocols of the operating system and provides value added services. 
     One of these value added services is the reliable broadcast protocol. This protocol engine adds sequence numbers to packets of packetized messages on the transmit side and verifies that all packets have been received on the receive side. Packets are stored for retransmission on the transmit side. On the receive side, if all packets did not come in or some are garbled, a request is sent for retransmission. The bad or missing packets are then resent. When all packets have been successfully received, an acknowledgment message is sent. This causes the transmit side protocol engine to flush the packets out of the retransmit buffer to make room for packets of the next message. 
     Another value added service is the Intelligent Multicast Protocol. This protocol involves the service discipline examining the subject of a message to be sent and determining how many subscribers there are for this message subject. If the number of subscribers is below a threshold set by determining costs of point-to-point versus broadcast transmission, the message is sent point-to-point. Otherwise the message is sent by the reliable broadcast protocol. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram illustrating the relationships of the various software modules of the communication interface of one embodiment of the invention to client applications and the network. 
     FIG. 2 is an example of a form-class definition of the constructed variety. 
     FIG. 3 is an example of another constructed form-class definition. 
     FIG. 4 is an example of a constructed form-class definition containing fields that are themselves constructed forms. Hence, this is an example of nesting. 
     FIG. 5 is an example of three primitive form classes. 
     FIG. 6 is an example of a typical form instance as it is stored in memory. 
     FIG. 7 illustrates the partitioning of semantic data, format data, and actual or value data between the form-class definition and the form instance. 
     FIG. 8 is a flow chart of processing during a format operation, 
     FIG. 9 is a target format-specific table for use in format operations. 
     FIG. 10 is another target format-specific table for use in format operations. 
     FIG. 11 is an example of a general conversion table for use in format operations. 
     FIG. 12 is a flow chart for a typical semantic-dependent operation. 
     FIGS. 13A and 13B are, respectively, a class definition and the class descriptor form which stores this class definition. 
     FIG. 14 is a block diagram illustrating the relationships between the subject-mapper module and the service discipline modules of the communication component the requesting application and the service for subject-based addressing. 
     FIG. 15 illustrates the relationship of the various modules, libraries and interfaces of an alternative embodiment of the invention to the client applications. 
     FIG. 16 illustrates the relationships of various modules inside the communication interface of an alternative embodiment. 
     FIG. 17 is a block diagram of a typical distributed computer network. 
     FIG. 18 is a process architecture showing the relationship of the DCC library to the DCC protocol engines in the daemon. 
     FIG. 19, comprised of FIGS. 19A and 19B, is a flow diagram of the process which occurs, inter alia, at the three layers of the software of the invention where a subscribe request is sent to a service. 
     FIG. 20, comprised of FIGS. 20A and 20B, is a flow chart of the process which occurs at, inter alia, the three layers of the software interface according to the teachings of the invention when a subscribe request is received at a data producing process and messages flow back to the subscribing process. 
     FIG. 21, comprised of FIGS. 21A and 21B, is a flow chart of the process which occurs at the DCC library and in the reliable broadcast protocol engine when messages are sent by the reliable broadcast protocol. 
     FIG. 22, comprised of FIGS. 22A and 22B is a flow chart of processing by a reliable broadcast protocol engine on the data consumer side of the reliable broadcast transaction. 
     FIG. 23 is a flow chart of the processing which occurs in the service discipline to implement the Intelligent Multicast™ protocol. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED AND ALTERNATIVE EMBODIMENTS 
     Since the following description is highly technical, it can best be understood by an understanding of the terms used in the digital network telecommunication art defined in the appended glossary. The reader is urged to read the glossary at the end of the specification herein first. 
     Referring to FIG. 1 there is shown a block diagram of a typical system in which the communications interface of the invention could be incorporated, although a wide variety of system architectures can benefit from the teachings of the invention. The communication interface of the invention may be sometimes hereafter referred to as the TIB™ or Teknekron Information Bus in the specification of an alternative embodiment given below. The reader is urged at this point to study the glossary of terms included in this specification to obtain a basic understanding of some of the more important terms used herein to describe the invention. The teachings of the invention are incorporated in several libraries of computer programs which, taken together, provide a communication interface having many functional capabilities which facilitate modularity in client application development and changes in network communication or service communication protocols by coupling of various client applications together in a &#34;decoupled&#34; fashion. Hereafter, the teachings of the invention will be referred to as the communication interface. &#34;Decoupling,&#34; as the term is used herein, means that the programmer of client application is freed of the necessity to know the details of the communication protocols, data representation format and data record organization of all the other applications or services with which data exchanges are desired. Further, the programmer of the client application need not know the location of services or servers providing data on particular subjects in order to be able to obtain data on these subjects. The communication interface automatically takes care of all the details in data exchanges between client applications and between data-consumer applications and data-provider services. 
     The system shown in FIG. 1 is a typical network coupling multiple host computers via a network or by shared memory. Two host computers, 10 and 12, are shown in FIG. 1 running two client applications 16 and 18, although in other embodiments these two client applications may be running on the same computer. These host computers are coupled by a network 14 which may be any of the known networks such as the ETHERNET™ communication protocol, the token ring protocol, etc. A network for exchanging data is not required to practice the invention, as any method of exchanging data known in the prior art will suffice for purposes of practicing the invention. Accordingly, shared memory files or shared distributed storage to which the host computers 10 and 12 have equal access will also suffice as the environment in which the teachings of the invention are applicable. 
     Each of the host computers 10 and 12 has random access memory and bulk memory such as disk or tape drives associated therewith (not shown). Stored in these memories are the various operating system programs, client application programs, and other programs such as the programs in the libraries that together comprise the communication interface which cause the host computers to perform useful work. The libraries of programs in the communication interface provide basic tools which may be called upon by client applications to do such things as find the location of services that provide data on a particular subject and establish communications with that service using the appropriate communication protocol. 
     Each of the host computers may also be coupled to user interface devices such as terminals, printers, etc. (not shown). 
     In the exemplary system shown in FIG. 1, host computer 10 has stored in its memory a client application program 16. Assume that this client application program 16 requires exchanges of data with another client application program or service 18 controlling host computer 12 in order to do useful work. Assume also that the host computers 10 and 12 use different formats for representation of data and that application programs 16 and 18 also use different formats for data representation and organization for the data records created thereby. These data records will usually be referred to herein as forms. Assume also that the data path 14 between the host computers 10 and 12 is comprised of a local area network of the ETHERNET™ variety. 
     Each of the host processors 10 and 12 is also programmed with a library of programs, which together comprise the communication interfaces 20 and 22, respectively. The communication interface programs are either linked to the compiled code of the client applications by a linker to generate run time code, or the source code of the communication programs is included with the source code of the client application programs prior to compiling. In any event, the communication library programs are somehow bound to the client application. Thus, if host computer 10 was running two client applications, each client application would be bound to a communication interface module such as module 20. 
     The purpose of the communications interface module 20 is to decouple application 16 from the details of the data format and organization of data in forms used by application 18, the network address of application 18, and the details of the communication protocol used by application 18, as well as the details of the data format and organization and communication protocol necessary to send data across network 14. Communication interface module 22 serves the same function for application 18, thereby freeing it from the need to know many details about the application 16 and the network 14. The communication interface modules facilitate modularity in that changes can be made in client applications, data formats or organizations, host computers, or the networks used to couple all of the above together without the need for these changes to ripple throughout the system to ensure continued compatibility. 
     In order to implement some of these functions, the communications interfaces 20 and 22 have access via the network 14 to a network file system 24 which includes a subject table 26 and a service table 28. These tables will be discussed in more detail below with reference to the discussion of subject-based addressing. These tables list the network addresses of services that provide information on various subjects. 
     A typical system model in which the communication interface is used consists of users, users groups, networks, services, service instances (or servers) and subjects. Users, representing human end users, are identified by a user-ID. The user ID used in the communications interface is normally the same as the user ID or log-on ID used by the underlying operating system (not shown). However, this need not be the case. Each user is a member of exactly one group. 
     Groups are comprised of users with similar service access patterns and access rights. Access rights to a service or system object are grantable at the level of users and at the level of groups. The system administrator is responsible for assigning users to groups. 
     A &#34;network,&#34; as the term is used herein, means the underlying &#34;transport layer&#34; (as the term is used in the ISO network layer model) and all layers beneath the transport layer in the ISO network model. An application can send or receive data across any of the networks to which its host computer is attached. 
     The communication interface according to the teachings of the invention, of which blocks 20 and 22 in FIG. 1 are exemplary, includes for each client application to which it is bound a communications component 30 and a data-exchange component 32. The communications component 30 is a common set of communication facilities which implement, for example, subject-based addressing and/or service discipline decoupling. The communications component is linked to each client application. In addition, each communications component is linked to the standard transport layer protocols, e.g., TCP/IP, of the network to which it is coupled. Each communication component is linked to and can support multiple transport layer protocols. The transport layer of a network does the following things: it maps transport layer addresses to network addresses, multiplexes transport layer connections onto network connections to provide greater throughput, does error detection and monitoring of service quality, error recovery, segmentation and blocking flow control of individual connections of transport layer to network and session layers, and expedited data transfer. The communications component cooperates with the transport layer to provide reliable communications protocols for client applications as well as providing location transparency and network independence to the client applications. 
     The data-exchange component of the communications interface, of which component 32 is typical, implements a powerful way of representing and transmitting data by encapsulating the data within self-describing data objects called forms. These forms are self-describing in that they include not only the data of interest, but also type or format information which describes the representations used for the data and the organization of the form. Because the forms include this type or format information, format operations to convert a particular form having one format to another format can be done using strictly the data in the form itself without the need for access to other data called class descriptors or class definitions which give semantic information. Semantic information in class descriptors basically means the names of the fields of the form. 
     The ability to perform format operations solely with the data in the form itself is very important in that it prevents the delays encountered when access must be made to other data objects located elsewhere, such as class descriptors. Since format operations alone typically account for 25 to 50% of the processing time for client applications, the use of self-describing objects streamlines processing by rendering it faster. 
     The self-describing forms managed by the data-exchange component also allow the implementation of generic tools for data manipulation and display. Such tools include communication tools for sending forms between processes in a machine-independent format. Further, since self-describing forms can be extended, i.e., their organization changed or expanded, without adversely impacting the client applications using said forms, such forms greatly facilitate modular application development. 
     Since the lowest layer of the communications interface is linked with the transport layer of the ISO model and since the communications component 30 includes multiple service disciplines and multiple transport-layer protocols to support multiple networks, it is possible to write application-oriented protocols which transparently switch over from one network to another in the event of a network failure. 
     A &#34;service&#34; represents a meaningful set of functions which are exported by an application for use by its client applications. Examples of services are historical news retrieval services such as Dow Jones New, Quotron data feed, and a trade ticket router. Applications typically export only one service, although the export of many different services is also possible. 
     A &#34;service instance&#34; is an application or process capable of providing the given service. For a given service, several &#34;instances&#34; may be concurrently providing the service so as to improve the throughput of the service or provide fault tolerance. 
     Although networks, services and servers are traditional components known in the prior art, prior art distributed systems do not recognize the notion of a subject space or data independence by self-describing, nested data objects. Subject space supports one form of decoupling called subject-based addressing. Self-describing data objects which may be nested at multiple levels are new. Decoupling of client applications from the various communications protocols and data formats prevalent in other parts of the network is also very useful. 
     The subject space used to implement subject-based addressing consists of a hierarchical set of subject categories. In the preferred embodiment, a four-level subject space hierarchy is used. An example of a typical subject is: &#34;equity.ibm.composite.trade.&#34; The client applications coupled to the communications interface have the freedom and responsibility to establish conventions regarding use and interpretations of various subject categories. 
     Each subject is typically associated with one or more services providing data about that subject in data records stored in the system files. Since each service will have associated with it in the communication components of the communication interface a service discipline, i.e., the communication protocol or procedure necessary to communicate with that service, the client applications may request data regarding a particular subject without knowing where the service instances that supply data on that subject are located on the network by making subscription requests giving only the subject without the network address of the service providing information on that subject. These subscription requests are translated by the communications interface into an actual communication connection with one or more service instances which provide information on that subject. 
     A set of subject categories is referred to as a subject domain. Multiple subject domains are allowed. Each domain can define domain-specific subject and coding functions for efficiently representing subjects in message headers. 
     DATA INDEPENDENCE: The Data-Exchange Component 
     The overall purpose of the data-exchange component such as component 32 in FIG. 1 of the communication interface is to decouple the client applications such as application 16 from the details of data representation, data structuring and data semantics. 
     Referring to FIG. 2, there is shown an example of a class definition for a constructed class which defines both format and semantic information which is common to all instances of forms of this class. In the particular example chosen, the form class is named Player --  Name and has a class ID of 1000. The instances of forms of this class 1000 include data regarding the names, ages and NTRP ratings for tennis players. Every class definition has associated with it a class number called the class ID which uniquely identifies the class. 
     The class definition gives a list of fields by name and the data representation of the contents of the field. Each field contains a form and each form may be either primitive or constructed. Primitive class forms store actual data, while constructed class forms have fields which contain other forms which may be either primitive or constructed. In the class definition of FIG. 2, there are four fields named Rating, Age, Last --  Name and First --  Name. Each field contains a primitive class form so each field in instances of forms of this class will contain actual data. For example, the field Rating will always contain a primitive form of class 11. Class 11 is a primitive class named Floating --  Point which specifies a floating-point data representation for the contents of this field. The primitive class definition for the class Floating --  Point, class 11, is found in FIG. 5. The class definition of the primitive class 11 contains the class name, Floating --  Point, which uniquely identifies the class (the class number, class 11 in this example, also uniquely identifies the class) and a specification of the data representation of the single data value. The specification of the single data value uses well-known predefined system data types which are understood by both the host computer and the application dealing with this class of forms. 
     Typical specifications for data representation of actual data values include integer, floating point, ASCII character strings or EBCDIC character strings, etc. In the case of primitive class 11, the specification of the data value is Floating --  Point --  1/1 which is an arbitrary notation indicating that the data stored in instances of forms of this primitive class will be floating-point data having two digits total, one of which is to the right of the decimal point. 
     Returning to the consideration of the Player --  Name class definition of FIG. 2, the second field is named Age. This field contains forms of the primitive class named Integer associated with class number 12 and defined in FIG. 5. The Integer class of form, class 12, has, per the class definition of FIG. 5, a data representation specification of Integer --  3, meaning the field contains integer data having three digits. The last two fields of the class 1000 definition in FIG. 2 are Last --  Name and First --  Name. Both of these fields contain primitive forms of a class named String --  Twenty --  ASCII, class 10. The class 10 class definition is given in FIG. 5 and specifies that instances of forms of this class contain ASCII character strings which are 20 characters long. 
     FIG. 3 gives another constructed class definition named Player --  Address, class 1001. Instances of forms of this class each contain three fields named Street, City and State. Each of these three fields contains primitive forms of the class named String --  20 --  ASCII, class 10. Again, the class definition for class 10 is given in FIG. 5 and specifies a data representation of 20-character ASCII strings. 
     An example of the nesting of constructed class forms is given in FIG. 4. FIG. 4 is a class definition for instances of forms in the class named Tournament --  Entry, class 1002. Each instance of a form in this class contains three fields named Tournament --  Name, Player, and Address. The field Tournament --  Name includes forms of the primitive class named String --  Twenty --  ASCII, class 10 defined in FIG. 5. The field named Player contains instances of constructed forms of the class named Player --  Name, class 1000 having the format and semantic characteristics given in FIG. 2. The field named Address contains instances of the constructed form of constructed forms of the constructed class named Player --  Address, class 1001, which has the format and semantic characteristics given in the class definition of FIG. 3. 
     The class definition of FIG. 4 shows how nesting of forms can occur in that each field of a form is a form itself and every form may be either primitive and have only one field or constructed and have several fields. In other words, instances of a form may have as many fields as necessary, and each field may have as many subfields as necessary. Further, each subfield may have as many sub-subfields as necessary. This nesting goes on for any arbitrary number of levels. This data structure allows data of arbitrary complexity to be easily represented and manipulated. 
     Referring to FIG. 6 there is shown an instance of a form of the class of forms named Tournament --  Entry, class 1002, as stored as an object in memory. The block of data 38 contains the constructed class number 1002 indicating at this is an instance of a form of the constructed class named Tournament --  Entry. The block of data 40 indicates that this class of form has three fields. Those three fields have blocks of data shown at 42, 44, and 46 containing the class numbers of the forms in these fields. The block of data at 42 indicates that the first field contains a form of class 10 as shown in FIG. 5. A class 10 form is a primitive form containing a 20-character string of ASCII characters as defined in the class definition for class 10 in FIG. 5. The actual string of ASCII characters for this particular instance of this form is shown at 48, indicating that this is a tournament entry for the U.S. Open tennis tournament. The block of data at 44 indicates that the second field contains a form which is an instance of a constructed form of class 1000. Reference to this class definition shows that this class is named Player --  Name. The block of data 50 shows that this class of constructed form contains four subfields. Those fields contain forms of the classes recorded in the blocks of data shown at 52, 54, 56 and 58. These fields would be subfields of the field 44. The first subfield has a block of data at 52, indicating that this subfield contains a form of primitive class 11. This class of form is defined in FIG. 5 as containing a floating-point two-digit number with one decimal place. The actual data for this instance of the form is shown at 60, indicating that this player has an NTRP rating of 3.5. The second subfield has a block of data at 54, indicating that this subfield contains a form of primitive class 12. The class definition for this class indicates that the class is named integer and contains integer data. The class definition for class 1000 shown in FIG. 2 indicates that this integer data, shown at block 62, is the player&#39;s age. Note that the class definition semantic data regarding field names is not stored in the form instance. Only the format or type information is stored in the form instance in the form of the class ID for each field. 
     The third subfield has a block of data at 56, indicating that this subfield contains a form of primitive class 10 named String --  20 --  ASCII. This subfield corresponds to the field Last --  Name in the form of class Player --  Name, class 1000, shown in FIG. 2. The primitive class 10 class definition specifies that instances of this primitive class contain a 20-character ASCII string. This string happens to define the player&#39;s last name. In the instance shown in FIG. 6, the player&#39;s last name is Blackett, as shown at 64. 
     The last subfield has a block of data at 58, indicating that the field contains a primitive form of primitive class 10 which is a 20-character ASCII string. This subfield is defined in the class definition of class 1000 as containing the player&#39;s first name. This ASCII string is shown at 66. 
     The third field in the instance of the form of class 1002 has a block of data at 46, indicating that this field contains a constructed form of the constructed class 1001. The class definition for this class is given in FIG. 3 and indicates the class is named Player --  Address. The block of data at 68 indicates that this field has three subfields containing forms of the class numbers indicated at 70, 72 and 74. These subfields each contain forms of the primitive class 10 defined in FIG. 5. Each of these subfields therefore contains a 20-character ASCII string. The contents of these three fields are defined in the class definition for class 1001 and are, respectively, the street, city and state entries for the address of the player named in the field 44. These 3-character strings are shown at 76, 78 and 80, respectively. 
     Referring to FIG. 7, there is shown a partition of the semantic information, format information and actual data between the class definition and instances of forms of this class. The field name and format or type information are stored in the class definition, as indicated by box 82. The format or type information (in the form of the class ID) and actual data or field values are stored in the instance of the form as shown by box 72. For example, in the instance of the form of class Tournament --  Entry, class 1002 shown in FIG. 6, the format data for the first field is the data stored in block 42, while the actual data for the first field is the data shown at block 48. Essentially, the class number or class ID is equated by the communications interface with the specification for the type of data in instances of forms of that primitive class. Thus, the communications interface can perform format operations on instances of a particular form using only the format data stored in the instance of the form itself without the need for access to the class definition. This speeds up format operations by eliminating the need for the performance of the steps required to access a class definition which may include network access and/or disk access, which would substantially slow down the operation. Since format-type operations comprise the bulk of all operations in exchanging data between foreign processes, the data structure and the library of programs to handle the data structure defined herein greatly increase the efficiency of data exchange between foreign processes and foreign computers. 
     For example, suppose that the instance of the form shown in FIG. 6 has been generated by a process running on a computer by Digital Equipment Corporation (DEC) and therefore text is expressed in ASCII characters. Suppose also that this form is to be sent to a process running on an IBM computer, where character strings are expressed in EBCDIC code. Suppose also that these two computers were coupled by a local area network using the ETHERNET™ communications protocol. 
     To make this transfer, several format operations would have to be performed. These format operations can best be understood by reference to FIG. 1 with the assumption that the DEC computer is host 1 shown at 10 and the IBM computer is host 2 shown at 12. 
     The first format operation to transfer the instance of the form shown in FIG. 6 from application 16 to application 18 would be a conversion from the format shown in FIG. 6 to a packed format suitable for transfer via network 14. Networks typically operate on messages comprised of blocks of data comprising a plurality of bytes packed together end to end preceded by multiple bytes of header information which include such things as the message length, the destination address, the source address, and so on, and having error correction code bits appended to the end of the message. Sometimes delimiters are used to mark the start and end of the actual data block. 
     The second format operation which would have to be performed in this hypothetical transfer would be a conversion from the packed format necessary for transfer over network 14 to the format used by the application 18 and the host computer 12. 
     Format operations are performed by the forms-manager modules of the communications interface. For example, the first format operation in the hypothetical transfer would be performed by the forms-manager module 86 in FIG. 1, while the second format operation in the hypothetical transfer would be performed by the forms-manager module in the data-exchange component 88. 
     Referring to FIG. 8, there is shown a flowchart of the operations performed by the forms-manager modules in performing format operations. Further details regarding the various functional capabilities of the routines in the forms-manager modules of the communications interface will be found in the functional specifications for the various library routines of the communications interface included herein. The process of FIG. 8 is implemented by the software programs in the forms-manager modules of the data-exchange components in the communications interface according to the teachings of the invention. The first step is to receive a format conversion call from either the application or from another module in the communications interface. This process is symbolized by block 90 and the pathways 92 and 94 in FIG. 1. The same type call can be made by the application 18 or the communications component 96 for the host computer 12 in FIG. 1 to the forms-manager module in the data-exchange component 88, since this is a standard functional capability or &#34;tool&#34; provided by the communication interface of the invention to all client applications. Every client application will be linked to a communication interface like interface 20 in FIG. 1. 
     Typically, format conversion calls from the communication components such as modules 30 and 96 in FIG. 1 to the forms-manager module will be from a service discipline module which is charged with the task of sending a form in format 1 to a foreign application which uses format 2. Another likely scenario for a format conversion call from another module in the communication interface is when a service discipline has received a form from another application or service which is in a foreign format and which needs to be converted to the format of the client application. 
     The format conversion call will have parameters associated with it which are given to the forms manager. These parameters specify both the &#34;from&#34; format and the &#34;to&#34; or &#34;target&#34; format. 
     Block 98 represents the process of accessing an appropriate target format-specific table for the specified conversion, i.e., the specified &#34;from&#34; format and the specified &#34;to&#34; format will have a dedicated table that gives details regarding the appropriate target format class for each primitive &#34;from&#34; format class to accomplish the conversion. There are two tables which are accessed sequentially during every format conversion operation in the preferred embodiment. In alternative embodiments, these two tables may be combined. Examples of the two tables used in the preferred embodiment are shown in FIGS. 9, 10 and 11. FIG. 9 shows a specific format conversion table for converting from DEC machines to X.409 format. FIG. 10 shows a format-specific conversion table for converting from X.409 format to IBM machine format. FIG. 11 shows a general conversion procedures table identifying the name of the conversion program in the communications interface library which performs the particular conversion for each &#34;from&#34;-&#34;to&#34; format pair. 
     The tables of FIGS. 9 and 10 probably would not be the only tables necessary for sending a form from the application 16 to the application 18 in FIG. 1. There may be further format-specific tables necessary for conversion from application 16 format to DEC machine format and for conversion from IBM machine format to application 18 format. However, the general concept of the format conversion process implemented by the forms-manager modules of the communications interface can be explained with reference to FIGS. 9, 10 and 11. 
     Assume that the first conversion necessary in the process of sending a form from application 16 to application 18 is a conversion from DEC machine format to a packed format suitable for transmission over an ETHERNET™ network. In this case, the format conversion call received in step 90 would invoke processing by a software routine in the forms-manager module which would perform the process symbolized by block 98. 
     In this hypothetical example, the appropriate format-specific table to access by this routine would be determined by the &#34;from&#34; format and &#34;to&#34; format parameters in the original format conversion call received by block 90. This would cause access to the table shown in FIG. 9. The format conversion call would also identify the address of the form to be converted. 
     The next step is symbolized by block 100. This step involves accessing the form identified in the original format conversion call and searching through the form to find the first field containing a primitive class of form. In other words, the record is searched until a field is found storing actual data as opposed to another constructed form having subfields. 
     In the case of the form shown in FIG. 6, the first field storing a primitive class of form is field 42. The &#34;from&#34; column of the table of FIG. 9 would be searched using the class number 10 until the appropriate entry was found. In this case, the entry for a &#34;from&#34; class of 10 indicates that the format specified in the class definition for primitive class 25 is the &#34;to&#34; format. This process of looking up the &#34;to&#34; format using the &#34;from&#34; format is symbolized by block 102 in FIG. 8. The table shown in FIG. 9 may be &#34;hardwired&#34; into the code of the routine which performs the step symbolized by block 102. 
     Alternatively, the table of FIG. 9 may be a database or other file stored somewhere in the network file system 24 in FIG. 1. In such a case, the routine performing the step 102 in FIG. 8 would know the network address and file name for the file to access for access to the table of FIG. 9. 
     Next, the process symbolized by block 104 in FIG. 8 is performed by accessing the general conversion procedures table shown in FIG. 11. This is a table which identifies the conversion program in the forms manager which performs the actual work of converting one primitive class of form to another primitive class of form. This table is organized with a single entry for every &#34;from&#34;-&#34;to&#34; format pair. Each entry in the table for a &#34;from&#34;-&#34;to&#34; pair includes the name of the conversion routine which does the actual work of the conversion. The process symbolized by block 104 comprises the steps of taking the &#34;from&#34;-&#34;to&#34; pair determined from access to the format-specific conversion table in step 102 and searching the entries of the general conversion procedures table until an entry having a &#34;from&#34;-&#34;to&#34; match is found. In this case, the third entry from the top in the table of FIG. 11 matches the &#34;from&#34;-&#34;to&#34; format pair found in the access to FIG. 9. This entry is read, and it is determined that the name of the routine to perform this conversion is ASCII --  ETHER. (In many embodiments, the memory address of the routine, opposed to the name, would be stored in the table.) 
     Block 106 in FIG. 8 symbolizes the process of calling the conversion program identified by step 104 and performing this conversion routine to change the contents of the field selected in step 100 to the &#34;to&#34; or target format identified in step 102. In the hypothetical example, the routine ASCII --  ETHER would be called and performed by step 106. The call to this routine would deliver the actual data stored in the field selected in the process of step 100, i.e., field 42 of the instance of a form shown in FIG. 6, such that the text string &#34;U.S. Open&#34; would be converted to a packed ETHERNET™ format. 
     Next, the test of block 108 is performed to determine if all fields containing primitive classes of forms have been processed. If they have, then format conversion of the form is completed, and the format conversion routine is exited as symbolized by block 110. 
     If fields containing primitive classes of forms remain to be processed, then the process symbolized by block 112 is performed. This process finds the next field containing a primitive class of form. 
     Thereafter, the processing steps symbolized by blocks 102, 104, 106, and 108 are performed until all fields containing primitive classes of forms have been converted to the appropriate &#34;to&#34; format. 
     As noted above, the process of searching for fields containing primitive classes of forms proceeds serially through the form to be converted. If the next field encountered contains a form of a constructed class, that class of form must itself be searched until the first field therein with a primitive class of form is located. This process continues through all levels of nesting for all fields until all fields have been processed and all data stored in the form has been converted to the appropriate format. As an example of how this works, in the form of FIG. 6, after processing the first field 42, the process symbolized by block 112 in FIG. 8 would next encounter the field 44 (fields will be referred to by the block of data that contain the class ID for the form stored in that field although the contents of the field are both the class ID and the actual data or the fields and subfields of the form stored in that field). Note that in the particular class of form represented by FIG. 6, the second field 44 contains a constructed form comprised of several subfields. Processing would then access the constructed form of class 1000 which is stored by the second field and proceeds serially through this constructed form until it locates the first field thereof which contains a form of a primitive class. In the hypothetical example of FIG. 6, the first field would be the subfield indicated by the class number 11 at 52. The process symbolized by block 102 would then look up class 11 in the &#34;from&#34; column in the table of FIG. 9 and determine that the target format is specified by the class definition of primitive class 15. This &#34;from&#34;-&#34;to&#34; pair 11-15 would then be compared to the entries of the table of FIG. 11 to find a matching entry. Thereafter, the process of block 106 in FIG. 8 would perform the conversion program called Float1 --  ETHER to convert the block of data at 60 in FIG. 6 to the appropriate ETHERNET™ packed format. The process then would continue through all levels of nesting. 
     Referring to FIG. 12, there is shown a flowchart for a typical semantic-dependent operation. Semantic-dependent operations allow decoupling of applications by allowing one application to get the data in a particular field of an instance of a form generated by a foreign application provided that the field name is known and the address of the form instance is known. The communications interface according to the teachings of the invention receives semantic-dependent operation requests from client applications in the form of Get --  Field calls in the preferred embodiment where all processes use the same field names for data fields which mean the same thing (regardless of the organization of the form or the data representation of the field in the form generated by the foreign process). In alternative embodiments, an aliasing or synonym table or data base is used. In such embodiments, the Get --  Field call is used to access the synonym table in the class manager and looks for all synonyms of the requested field name. All field names which are synonyms of the requested field name are returned. The class manager then searches the class definition for a match with either the requested field name or any of the synonyms and retrieves the field having the matching field name. 
     Returning to consideration of the preferred embodiment, such Get --  Field calls may be made by client applications directly to the forms-class manager modules such as the module 122 in FIG. 1, or they may be made to the communications components or forms-manager modules and transferred by these modules to the forms-class manager. The forms-class manager creates, destroys, manipulates, stores and reads form-class definitions. 
     A Get --  Field call delivers to the forms-class manager the address of the form involved and the name of the field in the form of interest. The process of receiving such a request is symbolized by block 120 in FIG. 12. Block 120 also symbolizes the process by which the class manager is given the class definition either programmatically, i.e., by the requesting application, or is told the location of a data base where the class definitions including the class definition for the form of interest may be found. There may be several databases or files in the network file system 24 of FIG. 1 wherein class definitions are stored. It is only necessary to give the forms-class manager the location of the particular file in which the class definition for the form of interest is stored. 
     Next, as symbolized by block 122, the class-manager module accesses the class definition for the form class identified in the original call. 
     The class manager then searches the class definition field names to find a match for the field name given in the original call. This process is symbolized by block 124. 
     After locating the field of interest in the class definition, the class manager returns a relative address pointer to the field of interest in instances of forms of this class. This process is symbolized by block 126 in FIG. 12. The relative address pointer returned by the class manager is best understood by reference to FIGS. 2, 4 and 6. Suppose that the application which made the Get --  Field call was interested in determining the age of a particular player. The Get --  Field request would identify the address for the instance of the form of class 1002 for player Blackett as illustrated in FIG. 6. Also included in the Get --  Field request would be the name of the field of interest, i.e., &#34;age&#34;. The class manager would then access the instance of the form of interest and read the class number identifying the particular class descriptor or class definition which applied to this class of forms. The class manager would then access the class descriptor for class 1002 and find a class definition as shown in FIG. 4. The class manager would then access the class definitions for each of the fields of class definition 1002 and would compare the field name in the original Get --  Field request to the field names in the various class definitions which make up the class definition for class 1002. In other words, the class manager would compare the names of the fields in the class definitions for classes 10, 1000, and 1001 to the field name of interest, &#34;Age&#34;. A match would be found in the class definition for class 1000 as seen from FIG. 2. For the particular record format shown in FIG. 6, the &#34;Age&#34; field would be the block of data 62, which is the tenth block of data in from the start of the record. The class manager would then return a relative address pointer of 10 in block 126 of FIG. 12. This relative address pointer is returned to the client application which made the original Get --  Field call. The client application then issues a Get --  Data call to the forms-manager module and delivers to the forms-manager module the relative address of the desired field in the particular instance of the form of interest. The forms-manager module must also know the address of the instance of the form of interest which it will already have if the original Get --  Field call came through the forms-manager module and was transferred to the forms-class manager. If the forms-manager module does not have the address of the particular instance of the form of interest, then the forms manager will request it from the client application. After receiving the Get --  Data call and obtaining the relative address and the address of the instance of the form of interest, the forms manager will access this instance of the form and access the requested data and return it to the client application. This process of receiving the Get --  Data call and returning the appropriate data is symbolized by block 128 in FIG. 12. 
     Normally, class-manager modules store the class definitions needed to do semantic-dependent operations in RAM of the host machine as class descriptors. Class definitions are the specification of the semantic and formation information that define a class. Class descriptors are memory objects which embody the class definition. Class descriptors are stored in at least two ways. In random access memory (RAM), class descriptors are stored as forms in the format native to the machine and client application that created the class definition. Class descriptors stored on disk or tape are stored as ASCII strings of text. 
     When the class-manager module is asked to do a semantic-dependent operation, it searches through its store of class descriptors in RAM and determines if the appropriate class descriptor is present. If it is, this class descriptor is used to perform the operation detailed above with reference to FIG. 12. If the appropriate class descriptor is not present, the class manager must obtain it. This is done by searching through known files of class descriptors stored in the system files 24 in FIG. 1 or by making a request to the foreign application that created the class definition to send the class definition to the requesting module. The locations of the files storing class descriptors are known to the client applications, and the class-manager modules also store these addresses. Often, the request for a semantic-dependent operation includes the address of the file where the appropriate class descriptor may be found. If the request does not contain such an address, the class manager looks through its own store of class descriptors and through the files identified in records stored by the class manager identifying the locations of system class descriptor files. 
     If the class manager asks for the class descriptor from the foreign application that generated it, the foreign application sends a request to its class manager to send the appropriate class descriptor over the network to the requesting class manager or the requesting module. The class descriptor is then sent as any other form and used by the requesting class manager to do the requested semantic-dependent operation. 
     If the class manager must access a file to obtain a class descriptor, it must also convert the packed ASCII representation in which the class descriptors are stored on disk or tape to the format of a native form for storage in RAM. This is done by parsing the ASCII text to separate out the various field names and specifications of the field contents and the class numbers. 
     FIGS. 13A and 13B illustrate, respectively, a class definition and the structure and organization of a class descriptor for the class definition of FIG. 13A and stored in memory as a form. The class definition given in FIG. 13A is named Person --  Class and has only two fields, named last and first. Each of these fields is specified to store a 20-character ASCII string. 
     FIG. 13B has a data block 140 which contains 1021 indicating that the form is a constructed form having a class number 1021. The data block at 142 indicates that the form has 3 fields. The first field contains a primitive class specified to contain an ASCII string which happens to store the class name, Person --  Class, in data block 146. The second field is of a primitive class assigned the number 2, data block 148, which is specified to contain a boolean value, data block 150. Semantically, the second field is defined in the class definition for class 1021 to define whether the form class is primitive (true) or constructed (false). In this case, data block 150 is false indicating that class 1021 is a constructed class. The third field is a constructed class given the class number 112 as shown by data block 152. The class definition for class 1021 defines the third field as a constructed class form which gives the names and specifications of the fields in the class definition. Data block 154 indicates that two fields exist in a class 112 form. The first field of class 112 is itself a constructed class given the class number 150, data block 156, and has two subfields, data block 158. The first subfield is a primitive class 15, data block 160, which is specified in the class definition for class 150 to contain the name of the first field in class 1021. Data block 162 gives the name of the first field in class 1021. The second subfield is of primitive class 15, data block 164, and is specified in the class definition of class 150 (not shown) to contain an ASCII string which specifies the representation, data block 166, of the actual data stored in the first field of class 1021. The second field of class 112 is specified in the class definition of class 112 to contain a constructed form of class 150, data block 168, which has two fields, data block 170, which give the name of the next field in class 1021 and specify the type of representation of the actual data stored in this second field. 
     DATA DISTRIBUTION AND SERVICE PROTOCOL DECOUPLING BY SUBJECT-BASED ADDRESSING AND THE USE OF SERVICE DISCIPLINE PROTOCOL LAYERS 
     Referring to FIG. 14, there is shown a block diagram of the various software modules, files, networks, and computers which cooperate to implement two important forms of decoupling. These forms of decoupling are data distribution decoupling and service protocol decoupling. Data distribution decoupling means freeing client applications from the necessity to know the network addresses for servers providing desired services. Thus, if a particular application needs to know information supplied by, for example, the Dow Jones news service, the client application does not need to know which servers and which locations are providing data from the Dow Jones news service raw data feed. 
     Service protocol decoupling means that the client applications need not know the particular communications protocols used by the servers, services or other applications with which exchanges of data are desired. 
     Data distribution decoupling is implemented by the communications module 30 in FIG. 14. The communications component is comprised of a library of software routines which implement a subject mapper 180 and a plurality of service disciplines to implement subject-based addressing. Service disciplines 182, 184 and 186 are exemplary of the service disciplines involved in subject-based addressing. 
     Subject-based addressing allows services to be modified or replaced by alternate services providing equivalent information without impacting the information consumers. This decoupling of the information consumers from information providers permits a higher degree of modularization and flexibility than that provided by traditional service-oriented models. 
     Subject-based addressing starts with a subscribe call 188 to the subject mapper 180 by a client application 16 running on host computer 10. The subscribe call is a request for information regarding a particular subject. Suppose hypothetically that the particular subject was equity.IBM.news. This subscribe call would pass two parameters to the subject mapper 180. One of these parameters would be the subject equity.IBM.news. The other parameter would be the name of a callback routine in the client application 16 to which data regarding the subject is to be passed. The subscribe call to the subject mapper 180 is a standard procedure call. 
     The purpose of the subject mapper is to determine the network address for services which provide information on various subjects and to invoke the appropriate service discipline routines to establish communications with those services. To find the location of the services which provide information regarding the subject in the subscribe call, the subject mapper 80 sends a request symbolized by line 190 to a directory-services component 192. The directory-services component is a separate process running on a computer coupled to the network 14 and in fact may be running on a separate computer or on the host computer 10 itself. The directory-services routine maintains a data base or table of records called service records which indicate which services supply information on which subjects, where those services are located, and the service disciplines used by those services for communication. The directory-services component 192 receives the request passed from the subject mapper 180 and uses the subject parameter of that request to search through its tables for a match. That is, the directory-services component 192 searches through its service records until a service record is found indicating a particular service or services which provide information on the desired subject. This service record is then passed back to the subject mapper as symbolized by line 194. The directory-services component may find several matches if multiple services supply information regarding the desired subject. 
     The service record or records passed back to the subject mapper symbolized by line 194 contain many fields. Two required fields in the service records are the name of the service which provides information on the desired subject and the name of the service discipline used by that service. Other optional fields which may be provided are the name of the server upon which said service is running and a location on the network of that server. 
     Generally, the directory-services component will deliver all the service records for which there is a subject map, because there may not be a complete overlap in the information provided on the subject by all services. Further, each service will run on a separate server which may or may not be coupled to the client application by the same network. If such multiplicity of network paths and services exists, passing all the service records with subject matter matches back to the subject mapper provides the ability for the communications interface to switch networks or switch servers or services in the case of failure of one or more of these items. 
     As noted above, the subject mapper 180 functions to set up communications with all of the services providing information on the desired subject. If multiple service records are passed back from the directory-services module 192, then the subject mapper 180 will set up communications with all of these services. 
     Upon receipt of the service records, the subject mapper will call each identified service discipline and pass to it the subject and the service record applicable to that service discipline. Although only three service disciplines 182, 184 and 186 are shown in FIG. 14, there may be many more than three in an actual system. 
     In the event that the directory-services component 192 does not exist or does not find a match, no service records will be returned to the subject mapper 180. In such a case, the subject mapper will call a default service discipline and pass it and the subject and a null record. 
     Each service discipline is a software module which contains customized code optimized for communication with the particular service associated with that service discipline. 
     Each service discipline called by the subject mapper 180 examines the service records passed to it and determines the location of the service with which communications are to be established. In the particular hypothetical example being considered, assume that only one service record is returned by the directory-services module 192 and that that service record identifies the Dow Jones news service running on server 196 and further identifies service discipline A at 182 as the appropriate service discipline for communications with the Dow Jones news service on server 196. Service discipline A will then pass a request message to server 196 as symbolized by line 198. This request message passes the subject to the service and may pass all or part of the service record. 
     The server 196 processes the request message and determines if it can, in fact, supply information regarding the desired subject. It then sends back a reply message symbolized by line 200. 
     Once communications are so established, the service sends all items of information pertaining to the requested subject on a continual basis to the appropriate service discipline as symbolized by path 202. In the example chosen here, the service running on server 196 filters out only those news items which pertain to IBM for sending to service discipline at 182. In other embodiments, the server may pass along all information it has without filtering this information by subject. The communications component 30 then filters out only the requested information and passes it along to the requesting application 16. In some embodiments this is done by the daemon to be described below, and in other embodiments, it is done elsewhere such as in the information or service layers to be described below. 
     Each service discipline can have a different behavior. For example, service discipline B at 184 may have the following behavior. The service running on server 196 may broadcast all news items of the Dow Jones news service on the network 14. All instances of service discipline B may monitor the network and filter out only those messages which pertain to the desired subject. Many different communication protocols are possible. 
     The service discipline A at 182 receives the data transmitted by the service and passes it to the named callback routine 204 in the client application 16. (The service discipline 182 was passed the name of the callback routine in the initial message from the mapper 180 symbolized by line 181.) The named callback routine then does whatever it is programmed to do with the information regarding the desired subject. 
     Data will continue to flow to the named callback routine 204 in this manner until the client application 16 expressly issues a cancel command to the subject mapper 180. The subject mapper 180 keeps a record of all subscriptions in existence and compares the cancel command to the various subscriptions which are active. If a match is found, the appropriate service discipline is notified of the cancel request, and this service discipline then sends a cancel message to the appropriate server. The service then cancels transmission of further data regarding that subject to the service discipline which sent the cancel request. 
     It is also possible for a service discipline to stand alone and not be coupled to a subject mapper. In this case the service discipline or service disciplines are linked directly to the application, and subscribe calls are made directly to the service discipline. The difference is that the application must know the name of the service supplying the desired data and the service discipline used to access the service. A database or directory-services table is then accessed to find the network address of the identified service, and communications are established as defined above. Although this software architecture does not provide data distribution decoupling, it does provide service protocol decoupling, thereby freeing the application from the necessity to know the details of the communications interface with the service with which data is to be exchanged. 
     More details on subject-based addressing subscription services provided by the communications interface according to the teachings of the invention are given in Section 4 of the communications interface specification given below. The preferred embodiment of the communications interface of the invention is constructed in accordance with that specification. 
     An actual subscribe function in the preferred embodiment is done by performing the TIB --  Consume --  Create library routine described in Section 4 of the specification. The call to TIB --  Consume --  Create includes a property list of parameters which are passed to it, one of which is the identity of the callback routine specified as My --  Message --  Handler in Section 4 of the specification. 
     In the specification, the subject-based addressing subscription service function is identified as TIBINFO. The TIBINFO interface consists of two libraries. The first library is called TIBINFO --  CONSUME for data consumers. The second library is called TIBINFO --  PUBLISH for data providers. An application includes one library or the other or both depending on whether it is a consumer a provider or both. An application can simultaneously be a consumer and a provider. 
     Referring to FIG. 15, there is shown a block diagram of the relationship of the communications interface according to the teachings of the invention to the applications and the network that couples these applications. Blocks having identical reference numerals to blocks in FIG. 1 provide similar functional capabilities as those blocks in FIG. 1. The block diagram in FIG. 15 shows the process architecture of the preferred embodiment. The software architecture corresponding to the process architecture given in FIG. 15 is shown in block form in FIG. 16. 
     The software architecture and process architecture detailed in FIGS. 15 and 16, respectively, represents an alternative embodiment to the embodiment described above with reference to FIGS. 1-14. 
     Referring to FIG. 15, the communications component 30 of FIG. 1 is shown as two separate functional blocks 30A and 30B in FIG. 15. That is, the functions of the communications component 30 in FIG. 1 are split in the process architecture of FIG. 15 between two functional blocks. A communications library 30A is linked with each client application 16, and a backend communications daemon process 30B is linked to the network 14 and to the communication library 30A. There is typically one communication daemon per host processor. This host processor is shown at 230 in FIG. 15 but is not shown at all in FIG. 16. Note that in FIG. 15, unlike the situation in FIG. 1, the client applications 16 and 18 are both running on the same host processor 230. Each client application is linked to its own copies of the various library programs in the communication libraries 30A and 96 and the form library of the data-exchange components 32 and 88. These linked libraries of programs share a common communication daemon 30B. 
     The communication daemons on the various host processors cooperate among themselves to insure reliable, efficient communication between machines. For subject addressed data, the daemons assist in its efficient transmission by providing low-level system support for filtering messages by subject. The communication daemons implement various communication protocols described below to implement fault tolerance, load balancing and network efficiency. 
     The communication library 30A performs numerous functions associated with each of the application-oriented communication suites. For example, the communication library translates subjects into efficient message headers that are more compact and easier to check than ASCII subject values. The communications library also maps service requests into requests targeted for particular service instances, and monitors the status of those instances. 
     The data-exchange component 32 of the communications interface according to the teachings of the invention is implemented as a library called the &#34;form library.&#34; This library is linked with the client application and provides all the core functions of the data-exchange component. The form library can be linked independently of the communication library and does not require the communication daemon 30B for its operation. 
     The communication daemon serves in two roles. In the subject-based addressing mode described above where the service instance has been notified of the subject and the network address to which data is to be sent pertaining to this subject, the communication daemon 30B owns the network address to which the data is sent. This data is then passed by the daemon to the communication library bound to the client application, which in turn passes the data to the appropriate callback routine in the client application. In another mode, the communication daemon filters data coming in from the network 14 by subject when the service instances providing data are in a broadcast mode and are sending out data regarding many different subjects to all daemons on the network. 
     The blocks 231, 233 and 235 in FIG. 15 represent the interface functions which are implemented by the programs in the communication library 30A and the form library 32. The TIBINFO interface 233 provides subject-based addressing services by the communication paradigm known as the subscription call. In this paradigm, a data consumer subscribes to a service or subject and in return receives a continuous stream of data about the service or subject until the consumer explicitly terminates the subscription (or a failure occurs). A subscription paradigm is well suited to real-time applications that monitor dynamically changing values, such as a stock price. In contrast, the more traditional request/reply communication is ill suited to such real-time applications, since it requires data consumers to &#34;poll&#34; data providers to learn of changes. 
     The interface 235 defines a programmatic interface to the protocol suite and service comprising the Market Data Subscription Service (MDSS) sub-component 234 in FIG. 16. This service discipline will be described more fully later. The RMDP interface 235 is a service address protocol in that it requires the client application to know the name of the service with which data is to be exchanged. 
     In FIG. 16 there is shown the software architecture of the system. A distributed communications component 232 includes various protocol engines 237, 239 and 241. A protocol engine encapsulates a communication protocol which interfaces service discipline protocols to the particular network protocols. Each protocol engine encapsulates all the logic necessary to establish a highly reliable, highly efficient communication connection. Each protocol engine is tuned to specific network properties and specific applications properties. The protocol engines 237, 239 and 241 provide a generic communication interface to the client applications such as applications 16 and 18. This frees these applications (and the programmers that write them) from the need to know the specific network or transport layer protocols needed to communicate over a particular network configuration. Further, if the network configuration or any of the network protocols are changed such as by addition of a new local area network, gateway etc. or switching of transport layer protocols say from DECNET™ to TCP/IP™, the application programs need not be changed. Such changes can be accommodated by the addition, substitution or alteration of the protocol engines so as to accommodate the change. Since these protocol engines are shared, there is less effort needed to change the protocol engines than to change all the applications. 
     The protocol engines provide protocol transparency and communication path transparency to the applications thereby freeing these applications from the need to have code which deals with all these details. Further, these protocol engines provide network interface transparency. 
     The protocol engines can also provide value added services in some embodiments by implementing reliable communication protocols. Such value added services include reliable broadest and reliable point to point communications as well as Reliable Multicast™ communications where communications are switched from reliable broadcast to reliable point to point when the situation requires this change for efficiency. Further, the protocol engines enhance broadcast operations where two or more applications are requesting data on a subject by receiving data directed to the first requesting application and passing it along to the other requesting applications. Prior art broadcast software does not have this capability. 
     The protocol engines also support efficient subject based addressing by filtering messages received on the network by subject. In this way, only data on the requested subject gets passed to the callback routine in the requesting application. In the preferred embodiment, the protocol engines coupled to the producer applications or service instances filter the data by subject before it is placed in the network thereby conserving network bandwidth, input/output processor bandwidth and overhead processing at the receiving ends of communication links. 
     The distributed communication component 232 (hereafter DCC) in FIG. 16 is structured to meet several important objectives. First, the DCC provides a simple, stable and uniform communication model. This provides several benefits. It shields programmers from the complexities of: the distributed environment; locating a target process; establishing communications with this target process; and determining when something has gone awry. All these tasks are best done by capable communications infrastructure and not by the programmer. Second, the DCC reduces development time not only by increasing programmer productivity but also by simplifying the integration of new features. Finally, it enhances configurability by eliminating the burden on applications to know the physical distribution on the network of other components. This prevents programmers from building dependencies in their code on particular physical configurations which would complicate later reconfigurations. 
     Another important objective is the achievement of portability through encapsulation of important system structures. This is important when migrating to a new hardware or software environment because the client applications are insulated from transport and access protocols that may be changing. By isolating the required changes in a small portion of the system (the DCC), the applications can be ported virtually unchanged and the investment in the application software is protected. 
     Efficiency is achieved by the DCC because it is coded on top of less costly &#34;connectionless&#34; transport protocol standard protocol suites such as TCP/IP and OSI. The DCC is designed to avoid the most costly problem in protocols, i.e., the proliferation of data &#34;copy&#34; operations. 
     The DCC achieves these objectives by implementing a layer of services on top of the basic services provided by vendor supplied software. Rather than re-inventing basic functions like reliable data transfer or flow-control mechanisms, the DCC shields applications from the idiosyncracies of any particular operating system. Examples include the hardware oriented interfaces of the MS-DOS environment, or the per-process file descriptor limit of UNIX. By providing a single unified communication toll that can be easily replicated in many hardware and software environments, the DCC fulfills the above objectives. 
     The DCC implements several different transmission protocols to support the various interaction paradigms, fault-tolerance requirements and performance requirements imposed by the service discipline protocols. Two of the more interesting protocols are the reliable broadcast and intelligent multicast protocols. 
     Standard broadcast protocols are not reliable and are unable to detect lost messages. The DCC reliable broadcast protocols ensure that all operational hosts either receive each broadcast message or detects the loss of the message. Unlike many so-called reliable broadcast protocols, lost messages are retransmitted on a limited, periodic basis. 
     The Intelligent Multicast™ protocol provides a reliable datastream to multiple destinations. The novel aspect of this protocol is that it can switch dynamically from point-to-point transmission to broadcast transmission in order to optimize the network and processor load. The switch from point-to-point to broadcast (and vice-versa) is transparent to higher-level protocols. This transport protocol allows the support of a much larger number of consumers than would be possible using either point-to-point or broadcast alone. The protocol is built on top of other protocols with the DCC. 
     Currently, all DCC protocols exchange data only in discrete units i.e., messages (in contrast to many transport protocols). The DCC guarantees that the messages originating from a single process are received in the order sent. 
     The DCC contains fault tolerant message transmission protocols that support retransmission in the event of a lost message. The DCC software guarantees &#34;at-most-once&#34; semantics with regard to message delivery and makes a best attempt to ensure &#34;exactly-once&#34; semantics. 
     The DCC has no exposed interface for use by application programmers. 
     The distributed component 232 is coupled to a variety of service disciplines 234, 236 and 238. The service discipline 234 has the behavior which will herein be called Market Data Subscription Service. This protocol allows data consumers to receive a continuous stream of data, fault tolerant of failures of individual data sources. This protocol suite provides mechanisms for administering load-balancing and entitlement policies. 
     The MDSS service discipline is service oriented in that applications calling this service discipline through the RMDP interface must know the service that supplies requested data. The MDSS service discipline does however support the subscription communication paradigm which is implemented by the Subject Addressed Subscription Service (SASS) service discipline 238 in the sense that streams of data on a subject will be passed by the MDSS service discipline to the linked application. 
     The MDSS service discipline allows data consumer applications to receive a continuous stream of data, tolerant of failures of individual data sources. This protocol suite 234 also provides mechanisms for load balancing and entitlement policy administration where the access privileges of a user or application are checked to insure a data consumer has a right to obtain data from a particular service. 
     Two properties distinguish the MDSS service discipline from typical client server protocols. First, subscriptions are explicitly supported whereby changes to requested values are automatically propagated to requesting applications. Second client applications request or subscribe to a specific service (as opposed to a particular server and as opposed to a particular subject). The MDSS service discipline then forwards the client application request to an available server. The MDSS service discipline also monitors the server connection and reestablishes it if the connection fails using a different server if necessary. 
     The MDSS service discipline implements the following important objectives. 
     Fault tolerance is implemented by program code which performs automatic switchover between redundant services by supporting dual or triple networks and by utilizing the fault tolerant transmission protocols such as reliable broadcast implemented in the protocol engines. Recovery is automatic after a server failure. 
     Load balancing is performed by balancing the data request load across all operating servers for a particular service. The load is automatically rebalanced when a server fails or recovers. In addition, the MDSS supports server assignment policies that attempts to optimize the utilization of scarce resources such as &#34;slots&#34; in a page cache or bandwidth across an external communication line. 
     Network efficiency is implemented by an intelligent multicast protocol implemented by the distributed communication daemon 30B in FIG. 15. The intelligent multicast protocol optimizes limited resources of network and I/O processor bandwidth by performing automatic, dynamic switchover from point to point communication protocols to broadcast protocols when necessary. For example, Telerate page 8 data may be provided by point to point distribution to the first five subscribers and then switch all subscribers to broadcast distribution when the sixth subscriber appears. 
     The MDSS service discipline provides a simple, easy-to-use application development interface that masks most of the complexity of programming a distributed system, including locating servers, establishing communication connections, reacting to failures and recoveries and load balancing. 
     The core functions of the MDSS service discipline are: get, halt and derive. The &#34;get&#34; call from a client application establishes a fault-tolerant connection to a server for the specified service and gets the current value of the specified page or data element. The connection is subscription based so that updates to the specified page are automatically forwarded to the client application. &#34;Halt&#34; stops the subscription. &#34;Drive&#34; sends a modifier to the service that can potentially change the subscription. 
     The MDSS service discipline is optimized to support page oriented services but it can support distribution of any type data. 
     The service discipline labeled MSA, 236, has yet a different behavior. The service discipline labeled SASS, 238, supports subject-based address subscription services. 
     The basic idea behind subject based addressing and the SASS service discipline&#39;s (hereafter SASS) implementation of it is straightforward. Whenever an application requires data, especially data on a dynamically changing value, the application simply subscribes to it by specifying the appropriate subject. The SASS then maps this subject request to one or more service instances providing information on this subject. The SASS then makes the appropriate communication connections to all the selected services through the appropriate one or more protocol engines necessary to communication with the servicer or servers providing the selected service or services. 
     Through the use of subject based addressing, information consumers can request information in a way that is independent of the application producing the information. Hence, the producing application can be modified or supplanted by a new application providing the same information without affecting the consumers of the information. 
     Subject based addressing greatly reduces the complexities of programming a distributed application in three ways. First, the application requests information by subject, as opposed to by server or service. Specifying information at this high level removes the burden on applications of needing to know the current network address of the service instances providing the desired information. It further relieves the application of the burden or knowing all the details of the communication protocols to extract data from the appropriate service or services and the need to know the details of the transport protocols needed to traverse the network. Further, it insulates the client applications from the need for programming changes when something else changes like changes in the service providers, e.g., a change from IDN to Ticker 3 for equity prices. All data is provided through a single, uniform interface to client applications. A programmer writing a client application needing information from three different services need not learn three different service specific communication protocols as he or she would in traditional communication models. Finally, the SASS automates many of the difficult and error prone tasks such as searching for an appropriate service instance and establishing a correct communication connection. 
     The SASS service discipline provides three basic functions which may be invoked through the user interface. 
     &#34;Subscribe&#34; is the function invoked when the consumer requests information on a real-time basis on one or more subjects. The SASS service discipline sets up any necessary communication connections to ensure that all data matching the given subject(s) will be delivered to the consumer application. The consumer can specify that data be delivered either asynchronously (interrupt-driven) or synchronously. 
     The producer service will be notified of the subscription if a registration procedure for its service has been set up. This registration process will be done by the SASS and is invisible to the user. 
     The &#34;cancel&#34; function is the opposite of &#34;subscribe&#34;. When this function is invoked, the SASS closes down any dedicated communication channel and notifies the producer service of the cancellation if a registration procedure exists. 
     The &#34;Receive&#34; function and &#34;callback&#34; function are related functions by which applications receive messages matching their subscriptions. Callbacks are asynchronous and support the event driven programming style. This style is well suited for applications requiring real time data exchange. The receive function supports a traditional synchronous interface for message receipt. 
     A complementary set of functions exists for a data producer. Also, applications can be both data producers and data consumers. 
     Referring to FIG. 17 there is shown a typical computer network situation in which the teachings of the invention may be profitably employed. The computer network shown is comprised of a first host CPU 300 in Houston coupled by a local area network (hereafter LAN) 302 to a file server 304 and a gateway network interconnect circuit 306. The gateway circuit 306 connects the LAN 302 to a wide area network (hereafter WAN) 308. The WAN 308 couples the host 300 to two servers 310 and 312 providing the Quotron and Marketfeed 2000 services, respectively, from London and Paris, respectively. The WAN 308 also couples the host 300 to a second host CPU 314 in Geneva and a server 316 in Geneva providing the Telerate service via a second LAN 318. Dumb terminal 320 is also coupled to LAN 318. 
     Typically the hosts 300 and 314 will be multitasking machines, but they may also be single process CPU&#39;s such as computers running the DOS or PC-DOS operating systems. There is available for public inspection in the prosecution history files of the United States Patent and Trademark Office corresponding to this patent a collection of some software modules, which were originally filed as an Appendix A to the patent application which matured into this patent, and which illustrate an exemplary way of carrying out at least some of the teachings of the invention as an aid to understanding thereof. The software modules in the files of the United State Patent and Trademark Office are ported for a Unix multitasking machine such as a sun workstation. Fair use of this software to understand the invention is permitted, but any other duplication, performance, adaptation or the unauthorized exercise of any other exclusive right given to copyright owners under the 1976 Copyright Act is strictly prohibited except that the United States Government is hereby licensed to print copies of this copyrighted material when printing the patent for purposes of dissemination of the contents thereof as part of this patent disclosure. To adapt the teachings of the invention to the DOS or other single task environments requires that the TIB communication daemon 30B in the process architecture be structures as an interrupt driven process which is invoked, i.e., started upon receipt of a notification from the operating system that a message has been received on the network which is on a subject to which one of the applications has subscribed. 
     The LAN&#39;s 302 and 318, WAN 308 and gateway 306 may each be of any conventional structure and protocol or any new structure and protocol developed in the future so long as they are sufficiently compatible to allow data exchange among the remaining elements of the system. Typically, the structures and protocols used on the networks will be TCP/IP, DECNET™, ETHERNET™, token ring, ARPANET and/or other digital pack or high speed private line digital or analog systems using hardwire, microwave or satellite transmission media. Various CCITT recommendations such as X.1, X.2, X.3, X.20, X.21, X.24, X.28, X.29, X.25 and X.75 suggest speeds, user options, various interface standards, start-stop mode terminal handling, multiplex interface for synchronous terminals, definitions of interface circuits and packet-network interconnection, all of which are hereby incorporated by reference. A thorough discussion of computer network architecture and protocols is included in a special issue of IEEE Transactions on Communications, April 1980, Vol. COM-28, which also is incorporated herein by reference. Most digital data communication is done by characters represented as sequences of bits with the number of bits per character and the sequence of 0&#39;s and 1&#39;s that correspond to each character defining a code. The most common code is International Alphabet No. 5 which is known in the U.S. as ASCII. Other codes may also be used as the type of code used is not critical to the invention. 
     In coded transmission, two methods of maintaining synchronism between the transmitting and receiving points are commonly used. In &#34;start-stop&#34; transmission, the interval between characters is represented by a steady 1 signal, and the transmission of a single 0 bit signals the receiving terminal that a character is starting. The data bits follow the start bit and are followed by a stop pulse. The stop pulse is the same as the signal between characters and has a minimum length that is part of the terminal specification. In the synchronous method, bits are sent at a uniform rate with a synchronous idle pattern during intervals when no characters are being sent to maintain timing. The synchronous method is used for higher speed transmission. 
     Protocols as that term is used in digital computer network communication are standard procedures for the operation of communication. Their purpose is to coordinate the equipment and processes at interfaces at the ends of the communication channel. Protocols are considered to apply to several levels. The International Organization for Standardization (ISO) has developed a seven level Reference Model of Open System Interconnection to guide the development of standard protocols. The seven levels of this standard hereafter referred to as the ISO Model and their functions are: 
     (1) Application: Permits communication between applications. Protocols here serve the needs of the end user. 
     (2) Presentation: Presents structured data in proper form for use by application programs. Provides a set of services which may be selected by the application layer to enable it to interpret the meaning of data exchanged. 
     (3) Session: Sets up and takes down relationships between presentation entities and controls data exchange, i.e., dialog control. 
     (4) Transport: Furnishes network-independent transparent transfer of data. Relieves the session layer from any concern with the detailed way in which reliable and cost-effective transfer of data is achieved. 
     (5) Network: Provides network independent routing, switching services. 
     (6) Data Link: Gives error-free transfer of data over a link by providing functional and procedural means to establish, maintain and release data links between network entities. 
     (7) Physical: Provides mechanical, electrical, functional and procedural characteristics to establish, maintain, and release physical connections, e.g., data circuits between data link entities. 
     Some data link protocols, historically the most common, use characters or combinations of characters to control the interchange of data. Others, including the ANSI Advanced Data Communication Control Procedure and its subsets use sequences of bits in predetermined locations in the message to provide the link control. 
     Packet networks were developed to make more efficient use of network facilities than was common in the circuit-switched and message-switched data networks of the mid-60&#39;s, In circuit-switched networks, a channel was assigned full time for the duration of a call. In message-switched networks, a message or section of a serial message was transmitted to the next switch if a path (loop or trunk) was available. If not, the message was stored until a path was available. The use of trunks between message switches was often very efficient. In many circuit-switched applications though, data was transmitted only a fraction of the time the circuit was in use. In order to make more efficient use of facilities and for other reasons, packet networks came into existence. 
     In a packet network, a message from one host or terminal to another is divided into packets of some definite length, usually 128 bytes. These packets are then sent from the origination point to the destination point individually. Each packet contains a header which provides the network with the necessary information to handle the packet. Typically, the packet includes at least the network addresses of the source and destination and may include other fields of data such as the packet length, etc. The packets transmitted by one terminal to another are interleaved on the facilities between the packets transmitted by other users to their destinations so that the idle time of one source can be used by another source. Various network contention resolution protocols exist to arbitrate for control of the network by two or more destinations wishing to send packets on the same channel at the same time. Some protocols utilize multiple physical channels by time division or frequency multiplexing. 
     The same physical interface circuit can be used simultaneously with more than one other terminal or computer by the use of logical channels. At any given time, each logical channel is used for communication with some particular addressee; each packet includes in its header the identification of its logical channel, and the packets of the various logical channels are interleaved on the physical-interface circuit. 
     At the destination, the message is reassembled and formatted before delivery to the addressee process. In general, a network has an internal protocol to control the movement of data within the network. 
     The internal speed of the network is generally higher than the speed of any terminal or node connected to the network. 
     Three methods of handling messages are in common use. &#34;Datagrams&#34; are one-way messages sent from an originator to a destination. Datagram packets are delivered independently and not necessarily in the order sent. Delivery and nondelivery notifications may be provided. In &#34;virtual calls&#34;, packets are exchanged between two users of the network; at the destination, the packets are delivered to the addressee process in the same order in which they were originated. &#34;Permanent virtual circuits&#34; also provide for exchange of packets between two users on a network. Each assigns a logical channel, by arrangement with the provider of the network, for exchange of packet with the other. No setup or clearing of the channel is then necessary. 
     Some packet networks support terminals that do not have the internal capability to format messages in packets by means of a packet assembler and disassembler included in the network. 
     The earliest major packet network in the U.S. was ARPNET, set up to connect terminals and host computers at a number of universities and government research establishments. The objective was to permit computer users at one location to use data or programs located elsewhere, perhaps in a computer of a different manufacturer. Access to the network is through an interface message processor (IMP) at each location, connected to the host computer(s) there and the IMP at other locations. IMP&#39;s are not directly connected to each other IMP. Packets routed to destination IMP&#39;s not connected directly to the source IMP are routed through intervening IMP&#39;s until they arrive at the destination process. At locations where there is no host, terminal interface processors are used to provide access for dumb terminals. 
     Other packet networks have subsequently been set up worldwide, generally operating in the virtual call mode. 
     In early packet networks, routing of each packet in a message is independent. Each packet carries in its header the network address of the destination as well as a sequence number to permit arranging of the packets in the proper order at the destination. Networks designed more recently use a &#34;virtual circuit&#34; structure and protocol. The virtual circuit is set up at the beginning of a data transmission and contains the routing information for all the packets of that data transmission. The packets after the first contain the designation of the virtual circuit in their headers. In some networks, the choice of route is based on measurements received from all other nodes, of the delay to every other node on the network. In still other network structures, nodes on the network are connected to some or all the other nodes by doubly redundant or triply redundant pathways. 
     Some networks such as Dialog, Tymshare and Telenet use the public phone system for interconnection and make use of analog transmission channels and modems to modulate digital data onto the analog signal lines. 
     Other network structures, generally WAN&#39;s, use microwave and/or satellites coupled with earth stations for long distance transmissions and local area networks or the public phone system for local distribution. 
     There is a wide variety of network structures and protocols in use. Further, new designs for network and transport protocols, network interface cards, network structures, host computers and terminals, server protocols and transport and network layer software are constantly appearing. This means that the one thing that is constant in network design and operation is that it is constantly changing. Further, the network addresses where specific types of data may be obtained and the access protocols for obtaining this data are constantly changing. It is an object of the communication interface software of the invention to insulate the programmer of application programs from the need to know all the networks and transport protocols, network addresses, access protocols and services through which data on a particular subject may be obtained. By encapsulating and modularizing all this changing complexity in the interface software of the invention, the investment in application programs may be protected by preventing network topology or protocol dependencies from being programmed into the applications. Thus, when something changes on the network, it is not necessary to reprogram or scrap all the application programs. 
     The objectives are achieved according to the teachings of the invention by network communications software having a three-layer architecture, hereafter sometimes called the TIB™ software. In FIG. 17, these three layers are identified as the information layer, the service layer and the distributed communication layer. Each application program is linked during the compiling and linking process to its own copy of the information layer and the service layer. The compiling and linking process is what converts the source code of the application program to the machine readable object code. Thus, for example, application program 1, shown at 340, is directly linked to its own copy of layers of the software of the invention, i.e., the information layer 342 and the service layer 344. Likewise application 2, shown at 346 is linked to its own copies of the information layer 348 and the service layer 350. These two applications share the third layer of the software of the invention called the distributed communication layer 352. Typically there is only one distributed communication layer per node (where a node is any computer, terminal or server coupled to the network) which runs concurrently with the applications in multitasking machines but which could be interrupt drivers in nonmultitasking environments. 
     The second host 314 in Geneva in the hypothetical network of FIG. 17 is running application program 3, shown at 354. This application is linked to its copies of the information layer 356 and the service layer 358. A concurrently running distributed communication layer 360 in host 2 is used by application 354. 
     Each of the servers 310, 312 and 316 have a data producer versions of the 3 layer TIB™ software. There is a data consumer version of the TIB™ software which implements the &#34;subscribe&#34; function and a data producer version which implements the &#34;publish&#34; function. Where a process (a program in execution under the UNIX™ definition) is both a data consumer and a data publisher, it will have libraries of programs and interface specifications for its TIB™ software which implement both the subscribe and publish functions. 
     Each of the hosts 300 and 314 is under the control of an operating system, 370 and 372, respectively, which may be different. Host 1 and host 2 may also be computers of different manufacturers as may servers 310, 312 and 316. Host 1 has on-board shared memory 374 by which applications 340 and 346 may communicate such as by use of a UNIX™ pipe or other interprocess communication mechanism. Host 2 utilizes memory 378. 
     In a broad statement of the teachings of the invention, the information layer, such as 342, encapsulates the TIBINFO™ interface functionality, and the subject-based addressing functionality of the TIB™ software communication library 30A of FIGS. 15 and 16. The TIBINFO interface is defined in Section 4 of the software specification below. TIBINFO defines a programmatic interface by which applications linked to this information layer may invoke the protocols and services of the Subject-Addressed Subscription Service (SASS) component. 
     FIG. 18 clarifies the relationships between the process architecture of FIG. 15, the software architecture of FIG. 16 and the 3 layers for the TIB™ software shown in FIG. 17. In FIG. 15, the communications library 30A is a library of programs which are linked to the application 16 which provide multiple functions which may be called upon by the RMDP and TIBINFO interfaces. Subject-Addressed Subscription Services are provided by subject mapper programs and service discipline programs in the component labeled 30A/30B. This component 30A/30B also includes library programs that provide the common infrastructure program code which supports, i.e., communicates with and provides data to, the protocol engine programs of the TIB communication daemon 30B. 
     The TIBINFO interface is devoted to providing a programmatic interface by which linked client applications may start and use subject-addressed subscriptions for data provided by data producers on the network wherever they may be. 
     The RMDP interface provide the programmatic interface by which subscriptions may be entered and data received from services on the network by linked client applications which already know the names of the services which supply this data. The communication library 30A in FIG. 15 supplies library programs which may be called by linked client applications to implement the Market-Data-Subscription Service (MDSS). This function creates subscription data requested by service names by setting up, with the aid of the daemon&#39;s appropriate protocol engine, a reliable communication channel to one or more servers which supply the requested data. Failures of individual servers are transparent to the client since the MDSS automatically switches to a new server which supplies the same services using the appropriate protocol engine. The MDSS also automatically balances the load on servers and implements entitlement functions to control who gets access to a service. The reliable communication protocols of the DCC library 30A/30B such as intelligent multicast and reliable broadcast and the protocol engines of the daemon 30B are invoked by the MDSS library programs. More details are given in Section 3 of the TIB™ Specification given below. 
     Referring to FIG. 19, which is comprised of FIGS. 19A and 19B, there is shown a flow chart for the process carried out, inter alia, at each of the 3 layers on the subscriber process side for entering a subscription on a particular subject and receiving data on the subject. Step 400 represents the process of receiving a request from a user for data on a particular subject. This request could come from another process, another machine or from the operating system in some embodiments. For purposes of this example assume that the request comes to application 1 in FIG. 17 from a user. 
     Application 1 (on the application layer or layer 1 of the ISO Model) then sends a &#34;subscribe request&#34; to information layer 342 in FIG. 17. This process is represented by step 402 in FIG. 19. This subscribe request is entered by calling the appropriate library program in the linked library of programs which includes the TIB-INFO interface. This subroutine call passes the subject on which data is requested and a pointer to the callback routine in the requesting process that the TIB-INFO library program on the information layer is to call when messages are received on this subject. 
     The information layer 342 encapsulates a subject-to-service discipline mapping function which provides architectural decoupling of the requesting process as that term is defined in the glossary herein. Referring to steps 404 and 406 in FIG. 19 and to FIG. 17, the input to the information layer is the subject and the output is a call to a service discipline on the service layer 344 in FIG. 17. The information layer includes the TIB-INFO interface and all library programs of the linked communications library 30A in FIG. 15 involved with subject-to-service mapping. The information layer maps the subject to the service or services which provide data on this subject as symbolized by step 404 and then maps this service or services to one or more service disciplines that encapsulate communication protocols to communicate with these services. This information layer then coordinates with the service discipline to assign a &#34;TIB channel&#34; as symbolized by step 410. 
     A &#34;TIB channel&#34; is like an &#34;attention: Frank Jones&#34; line on the address of a letter. This TIB channel data is used to route the message to the process which requested data on whatever subject is assigned to that TIB channel. Each subject is assigned a TIB channel when a subscription is entered. There is a subscription list that correlates the subscribing processes, their network addresses, the subjects subscribed to and the TIB channel numbers assigned to these subjects. Data on this list is used by the daemon to route messages received at its port address to the proper requesting process. This list is also used on the data publisher side to cause messages on particular subjects to be routed to the port address of the machine on which the requesting process is running. The communication layer of the TIB software associated with the service writes the channel number data in the headers of packets from messages on particular subjects before these packets are transmitted on the network. At the receiver side, the TIB channel data in the header causes proper routing of the packet to the requesting process. The TIB channel abstraction and the routing function it implies is performed by the DCC library portion 30A/30B in FIG. 18 which is linked to each requesting process. 
     Assuming there are two such services, these services are then mapped by the service disciplines on the service layer to the servers that provide these services as symbolized by step 412. 
     In one embodiment, the information layer selects and calls only one of the service discipline subroutines in the service layer as symbolized by step 406. The service discipline then runs and assigns a TIB channel to the subscription subject as symbolized by step 410. The call from the information layer also passes the pointer to a callback routine in the information layer to be called when messages on the subject arrive. 
     In alternative embodiments, the information layer may call all the service disciplines identified in the subject-to-service discipline mapping process so as to set up communication links with all the services. 
     In some embodiments, the names of alternative services and alternative servers are passed to the selected service discipline or directly to the distributed communication layer by the information layer for use in setting up alternate communication links. This allows the distributed communication layer to set up an alternate communication link to another server in case of failure of the selected server or for simultaneous communication link setup to increase the throughput of the network. In still other embodiments, the requesting process can call the service layer directly and invoke the appropriate service discipline by doing the subject-to-service discipline mapping in the application itself. The data regarding alternate services and servers can be passed by calling a library subroutine in the DCC library of block 30A/30B in FIG. 18 which runs and stores the data regarding the alternates. 
     In alternative embodiments, the information layer may assign the TIB channel to each subject or the service layer may assign the TIB channel acting alone without coordinating with the information layer. Step 410 represents the embodiments where the service discipline assigns the TIB channel number by coordinating with the information layer. Messages sent by data provider processes will have the assigned subject channel data included as part of their header information. 
     TIB channels are used by the communication layer (DCC) for filtering and routing purposes. That is, the daemon 30B in FIG. 15 and protocol engines 30B in FIG. 18 know when a message arrives at the daemon&#39;s port address having particular TIB channel data in the header that there are outstanding subscriptions for data on this subject. The daemon process knows the channels for which there are outstanding subscriptions because this information is sent to the communication layer by the service layer. The daemon 30B stores data received from the service discipline regarding all TIB channels having open subscriptions. The daemon then sends any message on a subject having an open subscription to processes at that port address which have subscribed to messages on that subject. The daemon does not know what the subject is but it does know there is a match between TIB channels having open subscriptions and subjects of some of the incoming messages. 
     Each node coupled to the computer network of FIG. 17 such as host 300 has one network interface card and one port address. This port address may be assigned a &#34;logical channel&#34; in some networks for multiplexing of the network card by multiple processes running simultaneously on the same host. These port addresses may sometimes hereafter also be referred to as network addresses. How data gets back and forth between network addresses is the responsibility of the communication layers such as layer 352 in FIG. 17 which invokes the transport layer, network layer, data link layer and physical layer functionalities of the operating systems 370 and 372, network interface cards (not shown) and other circuits on the network itself such as might be found in gateway 306 and WAN 308. 
     The service layer, information layer and communication layer are layers which are &#34;on top&#34; of the ISO model layers, i.e., they perform services not performed on any layer of the ISO model or they perform &#34;value added&#34; services as an adjunct to services performed on an ISO model layer. 
     The purpose of the service layer is, among other things, to provide service decoupling as that term is defined in the glossary herein. Service decoupling frees the application of the need to know the whereabouts on the network of servers providing a service and the details of how to communicate. To perform this function, the service layer includes a program or function to map the selected service to all servers that provide this service and pick one (step 412 in FIG. 19). The service layer then maps the selected server to a protocol engine that encapsulates the communication procedures or protocols necessary to traverse the network, i.e., set up a data link regardless of the path that needs to be followed through the network to get to this server, and communicate with the selected server regardless of what type of machine it is, what type of network and network card it is coupled to and what operating system this server runs. This process is symbolized by step 414. 
     In alternative embodiments, the application or subscribing process may call the protocol engine directly by having done its own subject based addressing and encapsulating its own communication protocol. In other alternative embodiments, the service layer will select all the servers supplying a service and request the communication layer to set up data links with all of them simultaneously to increase the throughput of the network or to use one server and switch to another upon failure of the selected server. 
     Normally all services that provide a selected service are assumed to use the same communication protocol so a single service discipline can communicate with them all. However, if different instances of the same services or different services providing data on the same subjects use different communication protocols, the teachings of the invention contemplate subclasses of service disciplines. This means that the information layer will call a generic service discipline which contains code which can be shared by all subclasses of this service discipline to do common functions such as subscribe or cancel which are done the same way on all servers that provide this service. The generic service discipline will then map the subscription request to one or more of the different servers that provide the service. The service discipline(s) code which encapsulates the communication procedure peculiar to the selected server(s) is then called and runs to finish the process of setting up the subscription data stream with the selected server(s). 
     The output of the service layer is a request to the communication layer to the effect, &#34;set up a communication link by whatever means you deem most appropriate with the following server or services on the following subject channel.&#34; The service layer also sends a pointer to the service layer callback routine which will handle messages or packets on the requested subject. This process is symbolized by step 416. In some embodiments the network addresses of all servers that run service processes supplying data on the requested subject are passed to a DCC library program which stores them for use in providing a reliable communication link by providing failure recovery in case the selected server crashes. 
     Step 418 represents the process where the selected protocol engine sets up the requested data link by invoking selected functions of the transport layer protocols encapsulated in the operating system. These protocols invoke other communication protocols on the network, data link and physical layers so as to set up the requested data link and log onto the service as symbolized by step 420. The service layer service discipline usually then sends a message to the service notifying it of the subscription and the subject channel assigned to this subject as symbolized by step 422. The subject channel is noted by the information service and/or communication layer of the TIB interface software linked to the service. This allows the subject channel data to be added to the packet headers of transmitted packets on the subject of interest. This subscription message starts the flow of data in some embodiments, while in other embodiments, the flow of data starts when the data link to the server is first established. 
     In some embodiments, a single subscription may necessitate calling multiple services, so the information layer may map the subject to multiple service disciplines. These in turn map the request to multiple protocol engines which simultaneously set up data links to the multiple services. 
     In some alternative embodiments, the service disciplines talk directly to the transport layer and encapsulate the protocols necessary to communicate on the current network configuration. In these embodiments, the service layer may filter incoming messages by subject before calling the callback routine in the information layer. 
     On small networks, an alternate embodiment is to broadcast on the network subscription requests to particular subjects. Services coupled to the network listen to these broadcasts and send messages on the subjects of interest to the port addresses identified in the broadcasts. These messages are then directed by the DCC layer at the port address to the requesting process in the manner described elsewhere herein. 
     In alternative embodiments, the service layer also performs other functions such as: regulating access to certain services; session management in the traditional sense of the session layer of the ISO model; replication management of replicated services and servers; failure/recovery management in case of failure of a service; distribution management; load balancing to prevent one server or service from being inequitably loaded with data requests when other services/servers can fill the need; or, security functions such as providing secure, encoded communications with a server. Of particular importance among these alternate embodiments are the embodiments which encapsulate service recovery schemes on the service layer. In these embodiments, when a server goes down, a recovery scheme to obtain the same data elsewhere encapsulated in the appropriate service discipline is run to re-establish a new data link to an alternate server as symbolized by step 424. 
     In the preferred embodiment, the service discipline assigns the TIB channel to the subject and picks the protocol engine to use in terms of the characteristics of the server and the service to be accessed and the network and network protocol to be used, and in light of the degree of reliability necessary. 
     The daemon 30B in FIGS. 15 and 18 can include many different protocol engines, each of which has different characteristics. For example there may be a protocol engine for point-to-point communication between nodes having Novell network interface cards and using the Novell protocol and a protocol engine for point-to-point communications between nodes using the TCP and UDP protocols and associated network interface cards. There may also be a protocol engine for communication with high speed data publishers using reliable broadcast, and a protocol engine for either point-to-point or reliable broadcast communication using the Intelligent Multicast™ protocol. There can be as many protocol engines as there are options for communication protocols, types of servers and services and reliability options as are desired, and more can be added at any time. 
     Further, some of the service disciplines may be procedures for communicating with other processes on the same machine such as the operating system or another application or directly with a user through a terminal. More service disciplines can be added at any time to communicate with new sources of information. 
     A service discipline, when it receives a subscription request may open a specific TIB channel for that subject or allow any arbitrary TIB channel to be used. 
     The selected service discipline or disciplines pick the protocol engine that has the right characteristics to efficiently communicate with the selected service by calling a DCC library program. The DCC library programs updates the subscription list with the new subscription and channel data and send a message to the selected protocol engine via shared memory or some other interprocess transfer mechanism. If the host is not multitasking, the daemon will be caused to run by an interrupt generated by the DCC library program. The message to the selected protocol engine will be as previously described and will include the identity of the selected server. The protocol engine will map the identity of this server to the network address of the server and carry out the communication protocol encapsulated within the selected protocol engine to set up the data link. Some of these protocols are value added protocols to, for example, increase the reliability of generic transport layer broadcast protocols or to do intelligent multicasting. These value added protocols will be detailed below. This step is symbolized by step 426. 
     The distributed communication layers 352 and 360, function to provide configuration decoupling. This eliminates the need for the requesting process to know how to do various communication protocols such as TCP, UDP, broadcast etc and to have code therein which can implement these protocols. The protocol engines implement various communication protocols and the DCC library implements the notion of TIB channels and performs routing and filtering by subject matter based upon the TIB channel data in the packet headers of incoming packets. The protocol engine for communicating using the UDP protocol also does message disassembly into packets on the service or transmit side and packet reassembly into complete messages on the subscribing process or receive side. This is a value added service since the UDP transport protocol does not include these disassembly and reassembly functions. The TCP transport protocol includes these message disassembly and packet reassembly functions so the protocol engine that invokes this transport layer function need not supply these type value added services. 
     In some embodiments of the invention, the UDP protocol engine adds sequence numbers and data regarding how many packets comprise each complete message to the packet headers. This allows the daemon or DCC library of the receiving process TIB communication layer to check the integrity of the message received to insure that all packets have been received. 
     As data packets come in from the network, they are passed up through the DCC library, service layer and information layer to the subscribing process. The service layer in some embodiments may filter the incoming messages by subject matter instead of having this filtering done by the daemon or the DCC library as in other embodiments. In still other embodiments, the filtering by subject matter is done by the information layer. 
     In some embodiments, the service layer also performs data formatting by calling programs in the TIB FORMS interface 231 in FIG. 15 or the TIB Forms Library 32 in FIG. 15. 
     In some embodiments, the subject based addressing is done by collecting all the information a subscribing process could ever want in a gigantic data base and organizing the data base by subject matter with updates as data changes. The service layer would then comprise routines to map the subject request to data base access protocols to extract data from the proper areas of the data base. The communication layer in such embodiments maps incoming update data to update protocols to update the appropriate date in the data base. 
     The preferred embodiment implements the more powerful notion of allowing the data sources to be distributed. This allows new servers and services to be coupled to the system without wrecking havoc with all the existing application software. The use of the information, service and communication layers of the TIB software according to the teachings of the invention provides a very flexible way of decoupling the application software from the ever changing network below it. 
     In the preferred embodiment, the filtering by subject matter for point-to-point protocols is done by the TIB software on the transmit side. Note that in FIG. 17, the servers 310, 312 and 316 are decoupled from the network by TIB interface software symbolized by the blocks marked &#34;TIB IF&#34;. Terminal 320 is also decoupled in the same manner and can be a service for manual entry of data by the user. Specifically, this filtering is done by the information layer bound to the service which is publishing the data. For a service that is using the broadcast transport protocol, the TIB communication layer at the network addresses receiving the broadcast would filter out all messages except those having subjects matching open subscriptions by comparing the TIB channel data to the channel data for open subscriptions listed in the subscription table based upon subscription data generated by the information layer and TIB channel data generated by the service layer. Note that where a service simply broadcasts data, the service discipline for accessing that service can be as simple as &#34;listen for data arriving at the following network address and filter out the messages on other than the subscribed subject.&#34; The service discipline would then format the data properly by invoking the proper function in the TIB Forms Library and pass the data through the information layer to the requesting process. 
     The use of the communication layer allows all the network configuration parameters to be outside the applications and subject to revision by the system administrator or otherwise when the network configuration changes. This insulates the application software from the network interface and provides a functionality similar to and incorporating at least all the functionality of the ISO Model network layer. 
     Note also that in some embodiments, the functionality of the information, service and communication layers could also be easily implemented in hardware rather than the software of the preferred embodiment. The service and communication layers implement most of the functionality the ISO Model Network, Data Link and Physical layers plus more. 
     In some embodiments, the distributed communication layer only receives a general request from the service layer to set up a data link and decides on its own which is the most efficient protocol to use. For example, the DCC may receive 5 separate subscriptions for the same information. The DCC may elect on its own to set up 5 separate data links or bundle the requests, set up one data link and distribute the arriving message by interprocess transfers to each of the 5 requesting processes. In other embodiments, the DCC may act on its own to decide which protocol to use, but may accept things from the service layer such as, &#34;I want this fast&#34; or &#34;I want this reliable&#34;. In the latter case, the communication layer may elect to send two subscriptions for the same information to two different services or may set up two different links to the same service by different network paths. 
     In the preferred embodiment, the DCC library portion of the communication library serves the sole function of determining how to best get data from one network address to another. All replication management and failure recovery protocols are encapsulated in the service disciplines. 
     Referring to FIG. 20, comprised of FIGS. 20A and 20B, there is shown a flow chart for the processing involved at the three layers of the TIB software on the transmit side in creating a subscription data stream at a publishing process or service and sending it down through the TIB software and across the network to the subscribing process. 
     Step 430 represents the process whereby the selected service receives a message from a subscribing process and initiates a data stream. Each service such as the Quotron service running on server 310 in FIG. 17 and the Marketfeed 2000 and Telerate services running on servers 312 and 316, respectively, are decoupled from the network by a version of the three layer architecture TIB software according to the teachings of the invention. This is symbolized by the blocks marked TIB IF in these server boxes which stands for TIB interface software. 
     The TIB interface for each service decouples the service from any requirement to have functionality capable of supporting filtering or subject based addressing. Thus, if a service is designed to broadcast all equity prices on the American Stock Exchange and Over-the-Counter market, but the subscription is simply for IBM equity prices, the service responds as it always has and need not have a function to filter out only IBM equity prices. The service discipline for this type service will be adapted to filter out all messages except IBM equity prices in response to such a subscription request. 
     Another service like Telerate which publishes many different pages organized by subject matter, e.g., a page on Government T-Bill rates, a page on long term corporate bond rates etc., will be able to accept a subscription for only a specific page and ma be able to accept special commands to caused the service to publish only specific columns on a particular page. In such a case, the service layer bound to such a service will include a service discipline which receives subscription requests by subject and filters messages out from a broadcast that do not pertain to a subject having an open subscription. 
     Step 430 also represents the process of the service calling the TIB-Publish function of the information layer TIB-INFO library and starting the flow of data toward the subscribing process. The service need not have any of its own ability to filter by subject. The subscription request it receives is in the &#34;native tongue&#34; that this service understands because it is formatted and sequenced in that fashion by the service discipline of the subscribing process. 
     Most of the filtering by subject matter is done by the service disciplines, but where this filtering is done depends upon the type of service. Some services publish only one type of data so everything such a publisher puts out is of interest to the subscribing process. For example, assume that the service accessed is the real time clock 371 in FIG. 17 which puts out only the current time, and assume that the subject of the subscription is &#34;give me the time of day&#34;. In such a case, the service discipline is very simple and no filtering need occur. Such a service discipline can be simply a protocol to determine how to communicate the data to the requesting process and what TIB channel to assign to it. 
     The fact that the service starts sending data in whatever manner such a service normally sends data is symbolized by step 432. Thus, if the service is Telerate, it can send the page image and updates for any one of a number of different pages and it understands a subscription for only one of its many pages whereas the Quotron service would not understand a subscription for only IBM equity prices. The various service disciplines of the service layer provide, inter alia, the necessary functionality which the service does not have. 
     Step 432 assumes a service which broadcasts messages on many different subjects and a subscription request for only one or a few of those subjects. In other hypothetical examples, the service may publish only the requested information such as a particular telerate page. In the Telerate case, the subscription request may specify that only a particular page and particular columns of that page be sent and may request the page image by a point-to-point communication protocol using a dedicated TIB channel. 
     Step 434 represents the response processing of the service layer to the subscription request and the stream of data that results. In step 434, the service discipline does any necessary filtering by subject matter and assigns the TIB channel number. The filtering by subject matter is generally done by the service discipline on the data producer side of an exchange only when the producer produces vastly more data than is called for by the subscription such as in the case of a high speed, broadcast producer. In such a case, the extraneous data could overwhelm the network. The TIB channel numbers are assigned by the service discipline in step 434 but they are not actually added to the headers for the packets until the message reaches the communication layer. In some alternative embodiments, the TIB channel numbers may be written to the packet headers by the service discipline. 
     The TIB channel number assignment is done by the service discipline based upon the type of service, subscription and communication protocol being used. Where a broadcast protocol is being used, the service discipline in some embodiments will, in step 434, simply assign different TIB channel numbers to different subjects and send a message to subscribers listed in a subscription table maintained by the service layer on the information layer. The message will say simply, for example, &#34;for updates on IBM equity prices, monitor TIB channel 100.&#34; Note that the TIB channel data is used by the TIB software of the receiving host solely to route messages to the proper subscribing processes. TIB channels have nothing to do with logical channels, network routing or other network, data link or physical layer issues. 
     In other embodiments, in the broadcast protocol situation, the service discipline will consult a subscription list and filter out all messages on subjects other than subjects with open subscriptions. For those subjects, a TIB channel will be assigned and a message will be sent to the TIB software linked to the subscribing processes as to what TIB channels to listen to for messages to be routed to their client processes. 
     In the case of point-to-point protocols, the subscription requests usually contain the TIB channel numbers assigned to the subject by the service discipline selected by the information layer linked to the subscribing process. In such a case, step 434 represents the process of assigning the TIB channel number received in the subscription request to messages emitted from the service. In a typical case of subscription to a Telerate page which specifies that a particular TIB channel is to be used in case a point-to-point protocol is selected, the service discipline will send the page image by selecting a point-to-point protocol engine. The service discipline will also send a message acknowledging the subscription and advising the TIB software of the subscribing process to listen to a particular TIB channel for broadcasts of updates to the page. The receiving TIB software then opens a TIB broadcast channel for the updates. 
     Step 436 represents the processes performed by the DCC library after the service discipline calls it. The DCC library&#39;s sole function in the preferred embodiment is to determine the best way to send a message to any particular network address where the service discipline or the subscription request does not specify the communication protocol to be used. In some embodiments, the DCC library of the communication layer will accept suggestions from the service layer or subscription request as to how to send the message but may select a different protocol if this is deemed to be more efficient. 
     Further, the DCC library may change the communication protocol being used based upon changing conditions such as number of subscribers. For example, an Intelligent Multicast protocol may be chosen (described in more detail below). In this protocol, a point-to-point protocol is used when the number of subscribers is below a certain cutoff number (programmable by the system administrator) but switchover to a broadcast protocol automatically occurs when the number of subscribers rises above the cutoff number. In the preferred embodiment &#34;high-water&#34; and &#34;low-water&#34; marks are used as will be described below. In other embodiments, any cost function may be used to set the switchover point based upon cost and efficiency of sending multiple point-to-point messages as opposed to a single broadcast message. 
     Step 436 also represents the process of retrieving the message from local memory of the service and putting it into an interprocess transfer process to send it to the protocol engine/daemon 30B in FIG. 15. 
     Step 438 represents the processes carried out by the protocol engine of the service to transmit the messages to the subscribing processes. If the transport protocol in use is UDP, the protocol engine, in some embodiments, will do a packetizing function. This is the process of breaking down the message into packets and adding header data on the transmit side and reassembling the packets in the proper order on the receiver side. The TCP transport protocol does its own packetizing, so protocol engines that invoke this transport layer need not packetize. Nonpacket protocol engines also exist for other types of transport protocols. 
     The protocol engine also writes the port address of the machine running the subscribing process in the message headers and may perform other value added services. These other services include reliable broadcast and Intelligent Multicasting. Reliable broadcast services will be explained below, but basically this service provides functionality that does not exist in current broadcast communication protocols to increase reliability. 
     The protocol engines have a standard programmers interface through which they communicate with the transport layer routines in the operating system. The steps taken by the protocol engine to invoke the transport layer functionality so as to drive the network, data-link and physical layer protocols in such a manner so as to deliver the messages to the subscribing processes are not critical to the invention. This process is symbolized by steps 440 and 442. Exactly what these steps are cannot be specified here because they are highly dependent upon the structure, configuration and protocol of the network as well as the interface to the transport layer. When any of these change, the protocol engines may have to be changed to accommodate the change to the network. This, however, prevents the need to change the application software thereby providing configuration decoupling. 
     After the message traverses the network, it is picked up by the network interface card having the port address shared by the subscribing process. This process is symbolized by step 444. The network card buffers the message and generates an interrupt to the transport layer routine which handles incoming messages. 
     Step 446 represents the process where the transport layer software calls the appropriate protocol engine of the daemon 30B in the communication layer such as layers 352 or 360 in FIG. 17. The incoming message or packet will be passed to the appropriate protocol engine by some interprocess transfer mechanism such as shared memory. In the preferred embodiment, the daemon is an ongoing process running in background on a multitasking machine. In other embodiments, the daemon is interrupt driven and only runs when a message has been received or is to be transmitted. Step 446 also represents the packet reassembly process for TCP or other transport layer protocols here packet reassembly is done by the transport layer. 
     Step 448 represents the processes performed by the protocol engine in the daemon to process and route the incoming message. 
     For UDP transport layer protocol engines, packet reassembly is done. This of course implies that the protocol engine of the data producer process added sequence numbers to the packet headers so that they could be reassembled in the proper order. Other value added services may then be performed such as checking all the sequence numbers against data which indicates the sequence numbers which should have arrived to determine if all the packets have been received. In some embodiments, the data as to the sequence numbers to expect is written into fields dedicated to this purpose in the packet headers. In other embodiments, this data is sent in a separate message. 
     If any packets are missing, a message will automatically be sent by the receiving communication layer back to the data producer process&#39; communication layer to request retransmission of any lost or garbled packets. This of course implies that the communication layer for the data process stores all packets in memory and retains them for possible retransmission until an acknowledgment message is received indicating that all packets have been successfully received. 
     Step 448 also symbolizes the main function performed by the communication layer daemon/protocol engine in receiving messages. That function is routing the messages to the appropriate subscribing process according to the TIB channel information in the header. The protocol engine checks the TIB channel number in the header against the current subscription list sent to it by the service discipline. The subscription list will include pointers to the appropriate service discipline callback routine and subscribing process for messages assigned to any particular TIB channel. The protocol engine also filters messages by TIB channel number for embodiments in which messages reach the subscribing process&#39; TIB software which do not pertain to the subscribed to subject. This may also be done at the service layer or information layer but it is most efficient to do it at the communication layer. 
     The protocol engine will then put the message in the appropriate interprocess transfer mechanism, usually shared memory or a Unix™ pipe, and generate an interrupt to the DCC library as symbolized by step 450. This interrupt will vector processing to the appropriate DC library callback routine which was identified to the protocol engine by the DCC library when the subscription on this TIB channel and subject was opened. The DCC library routine so invoked is linked to and part of the subscribing process which initiated the subscription. The DCC library callback routine then retrieves the message from the interprocess transfer mechanism and stores it in local memory of the subscribing process. The DCC library callback routine then generates an interrupt to the service layer and passes it a pointer to the message. 
     Step 452 represents the process performed by the service layer on incoming messages. The interrupt from the DCC library causes to run the service discipline callback routine identified in the original subscribe message passed by the service layer through the DCC library. The callback routine will, in some embodiments, do any data format conversions necessary and may, in other embodiments do subject matter filtering. Then, the service discipline generates an interrupt to the information layer which cause the callback routine of the information layer to run. The interrupt contains a pointer to the message. 
     Step 454 symbolizes processing of incoming messages by the information layer. In some embodiments, the service layer does not guarantee that all messages reaching the information layer exactly match the subject for which data was requested. In these embodiments, step 454 symbolizes the process of comparing the TIB channel code to the subject of the subscription to make sure they match. If the data has been previously filtered by subject, step 454 cab be eliminated. 
     Step 456 symbolizes the process of generating an interrupt to the callback routine of the subscribing process if there is a match on subject. If not, no interrupt is generated and monitoring for new messages continues by the daemon while all the interrupt driven processes terminate and release their computer resources until the next interrupt. 
     Step 458 symbolizes the process of use of the message data for whatever purpose the subscribing process originally sought this data. 
     Reliable broadcast is one of the value added services that the communication layer can use to supplement and improve the communication protocols of the transport layer. Traditional broadcast protocols offered by prior art transport layers are not reliable. For example, if there is noise on the line which corrupts or destroys a packet or message or if the network interface card overflows the buffer, packets or entire messages can be lost and the processes listening for the message never gets the message, or they get an incomplete or garbled message. There is no acknowledge function in traditional broadcast, so if some of the processes miss the message or get incomplete or garbled messages, the transmitting process never finds out. This can happen for one in every hundred packets or for one in ten packet Traditional prior art transport layer broadcast protocols do not include functionality, i.e., program code, to distribute a broadcast message received at the network address of the host to multiple processes running on that host. 
     The communication layer according to the teachings of the invention includes at least one protocol engine to implement reliable broadcast protocols which are built on top and supplement the functionality of the prior art transport layer broadcast protocols. Referring to FIG. 21 comprised of FIGS. 21A and 21B, there is shown a flow chart for one embodiment of a reliable broadcast protocol implemented by the communication layer. Step 500 represents the process where the DCC library receives a request from a service discipline to send a message having a particular TIB channel assigned thereto. In some embodiments, this request may also include a request or a command to send the message by the reliable broadcast protocol. In embodiments where the reliable broadcast protocol is mandated by the service discipline, the service discipline includes a function to determine the number of subscribers to a particular channel and determine the cost of sending the same message many times to all the port addresses of all subscribers versus the cost of sending the message once by broadcast with messages to all subscribers to listen to TIB channel XX (whatever TIB channel number was assigned to this subject) for data on the subjects they are interested in. In the embodiment illustrated in FIG. 21, this cost determination function is included within the communication layer DCC library functionality. 
     Step 502 represents this cost determination process as performed by the DCC library. The particular program of the DCC library which implements this function, checks the subscription list and counts the number of subscribers to the TIB channel assigned to this message. The cost of sending the message point-to-point to all these subscribers is then evaluated using any desired costing function. In some embodiments, the cost function may be a comparison of the number of subscribers to a predetermined cutoff number. The particular cost function used is not critical to the invention. The cost of sending the message to multiple subscribers point-to-point is that the same message must be placed repeatedly on the network by the data producing software. The cost of broadcasting a message is that all network cards pick it up and may interrupt the transport protocol program in the operating system of the host which transmits the message by interprocess transfer to the TIB daemon only to find out the message is not of interest to any client process running on that host. Computer resources are thus wasted at any such host. 
     Step 504 represents the process the DCC library carries out to evaluate the cost and decide to send the message either by point-to-point protocol or reliable broadcast. If it is determined that the number of subscribers to this TIB channel is small enough, the decision will be made to send the message by a point-to-point protocol. Step 506 represents the process of calling the point-to-point protocol engine and sending the message using this protocol. 
     If the number of subscribers is too high for efficient point-to-point transmission, the DCC library calls the reliable broadcast protocol engine as symbolized by step 508. 
     Step 510 represents the first step of the reliable broadcast protocol processing. The reliable broadcast protocol according to the teachings of the invention supports multiple subscribing processes running of the same host and requires that each subscribing process receive all the packets of the message without error and acknowledge receipt thereof. The insure that this is the case, sequence numbers must be added to the headers of each packet and some data must be communicated to the subscribing processes that indicate the sequence numbers that must all have been received in order to have received the entire message. In some embodiments, only the sequence numbers will be added to the packet headers and the data regarding the sequence numbers that comprise the entire message will be sent by separate message to each process having an open subscription to the TIB channel assigned to the message. In other embodiments, the sequence numbers that comprise the entire message will be added to the header of the first packet or to the headers of all the packets. The sequence numbers added to the packets are different than the sequence numbers added by packetizing functionality of the transport protocols of the operating system in TCP protocols since the TIB sequence numbers are used only to determine if all packets of a message have been received. In some embodiments, the packet sequence numbers added by the transport protocol may be used by the TIB communication layer of the subscribing processes to determine if all the packets have been received. In other embodiments of reliable broadcast protocol engines for supplementing the UDP transport layer protocol, the packetizing function of the protocol engine adds sequence numbers which can be used both for transport/network/data link/physical layer functions but also for TIB communication layer functions in verifying that all packets of a message have been received. 
     After the sequence numbers have been added, the packets are written to a retransmit buffer with their sequence numbers for storage in case some or all of the packets need to be retransmitted later as symbolized by step 512. 
     Before the messages can be sent to the various subscribing processes, the reliable broadcast protocol engine adds the TIB channel data to the header of each packet and sends a message to each subscribing process listed in the subscription table as having open subscriptions for this channel to listen for data on their requested subject on TIB channel XX where XX is the TIB channel number assigned to this subject. 
     Step 516 represents the process of transmitting the packets via the standard broadcast protocols of the transport layer by calling the appropriate operating system program and passing a pointer to each packet. 
     Referring to FIG. 22 comprised of FIGS. 22A and 22B, there is shown a flow chart of the processing by the communication layer of the subscribing process in the reliable broadcast protocol. The packets broadcast on the network are picked up by all network interface cards of all hosts on the network which then invoke the transport protocol software of the operating systems of the various hosts. The transport protocols then notify the daemons of the communication layers that a broadcast message has arrived and puts the packets in an interprocess transfer mechanism, usually shared memory. The daemons then retrieve the packets from the interprocess transfer mechanism as represented by step 518. 
     Step 520 represents the process of checking the TIB channel numbers of the incoming packets to determine if they correspond to the TIB channel of any open subscription. If they do, the reliability sequence numbers are checked by the reliable broadcast protocol engine against the data indicating which packets and corresponding sequence numbers should have been received to have received a complete message. In some embodiments, especially embodiments using transport, network, data link and physical layers where error checking (ECC) is not performed at layers below the TIB interface software of the invention, error detection and correction is performed on the packets using the ECC bits appended to the packet. If errors have occurred that are beyond the range of correction given the number of ECC bits present, the packet is marked as garbled. 
     After determining which packets are missing or garbled, if any, the receiving protocol engine then sends a message back to the communication layer of the service or publishing process. This message will either acknowledge that all packets have been received without a problem or will request that certain packets be retransmitted. This is symbolized by step 522. 
     Step 524 represents the process of retransmission of the missing or garbled packets by the communication layer of the data producing process or service. In some embodiments, the missing or garbled packets will be sent point-to-point to only the subscribing process that did not get them. In other embodiments, the missing or garbled packets are broadcast to nodes with notification messages being sent to the subscribing processes that need them to listen on TIB channel XX where XX is the TIB channel on which the packets will be broadcast. The phrase &#34;listen to channel XX&#34; as it is used here has nothing to do with the actual transmission frequency, timeslot or other physical characteristic of the transmission. It merely means that the missing or garbled packets will be appearing on the network shortly and will have TIB channel XX routing information in their header data. 
     Step 526 represents the process of checking by the receiving communication layer that the replacement packets have been properly received similar to the processing of step 520. If they have, the receiving communication layer acknowledges this fact to the communication layer of the service. If not, a request for retransmission of the missing or garbled packets is again sent to the communication layer of the transmitting process, retransmission ensues and the whole process repeats until all packets have been successfully received. The final acknowledge message from the receiving communication layer to the transmitting communication layer that all packets have been successfully received causes the reliable broadcast protocol engine of the transmitting communication layer to flush all the packets from the retransmission memory as symbolized by step 528. 
     Step 530 represents the routing process where the reliable broadcast protocol engine checks the TIB channel data against the subscription list to determine which client processes have requested data assigned to this TIB channel. Once this information is known, the protocol engine passes a pointer to the message to all service disciplines which have entered subscriptions for data on this TIB channel. In some embodiments, the protocol engine will place a copy of the message in a separate interprocess transfer mechanism for every subscribing process. In other embodiments, shared memory will be the interprocess transfer mechanism and a pointer to the same copy of the message will be sent to all subscribing processes. The subscribing processes will then arbitrate for access to the message in the information layer or the service layer. 
     Step 532 represents the processes previously described of passing the message up through the service and information layers to the subscribing process by successive interrupts causing to run the callback routines designated when the subscription was entered. Filtering by subject matter may also occur in some embodiments at the service layer and/or the information layer to guarantee a match to the subscribed subject. 
     FIG. 23 is a flow chart of processing to transmit data by the Intelligent Multicast communication protocol. This protocol uses either point-to-point or reliable broadcast protocols for each message depending upon the subject matter and how many subscriptions are open on this subject. The choice of protocol is automatically made for each message depending upon how many subscribing processes/network addresses there are for the message at the time the message is published. If the number of subscribers for a subject changes sufficiently, the transmission protocol may change automatically. 
     Step 600 represents the process of receiving a subscription request at the service layer of the data publishing process, passing this subscription along to the subscribing process and making an entry for a new subscription in the subscription table. 
     In step 602, a message is published by the service through the information layer to the service layer. The subject of the message may or may not be on the subject for which the new subscription was just entered. The service layer examines the subject data forwarded by the information layer about the message and coordinates with the information layer to assign a TIB channel to the subject if the TIB channel was already assigned by the service and information layers of the subscribing process as symbolized by step 604. 
     In step 606, the service discipline compares the number of subscribers for the subject of the message to a programmable cutoff number which is based upon the cost of transmission point-to-point versus the cost of transmission by reliable broadcast. The programmable cutoff number can be set and altered by the system administrator and is based upon any desired cost function, the nature of which is not critical to the invention. In the preferred embodiment, the cost function is comprised of a high water mark and a low water mark. If the number of subscribers is above the high water mark, the message will be sent by reliable broadcast. If the number of subscribers to this subject then subsequently falls below the low water mark, subsequent messages will be sent point-to-point. In some embodiments, the cost function can be an automatic learning program that listens to the network and subscription requests and makes the decision based upon latency time or some other criteria of network efficiency. 
     Step 608 represents the process of calling the reliable broadcast protocol engine if the number of subscribers is greater than the cutoff number. The message is then put in an interprocess transfer mechanism directed to this protocol engine. 
     If the number of subscribers is below the cutoff number, point-to-point transmission is more efficient so the service discipline calls the point-to-point protocol engine and puts the message into an interprocess transfer mechanism directed to this protocol engine as symbolized by step 610. 
     Step 612 represents the process of waiting for the next message or subscription and returning to step 600 if a subscription is received and to step 602 if another message is received. 
     In summary the concept of the invention is to use software layers to decouple applications from the complexities of the computer network communication art in ways that applications have never before been decoupled. For example, it is believed that the subject based addressing decoupling provided by the information layer is new especially when coupled with the service decoupling provided by the service layer. It is believed to be new to have extensible service and communication layers that can be easily modified by the addition of new service disciplines and protocol engines to provide service and configuration decoupling under changing conditions such as new network topologies and the addition of new or changed services and/or servers to the network. It is new to have a service layer that includes many different service disciplines designed to encapsulate many varied communication protocols. For example, these service disciplines can handle communication with everything from services like Telerate to operating system programs, other processes on other machines (or even the same machine or another part of the same process even) to a user sitting at a terminal. Further, the abilities of this service layer to implement failure monitoring and recovery, distribution and replication management, and security/access control services is new. 
     Further, it is new to have the configuration decoupling and value added services of the communication layer. 
     The teachings of the invention contemplate use of any one of these layers or any combination of the three in the various embodiments which together define a class or genus of software programs the species of which implement the specific functions or combinations thereof defined herein. 
     There follows a more detailed specification of the various library programs and the overall structure and functioning of an embodiment of the communication interface according to the teachings of the invention. 
     Information Driven Architecture™, Teknekron Information Bus™, TIB™, TIBINFO™, TIBFORMS™, Subject-Based Addressing™, and RMDP™ are trademarks of Teknekron Software Systems, Inc. 
     CONTENTS 
     1. Introduction 
     2. Teknekron Information Bus Architecture 
     3. Reliable Market Data Protocol:RMDP 
     4. Subject-Addressed Subscription Service:TIBINFO 
     5. Data-exchange Component:TIBFORM 
     6. Appendix: `man` Pages 
     1. Introduction 
     The Teknekron Information Bus™ software (TIB™ component) is a distributed software component designed to facilitate the exchange of data among applications executing in a real-time, distributed environment. It is built on top of industry standard communication protocols (TCP/IP) and data-exchange standards (e.g., X.400). 
     The document is organized as follows. Section 2 gives an architectural overview of the TIB™. Section 3 describes the Reliable Market Data Protocol. This general purpose protocol is particularly well suited to the requirements of the page-based market data services. It is also often used for bulletin and report distribution. Section 4 describes TIBINFO, an interface supporting Subject-based Addressing. Section 5 describes a component and its interface that supports a very flexible and extensible data-exchange standard. This component is called TIBFORMS. The Appendix contains (UNIX-like) manual pages for the core interfaces. 
     2. Architectural Overview 
     2.1 Introduction 
     The Teknekron Information Bus (TIB™) is comprised of two major components: the (application-oriented) data communication component and the data-exchange component. These are depicted in FIG. 2.1. In addition, a set of presentation tools and a set of support utilities have been built around these components to assist the application developer in the writing of TIB™-based applications. 
     The (application-oriented) data communication component implements an extensible framework for implementing high-level, communication protocol suites. Two protocol suites have been implemented that are tailored toward the needs of fault-tolerant, real-time applications that communicate via messages. Specifically, the suites implement subscription services that provide communication support for monitoring dynamically changing values over a network. Subscription services implement a communication paradigm well suited to distributing market data from, for example, Quotron or Telerate. 
     One of the protocol suites supports a traditional service-oriented cooperative processing model. The other protocol suite directly supports a novel information-oriented, cooperative processing model by implementing subject-based addressing. Using this addressing scheme, applications can request information by subject through a general purpose interface. Subject-based addressing allowing information consumers to be decoupled from information producers; thereby, increasing the modularity and extensibility of the system. 
     The application-oriented protocol suites are built on top of a common set of communication facilities called the distributed communications component, depicted as a sublayer in FIG. 2.1. In addition to providing reliable communications protocols, this layer provides location transparency and network independence to its clients. 
     The layer is built on top of standard transport-layer protocols (e.g., TCP/IP) and is capable of supporting multiple transport protocols. The data-exchange component implements a powerful way of representing and transmitting data. All data is encapsulated within self-describing data objects, called TIB™-forms or, more commonly, simply forms. Since TIB™ forms are self-describing, they admit the implementation of generic tools for data manipulation and display. Such tools include communication tools for sending forms between processes in a machine-independent format. Since a self-describing form can be extended without adversely impacting the applications using it, forms greatly facilitate modular application development. 
     The two major components of TIB™ were designed so that applications programmers can use them independently or together. For example, forms are not only useful for communicating applications that share data, but also for non-communicating applications that desire to use the generic tools and modular programming techniques supported by forms. Such applications, of course, do not need the communication services of the TIB™. Similarly, applications using subject-based addressing, for example, need not transmit forms, but instead can transmit any data structure. Note that the implementation of the communication component does use forms, but it does not require applications to use them. 
     2.2 System Model 
     The system model supported by the TIB™ consists of users, user groups, networks, services, service instances (or servers), and subjects. 
     The concept of a user, representing a human &#34;end-user,&#34; is common to most systems. A user is identified by a user-id. The TIB™ user-id is normally the same as the user-id (or logon id) supported by the underlying operating system, but it need not be. 
     Each user is a member of a exactly one group. The intention is that group should be composed of users with similar service access patterns and access rights. Access rights to a service or system object are grantable at the level of users and at the level of groups. The system administrator is responsible for assigning users to groups. 
     A network is a logical concept defined by the underlying transport layer and is supported by the TIB™. An application can send or receive across any of the networks that its host machine is attached to. It also supports all gateways functions and internetwork routing that is supported by the underlying transport-layer protocols. 
     Since the lowest layer of the TIB™ communication component supports multiple networks, application-oriented protocols can be written that transparently switchover from one network to another in the event of a network failure. 
     A service represents a meaningful set of functions that are exported by an application for use by its clients. Examples of services are an historical news retrieval service, a Quotron datafeed, and a trade ticket router. An application will typically export only one service, although it can export many different services. 
     A service instance is an application process capable of providing the given service. (Sometimes these are called &#34;server processes.&#34;) For a given service, several instances may be concurrently providing it, so as to improve performance or to provide fault tolerance. Application-oriented communication protocols in the TIB™ can implement the notion of a &#34;fault-tolerant&#34; service by providing automatic switchover from a failed service instance to an operational one providing the same service. 
     Networks, services, and servers are traditional components of a system model and are implemented in one fashion or another in most distributed systems. On the other hand, the notion of a subject is novel to the information model implemented by the TIB™. 
     The subject space consists of a hierarchical set of subject categories. The current release of the TIB™ supports a 4 level hierarchy, as illustrated by the following well formed subject: &#34;equity.ibm.composite.trade.&#34; The TIB™ itself enforces no policy as to the interpretation of the various subject categories. Instead, the applications have the freedom and responsibility to establish conventions on use and interpretation of subject categories. 
     Each subject is typically associated with one or more services producing data about that subject. The subject-based protocol suites of the TIB™ are responsible for translating an application&#39;s request for data on a subject into communication connections to one or more service instances providing information on that subject. 
     A set of subject categories is referred to as a subject domain. The TIB™ provides support for multiple subject domains. This facility is useful, for example, when migrating from one domain to another domain. Each domain can define domain-specific subject encoding functions for efficiently representing subjects in message headers. 
     2.3 Process Architecture 
     The communication component of the TIB™ is a truly distributed system with its functions being split between a frontend TIB™/communication library, which is linked with each application, and a backend TIB™/communication daemon process, for which there is typically one per host processor. This process architecture is depicted FIG. 2.2. Note that this functional split between TIB™ library and TIB™ daemon is completely transparent to the application. In fact, the application is completely unaware of the existence of the TIB™ daemon, with the exception of certain failure return codes. 
     The TIB™ daemons cooperate among themselves to ensure reliable, efficient communication between machines. For subject-addressed data, they assist in its efficient transmission by providing low-level system support for filtering messages by subject. 
     The TIN™/ communication library performs numerous functions associated with each of the application-oriented communication suites. For example, the library translates subjects into efficient message headers that are more compact and easier to check than ASCII subject values. It also maps service requests into requests targeted for particular service instances, and monitors the status of those instances. 
     The data-exchange component of TIB™ is implemented as a library, called the TIB™/form library, that is linked with the application. This library provides all of the core functions of the data-exchange component and can be linked independently of the TIB™/communication library. The TIB™/form library does not require the TIB™/communication daemon. 
     2.4 Communication Component 
     The TIB™ Communication Component consists of 3 subcomponents: the lower-level distributed communication component (DCC), and two high-level application-oriented communication protocol suites-the Market Data Subscription Service (MDSS), and the Subject-Addressed Subscription Service (SASS). 
     The high-level protocol suites are tailored around a communication paradigm known as a subscription. In this paradigm, a data consumer &#34;subscribes&#34; to a service or subject, and in return receives a continuous stream of data about the service or subject until the consumer explicitly terminates the subscription (or a failure occurs). A subscription paradigm is well suited for realtime applications that monitor dynamically changing values, such as a stock&#39;s price. In contrast, the more traditional request/reply communication paradigm is ill-suited for such realtime applications, since it requires data consumers to &#34;poll&#34; data providers to learn of changes. 
     The principal difference between the two high-level protocols is that the MDSS is service-oriented and SASS is subject-oriented. Hence, for example, MDSS supports the sending of operations and messages to services, in addition to supporting subscriptions; whereas, SASS supports no similar functionality. 
     2.4.1 Market Data Subscription Service 
     2.4.1.1 Overview 
     MDSS allows data consumers to receive a continuous stream of data, tolerant of failures of individual data sources. This protocol suite provides mechanisms for administering load balancing and entitlement policies. 
     Two properties distinguish the MDSS protocols from the typical client/server protocols (e.g. RPC). First, subscriptions are explicitly supported, whereby changes to requested values are automatically propagated to clients. Second, clients request (or subscribe) to a service, as opposed to a server, and it is the responsibility of the MDSS component to forward the client&#39;s request to an available server. The MDSS is then responsible for monitoring the server connection and reestablishing if it fails, using a different server, if necessary. 
     The MDSS has been designed to meet the following important objectives: 
     (1) Fault tolerance. By supporting automatic switchover between redundant services, by explicitly supporting dual (or triple) networks, and by utilizing the fault-tolerant transmission protocols implemented in the DCC (such as the &#34;reliable broadcast protocols&#34;), the MDSS ensures the integrity of a subscription against all single point failures. An inopportune failure may temporarily disrupt a subscription, but the MDSS is designed to detect failures in a timely fashion and to quickly search for an alternative communication path and/or server. Recovery is automatic as well. 
     (2) Load balancing. The MDSS attempts to balance the load across all operational servers for a service. It also rebalances the load when a server fails or recovers. In addition, the MDSS supports server assignment policies that attempts to optimize the utilization of scarce resources such as &#34;slots&#34; in a page cache or bandwidth across an external communication line. 
     (3) Network efficiency. The MDSS supports the intelligent multicast protocol implemented in the DCC. This protocol attempts to optimize the limited resources of both network bandwidth and processor I/O bandwidth by providing automatic, dynamic switchover from point-to-point communication protocols to broadcast protocols. For example, the protocol may provide point-to-point distribution of Telerate page 8 to the first five subscribers and then switch all subscribers to broadcast distribution when the sixth subscriber appears. 
     (4) High-level communication interface. The MDSS implements a simple, easy-to-use application development interface that mask most of the complexities of programming a distributed system, including locating servers, establishing communication connections, reacting to failures and recoveries, and load balancing. 
     2.4.1.2 Functionality 
     The MDSS supports the following core functions: 
     get MDSS establishes a fault-tolerant connection to a server for the specified service and &#34;gets&#34; (i.e., retrieves) the current value of the specified page or data element. The connection is subscription based so that updates to the specified page are automatically forwarded. 
     halt &#34;halt&#34; the subscription to the specified service. 
     derive sends a modifier to the server that could potentially change the subscription. 
     The MDSS protocol has been high-optimized to support page-oriented market data feed, and this focus has been reflected in the choice of function names. However, the protocol suite itself is quite general and supports the distribution of any type of data. Consequently, the protocol suite is useful and is being used in other contexts (e.g., data distribution in an electronic billboard). 
     2.4.2. Subject-Addressed Subscription Service (SASS) 
     2.4.2.1 Overview 
     The SASS is a sophisticated protocol suite providing application developers a very high-level communications interface that fully supports the information-oriented, cooperative processing model. This is achieved through the use of subject-based addressing. 
     The basic idea behind subject-based addressing and the SASS&#39;s implementation of it is straightforward. Whenever an application requires a piece of data, especially, data that represents a dynamically changing value (e.g. a stock price), the application simply subscribes to that data by specifying the appropriate subject. For example, in order to receive all trade tickets on IBM, an application may issue the following subscription: &#34;trade --  ticket.IBM&#34;. Once an application has subscribed to a particular subject, it is the responsibility of the SASS to choose one or more service instances providing information on that subject. The SASS then makes the appropriate communications connections and (optionally) notifies the service instances providing the information. 
     The SASS has been designed to meet several important objectives: 
     (1) Decoupling information consumers from information providers. Through the use of subject-based addressing, information consumers can request information in a way that is independent of the application producing the information. Hence, the producing application can be modified or supplanted by a new application providing the same information without affecting the consumers of the information. 
     (2) Efficiency. Support for filtering messages by subject is built into the low levels of the TIB™ daemon, where it can be very efficient. Also, the SASS supports filtering data at the producer side: data that is not currently of interest to any application can simply be discarded prior to placing in on the network; thereby, conserving network bandwidth and processor I/0 bandwidth. 
     (3) High-level communication interface. The SASS interface greatly reduces the complexities of programming a distributed application in three ways. First, the consumer requests information by subject, as opposed to by server or service. Specifying information at this level is easier and more natural than at the service level. Also, it insulates the program from changes in service providers (e.g., a switch from IDN to Ticker 3 for equity prices). Second, the SASS presents all data through a simple uniform interface-a programmer needing information supplied by three services need not learn three service-specific protocols, as he would in a traditional processing model. Third, the SASS automates many of the hard or error-prone tasks, such as searching for an appropriate service instance, and establishing the correct communication connection. 
     2.4.2.2. Functionality 
     For a data consumer, the SASS provides three basic functions: 
     subscribe where the consumer requests information on a real-time basis on one or more subjects. The SASS components sets up any necessary communication connections to ensure that all data matching the given subject(s) will be delivered to the consumer. The consumer can specify that data be delivered either asynchronously (interrupt-driven) or synchronously. A subscription may result in the producer service instance being informed of the subscription. This occurs whenever the producer has set up a registration procedure for its service. This notification of the producer via any specified registration procedure is transparent to the consumer. 
     cancel which is the opposite of subscribe. The SASS component gracefully closes down any dedicated communication channels, and notifies the producer if an appropriate registration procedure exists for the service. 
     receive receive and &#34;callbacks&#34; are two different ways for applications to receive messages matching their subscriptions. Callbacks are asynchronous and support the event driven programming style-a style that is particularly well-suited for applications requiring realtime data exchange. &#34;Receive&#34; supports a traditional synchronous interface for message receipt. 
     For a data producer, the SASS provides a complementary set of functions. 
     Note that an application can be both a producer and a consumer with respect to the SASS, and this is not uncommon. 
     2.4.3 Distributed Communication Component 
     2.4.3.1 Overview 
     The Distributed Communication Component (DCC) provides communication services to higher-level TIB™ protocols, in particular, it provide several types of fault transparent protocols. 
     The DCC is based on several important objectives: 
     (1) The provision of a simple, stable, and uniform communication model. This objective offers several benefits. First, it offers increased programmer productivity by shielding developers from the complexities of a distributed environment; locating a target process, establishing communications with it, and determining when something has gone awry are all tasks best done by a capable communications infrastructure, not by the programmer. Second, it reduces development time, not only by increasing programmer productivity, but also by simplifying the integration of new features. Finally, it enhances configurability by keeping applications unaware of the physical distribution of other components. This prevents developers from building in dependencies based on a particular physical configuration. (Such dependencies would complicate subsequent reconfigurations.) 
     (2) Portability through encapsulation of important system structures. This objective achieves importance when migration to a new hardware or software environment becomes necessary. The effort expended in shielding applications from the specific underlying communication protocols and access methods pays off handsomely at that time. By isolating the required changes in a small portion of the system (in this case, the DCC), applications can be ported virtually unchanged, and the firm&#39;s application investment is protected. 
     (3) Efficiency. This is particular important in this component. To achieve this, the DCC builds on top of less costly &#34;connectionless&#34; transport protocols in standard protocol suites (e.g., TCP/IP and OSI). Also, the DCC has been carefully designed to avoid the most costly problem in protocols: the proliferation of data &#34;copy&#34; operations. 
     The DCC achieves these objectives by implementing a layer of services on top of the basic services provided by vendor-supplied software. Rather than re-inventing basic functions like reliable data transfer or flow-control mechanisms, the DCC concentrates on shielding applications from the idiosyncrasies of any one particular operating system. Examples include the hardware-oriented interfaces of the MS-DOS environment, or the per-process file descriptor limit of UNIX. By providing a single, unified communication tool that can be easily replicated in many hardware or software environment, the DCC fulfills the above objectives. 
     2.4.3.2. Functionality 
     The DCC implements several different transmission protocols to support the various interaction paradigms, fault-tolerance requirements, and performance requirements imposed by the high-level protocols. Two of the more interesting protocols are reliable broadcast and intelligent multicast protocols. 
     Standard broadcast protocols are not reliable and are unable to detect lost messages. The DCC reliable broadcast protocols ensure that all operational hosts either receive each broadcast message or detects the loss of the message. Unlike many so-called reliable broadcast protocols, lost messages are retransmitted on a limited, periodic basis. 
     The intelligent multicast protocol provides a reliable datastream to multiple destinations. The novel aspect of the protocol is that it can dynamically switch from point-to point transmission to broadcast transmission in order to optimize the network and processor load. The switch from point-to-point to broadcast (and vice versa) is transparent to higher-level protocols. This protocol admits the support of a much larger number of consumers than would be possible using either point-to-point or broadcast alone. The protocol is built on top of other protocols within the DCC. 
     Currently, all DCC protocols exchange data only in discrete units, i.e., &#34;messages&#34; (in contrast to many Transport protocols). The DCC guarantees that the messages originating from a single process are received in the order sent. 
     The DCC contains fault-tolerant message transmission protocols that support retransmission in the event of a lost message. The package guarantees &#34;at-most-once&#34; semantics with regards to message delivery and makes a best attempt to ensure &#34;exactly once&#34; semantics. 
     The DCC contains no exposed interfaces for use by application developers. 
     3. RELIABLE MARKET DATA PROTOCOL 
     3.1 Introduction 
     The Reliable Market Data Protocol (RMDP) defines a programmatic interface to the protocol suite and services comprising the Market Data Subscription Service (MDSS) TIB™ subcomponent. RMDP allows market data consumers to receive a continuous stream of data, based on a subscription request to a given service. RMDP tolerates failures of individual servers, by providing facilities to automatically reconnect to alternative servers providing the same service. All the mechanisms for detecting server failure and recovery, and for hunting for available servers are implemented in the RMDP library. Consequently, application programs can be written in a simple and naive way. 
     The protocol provides mechanisms for administering load balancing and entitlement policies. For example, consider a trading room with three Telerate lines. To maximize utilization of the available bandwidth of those Telerate lines, the system administrator can &#34;assign&#34; certain commonly used pages to particular servers, i.e., page 5 to server A, page 405 to server B, etc. Each user (or user group) would be assigned a &#34;default&#34; server for pages which are not explicitly preassigned. (These assignments are recorded in the TIB™ Services Directory.) 
     To accommodate failures, pages or users are actually assigned to prioritized list of servers. When a server experiences a hardware or software failure, RMDP hunts for and connects to the next server on the list. When a server recovers, it announces its presence to all RMDP clients, and RMDP reconnects the server&#39;s original clients to it. (Automatic reconnection avoids situations where some servers are overloaded while others are idle.) Except for status messages, failure and recovery reconnections are transparent to the application. 
     The MDSS protocol suite, including RMDP, is built on top of the DCC and utilizes the reliable communication protocols implemented in that component. In particular, the MDSS suite utilizes the reliable broadcast protocols and the intelligent multicast protocol provided therein. RMDP supports both LANs and wide area networks (WANs). RMDP also supports dual (or multiple) networks in a transparent fashion. 
     RMDP is a &#34;service-addressed&#34; protocol; a complementary protocol, TIBINFO, supports &#34;subject-based addressing.&#34; 
     3.2 Programmatic Interface 
     RMDP programs are event-driven. All RMDP function calls are non-blocking: even if the call results in communication with a server, the call returns immediately. Server responses, as well as error messages, are returned at a later time through an application-supplied callback procedure. 
     The principal object abstraction implemented in RMDP is that of an Rstream, a &#34;reliable stream,&#34; of data that is associated with a particular subscription to a specified service. Although, due to failures and recoveries, different servers may provide the subscription data at different times, the Rstream implements the abstraction of a single unified data stream. Except for short periods during failure or recovery reconnection, an Rstream is connected to exactly one server for the specified service. An application may open as many Rstreams as needed, subject only to available memory. 
     An Rstream is bidirectional--in particular, the RMDP client can send control commands and messages to the connected server over the Rstream. These commands and messages may spur responses or error messages from the server, and in one case, a command causes a &#34;derived&#34; subscription to be generated. Regardless of cause, all data and error messages (whether remotely or locally generated) are delivered to the client via the appropriate Rstream. 
     The RMDP interface is a narrow interface consisting of just six functions, which are described below. 
     
         ______________________________________
         void
         rmdp.sub.-- SetProp(property, value)
         rmdp.sub.-- prop.sub.-- t property;
         caddr.sub.-- t value;
______________________________________
 
    
     Used to set the values of RMDP properties. These calls must be made before the call to rmdp --  Init(). Required properties are marked with ? in the list below. Other properties are optional. The properties currently used are: 
     
         ______________________________________
         *RMDP.sub.-- CALLBACK
______________________________________
 
    
     Pointer to the callback function. See the description of callback below. 
     
         ______________________________________
         RMDP.sub.-- SERVICE.sub.-- MAP
______________________________________
 
    
     The name of Services Directory to be used in lieu of the standard directory. 
     
         ______________________________________
           RMDP.sub.-- GROUP
______________________________________
 
    
     The user group used to determine the appropriate server list. Should be prefixed with `+`. Default is group is &#34;+&#34; (i.e. The null group). 
     
         ______________________________________
         RMDP.sub.-- RETRY.sub.-- TIME
______________________________________
 
    
     The number of seconds that the client will wait between successive retries to the same server, e.g., in the case of cache full.&#34; Default is 30. 
     
         ______________________________________
         RMDP.sub.-- QUIET.sub.-- TIME
______________________________________
 
    
     The time in seconds that a stream may be &#34;quiet&#34; before the protocol assumes that the server had died and initiates a &#34;hunt&#34; for a different server. Default is 75. 
     
         ______________________________________
         RMDP.sub.-- VERIFY.sub.-- TIME
______________________________________
 
    
     The time in seconds between successive pings of the server by the client. Default is 60. 
     
         ______________________________________
         RMDP.sub.-- APP.sub.-- NAME
______________________________________
 
    
     The name of the application i.e. &#34;telerate&#34;, &#34;reuters&#34; etc. If this property is set, then the relevant entries from the Service Directory will be cached. 
     
         ______________________________________
            void
            rmdp.sub.-- Init();
______________________________________
 
    
     This initializes the internal data structures and must be called prior to any calls to rmdp --  Get (). 
     
         ______________________________________
       RStream
       rmdp.sub.-- Get(service, request, host)
       char *service, *request, *host;
______________________________________
 
    
     This is used to get a stream of data for a particular `service` and subscription `request`. For the standard market data services, the request will be the name of a page (e.g., &#34;5&#34;, &#34;AANN&#34;). If `host` is non-NULL, then the RMDP will only use the server on the given host. In this case, no reconnection to alternative servers will be attempted upon a server failure. If `host` is NULL, then RMDP will consult the TIB™ Services Directory to identify a list of server alternatives for the request. `rstream` is an opaque value that is used to refer to the stream. All data passed to the application&#39;s callback function will be identified by this value. 
     An error is indicated by RStream rstream=NULL. 
     
         ______________________________________
         RStream
         rmdp.sub.-- Derive(rstream, op)
         RStreamold;
         char   *op;
______________________________________
 
    
     This generates a new subscription and, hence, a new `Rstream` from an existing subscription. `command` is a string sent to the server, where it is interpreted to determine the specific derivation. 
     The standard market data servers understand the following commands: &#34;n&#34; for next-page &#34;p&#34; for previous-page and &#34;t XXXX&#34; for time-page. 
     Derived streams cannot be recovered in the case of server failure. If successful, an Rstream is returned, otherwise NULL is returned. 
     
         ______________________________________
        void
        rmdp.sub.-- Message(rstream, msg)
        RStreamrstream;
        char   *msg;
______________________________________
 
    
     Sends the string `msg` to the server used by `rstream`. The messages are passed directly to the server, and are not in any way affected by the state of the stream. The messages are understood by the standard market data servers include &#34;rr &lt;PAGE NAME&gt;&#34; to rerequest a page, and &#34;q a&#34; to request the server&#39;s network address. Some messages induce a response form the server (such as queries). In this case, the response will be delivered to all streams that are connected to the server. 
     
         ______________________________________
          void
          rmdp.sub.-- Halt(rstream)
          RStreamrstream;
______________________________________
 
    
     This gracefully halts the `rstream`. 
     
         ______________________________________
void
callback(rstream, msgtype, msg, act, err)
RStreamrstream;
mdp.sub.-- msg.sub.-- t   msgtype;
char   *msg;
mdp.sub.-- act.sub.-- t   act;
mdp.sub.-- err.sub.-- t   err;
______________________________________
 
    
     This is the callback function which was registered with rmdp --  SetProp (RMDP --  CALLBACK, callback). `rstream` is the stream to which the message pertains. `msgtype` can be any of the values defined below (see &#34;RMDP Message Type&#34;). `msg` is a string which may contain vt100 compatible escape sequences, as in MDSS. (It will NOT however be prefaced with an [[. . . E. That role is assumed by the parameter `msgtype`.) 
     The last two parameters are only meaningful if `msgtype` is MDP --  MSG --  STATUS. `act` can be any of the values found in &#34;RMDP Action Type&#34; (see below), but special action is necessary only if act=`MDP --  ACT --  CANCEL`. The latter indicates that the stream is being canceled and is no longer valid. It is up to the application to take appropriate action. In either case, `err` can be any of the values found in &#34;RMDP Error Type&#34; (see below), and provides a description of the status. 
     
         ______________________________________
RMDP Message Types (mdp.sub.-- msg.sub.-- t)
______________________________________
 
    
     The message types are listed below. These types are defined in the underlying (unreliable) Market Data Protocol (MDP) and are exported to the RMDP. 
     
         ______________________________________
MDP.sub.-- MSG.sub.-- BAD = -1
MDP.sub.-- MSG.sub.-- DATA = 0
                  Page data message.
MDP.sub.-- MSG.sub.-- STATUS = 1
                  Status/error message.
MDP.sub.-- MSG.sub.-- OOB = 2
                  &#34;Out of Band&#34; message, e.g.,
                    time stamp.
MDP.sub.-- MSG.sub.-- QUERY = 3
                  Query result.
RMDP Action Type (mdp.sub.-- act.sub.-- t)
______________________________________
 
    
     The action types are listed below. These action types inform the RMDP clients of activities occurring in the lower lever protocols. Generally speaking, they are &#34;for your information only&#34; messages, and do not require additional actions by the RMDP client. The exception is the &#34;MDP --  ACT --  CANCEL&#34; action, for which there is no recovery. These types are defined in the underlying (unreliable) Market Data Protocol (MDP) and are exported to the RMDP. 
     
         ______________________________________
MDP.sub.-- ACT.sub.-- OK = 0
                   No unusual action required.
MDP.sub.-- ACT.sub.-- CANCEL = 1
                   The request cannot be ser-
                   viced, cancel the stream, do
                   not attempt to reconnect.
                   (E.g., invalid page name.)
MDP.sub.-- ACT.sub.-- CONN.sub.-- FIRST = 2
                   The server is closing the
                   stream; the first server in the
                   alternatives list is being
                   tried. (E.g., the server is
                   shedding &#34;extra&#34; clients for
                   load balancing.)
MDP.sub.-- ACT.sub.-- CONN.sub.-- NEXT = 3
                   The server is closing the
                   stream; the next server in the
                   alternatives list is being
                   tried. (E.g., the server&#39;s line
                   to host fails.)
MDP.sub.-- ACT.sub.-- LATER = 4
                   Server cannot service re-
                   quest at this time; will resub-
                   mit request later, or try a
                   different server. (E.g., Cache
                   full.)
MDP.sub.-- ACT.sub.-- RETRY = 5
                   Request is being retried
                   immediately.
RMDP Error Types (mdp.sub.-- err.sub.-- t)
______________________________________
 
    
     Description of error, for logging or reporting to end user. These types are defined in the underlying (unreliable) Market Data Protocol (MDP) and are exported to the RMDP. 
     
         ______________________________________
       MDP.sub.-- ERR.sub.-- OK = 0
       MDP.sub.-- ERR.sub.-- LOW = 1
       MDP.sub.-- ERR.sub.-- QUIET = 2
       MDP.sub.-- ERR.sub.-- INVAL = 3
       MDP.sub.-- ERR.sub.-- RESRC = 4
       MDP.sub.-- ERR.sub.-- INTERNAL = 5
       MDP.sub.-- ERR.sub.-- DELAY = 6
       MDP.sub.-- ERR.sub.-- SYS = 7
       MDP.sub.-- ERR.sub.-- COMM = 8
______________________________________
 
    
     4. Subject-Addressed Subscription Service:TIBINFO 
     4.1 Introduction 
     TIBINFO defines a programmatic interface to the protocols and services comprising the TIB™ subcomponent providing Subject-Addressed Subscription Services (SASS). The TIBINFO interface consists of libraries: TIBINFO --  CONSUME for data consumers, and TIBINFO --  PUBLISH for data provides. An application includes one library or the other or both depending on whether it is a consumer or provider or both. An application can simultaneously be a consumer and a producer. 
     Through its support of Subject-Based Addressing, TIBINFO supports a information-oriented model of cooperative processing by providing a method for consumers to request information in a way that is independent of the service (or services) producing the information. Consequently, services can be modified or replaced by alternate services providing equivalent information without impacting the information consumers. This decoupling of information consumers from information providers permits a higher degree of modularization and flexibility than that permitted by traditional service-oriented processing models. 
     For Subject-Based Addressing to be useful in a real time environment, it must be efficiently implemented. With this objective in mind, support for Subject-Based Addressing has been built into the low levels of the Distributed Communications Component. In particular, the filtering of messages by subject is performed within the TIB™ daemon itself. 
     4.2 Concepts 
     Subject 
     The subject space is hierarchical. Currently, a 4-level hierarchy is supported of the following format: 
     
         major[.minor[.qualifier1[.qualifier2[[[ 
    
     where &#39;[&#39;and &#39;]&#39; are metacharacters that delimit an optional component. major, minor, qualifier1 and qualifier2 are called subject identifiers. A subject identifier is a string consisting of the printable ascii characters excluding &#39;.&#39;, &#39;?&#39;, and &#39;*&#39;. A subject identifier can be an empty string, in which case it will match with any subject identifier in that position. The complete subject, including the &#39;.&#39; separators, cannot exceed 32 characters. Subject are case sensitive. 
     Some example of valid subjects are listed below: The comments refer to the interpretation of subject on the consume side. (The publish-side semantics are slightly different.) 
     
         ______________________________________
equity.ibm.composite.quote
equity..composite.quote
                  matches any minor subject
equity.ibm        matches any qualifier1 and
                  qualifier2
equity.ibm.       same as above
______________________________________
 
    
     Within the TIBINFO and the SASS, subjects are not interpreted. Hence, applications are fee to establish conventions on the subject space. It should be noted that SASS components first attempt to match the major and minor subject identifiers first. As a consequence, although applications can establish the convention that &#34;equity.ibm&#34; and &#34;..equity.ibm&#34; are equivalent subjects, subscriptions to &#34;equity.ibm&#34; will be more efficiently processed. 
     Stream 
     A stream is an abstraction for grouping subscriptions. The subscriptions on a stream share a common set of properties, notably the same message handler (i.e., &#34;callback&#34; routine) and the same error handler. All subscriptions on a stream can be &#34;canceled&#34; simply by destroying the stream. 
     A stream imposes little overhead on the system. They can therefore be freely created and destroyed. 
     Protocol Engines, Service Disciplines, and Subject Mappers 
     The SASS and DCC components implement many support services in order to provide the functionality in TIBINFO. These include subject mappers for efficiently handling subjects, service disciplines for controlling the interaction with servers, and protocol engines for implementing reliable communication protocols. TIBINFO provides an interface for setting properties of these components. Hence, by setting the appropriate properties, one can specify, for example, the behavior of the subject mapper through the TIBINFO interface. Since these properties are in configuration files, configuration and site dependent parameters can be altered for the above components by the system administrator through TIBINFO. 
     In some embodiments, the property definitions for TIBINFO and for the underlying components may be augmented to support enhancements. This use of properties yields flexibility and extensibility within the confines of a stable functional interface. 
     4.3 Description 
     The TIBINFO interface is high-level and easy to use. Published data can be a form or an uninterpreted byte string. Messages can be received either in a synchronous fashion, or in an asynchronous fashion that is suitable for event-driven programing. The following functions are sufficient to write sophisticated consumers using event-driven programming. 
     
         ______________________________________
Tib.sub.-- stream
         *tib.sub.-- consume.sub.-- create(property-list, TIB.sub.--
______________________________________
         EOP)
 
    
     Creates a TIBINFO stream that supports multiple subscriptions via the &#34;subscribe&#34; function. The property --  list is a (possibly empty) list of property value pairs, as illustrated by 
     
         ______________________________________
tib.sub.-- consume.sub.-- create(TIB.sub.-- PROP.sub.-- MSGHANDLER,
my.sub.-- handler,
TIB.sub.-- PROP.sub.-- ERRHANDLER, my.sub.-- err.sub.-- handler,
TIB.sub.-- EOP);
______________________________________
 
    
     Valid properties are defined below. TIB --  EOP is a literal signaling the end of the property list. 
     
         ______________________________________
         void tib.sub.-- destroy(stream)
         Tib.sub.-- stream   *stream;
______________________________________
 
    
     Reclaims resources used by the specified stream. 
     
         ______________________________________
Tib.sub.-- errorcode tib.sub.-- subscribe(stream, subject, clientdata)
Tib.sub.-- stream    *stream;
Tib.sub.-- subject   *subject;
caddr.sub.-- t       clientdata;
______________________________________
 
    
     Informs the TIB™ software that the client application is interested in messages having the indicated subject. If stream has an associated &#34;message-handler,&#34; then it will be called whenever a message satisfying the subscription arrives. Qualifying messages are delivered on a first-in/first-out basis. The value of clientdata is returned in every message satisfying the subscription subject. Note that multiple subscriptions to the same subject on the same stream are undefined. 
     
         ______________________________________
void tib.sub.-- cancel(stream)
void.sub.-- stream     *stream;
______________________________________
 
    
     Cancels the client application&#39;s subscription to the specified subject. 
     
         ______________________________________
void my.sub.-- message.sub.-- handler(stream,msg)
Tib.sub.-- stream    *stream;
Tib.sub.-- message   *message;
______________________________________
 
    
     This is the &#34;callback&#34; function that was registered with the stream. Forms are returned unpacked. The function can reference the entire message structure through the macros described below. 
     The following functions are sufficient to write producers. Two publishing functions are provided to support the different data types that can be transmitted through the TIB-INFO interface. 
     
         ______________________________________
tib.sub.-- publish.sub.-- create(property-list, TIB.sub.-- EOP)
______________________________________
 
    
     Is used to create an TIBINFO stream for publishing records. The property --  list is a (possibly empty) list of property-value pairs, as illustrated by 
     
         ______________________________________
tib.sub.-- publish.sub.-- create(TIB.sub.-- PROP.sub.-- ERRHANDLER,
my.sub.-- handler,TIB.sub.-- EOP);
______________________________________
 
    
     Valid properties are defined below. TIB --  EOP is a constant signalling the end of the property list. 
     
         ______________________________________
         tib.sub.-- destroy(stream)
         Tib.sub.-- stream   stream;
______________________________________
 
    
     Reclaims resources used by the specified stream. 
     
         ______________________________________
Tib.sub.-- errorcode tib.sub.-- publish.sub.-- form(stream, subject,
form)
Tib.sub.-- stream
           *stream;
Tib.sub.-- subject
           *subject;
Form       form;
______________________________________
 
    
     Accepts a single, unpacked form, packs it, and publishes it. 
     
         ______________________________________
Tib.sub.-- errorcode tib.sub.-- publish.sub.-- buffer(stream, subject,
length,
form)
Tib.sub.-- stream
           *stream;
Tib.sub.-- subject
           *subject;
short      length;
Form       form;
______________________________________
 
    
     Accepts a byte buffer of specified length and publishes it. 
     The remaining functions are control functions that apply to both the consume and the publish side. 
     
         ______________________________________
           void Tib.sub.-- batch()
______________________________________
 
    
     This may be used prior to initiating multiple subscriptions. It informs the TIN™ library that it can delay acting on the subscriptions until a tib --  unbatch is seen. This allows the TIB™ library to attempt to optimize the execution of requests. Note that no guarantees are made about the ordering or timing of &#34;batched&#34; request. In particular, (i) requests may be executed prior to the receipt of the tib --  unbatch function, and (ii) the effects of changing properties in the middle of a batched sequence of requests is undefined. Batch and unbatch requests may be nested. (Note that the use of tib --  batch is completely optional and it does not change the semantics of a correct program.) 
     
         ______________________________________
Tib.sub.-- errorcode tib.sub.-- stream.sub.-- set(stream, property,
value)
Tib.sub.-- stream
           *stream;
Tib.sub.-- property
           *property;
caddr.sub.-- t
           value;
______________________________________
 
    
     Used to change the dynamically settable properties of a stream. These properties are described below. Note that some properties can only be set prior to stream creation (via tib --  default --  set) or at stream creation. 
     
         ______________________________________
caddr.sub.-- t tib.sub.-- stream.sub.-- get(stream, property)
Tib.sub.-- stream
              *stream;
Tib.sub.-- property
              *property;
______________________________________
 
    
     Used to retrieve the current value of the specified property. 
     
         ______________________________________
Tib.sub.-- errorcode tib.sub.-- default.sub.-- set( property, value)
Tib.sub.-- stream
             *stream;
Tib.sub.-- property
             *property;
caddr.sub.-- t
             value;
______________________________________
 
    
     Used to change the initial properties of a stream. During stream creation, the default values are used as initial values in the new stream whenever a property value is not explicitly specified in the creation argument list. 
     
         ______________________________________
Tib.sub.-- errorcode tib.sub.-- default.sub.-- get( property)
Tib.sub.-- stream
              *stream;
Tib.sub.-- property
              *property;
______________________________________
 
    
     Used to retrieve the default value of the specified property. 
     
         ______________________________________
            tib.sub.-- unbatch()
______________________________________
 
    
     Informs TIBINFO to stop &#34;batching&#34; functions and to execute any outstanding ones. 
     TIBINFO Attributes 
     The properties defined by TIBINFO and their allowable values are listed below and are described in detail in the appropriate &#34;man&#34; pages. The last grouping of properties allow the programmer to send default property values and hints to the underlying system components-specifically, the network protocol engines, the TIB™ subject mapper, and various service disciplines. 
     
         ______________________________________
TIB.sub.-- PROP.sub.-- CFLIE
                   cfile-handle
TIB.sub.-- PROP.sub.-- CLIENTDATA
                   pointer
TIB.sub.-- PROP.sub.-- ERRHANDLER
                   error-handler-routine
TIB.sub.-- PROP.sub.-- LASTMSG
                   tib.sub.-- message pointer
TIB.sub.-- PROP.sub.-- MSGHANDLER
                   message-handler-routine
TIB.sub.-- PROP.sub.-- NETWORK
                   protocol-engine-property-list
TIB.sub.-- PROP.sub.-- NETWORK.sub.-- CFILE
                   protocol-engine-property-
                   cfile
TIB.sub.-- PROP.sub.-- SERVICE
                   service-discipline-property-
                   list
TIB.sub.-- PROP.sub.-- SERVICE.sub.-- CFILE
                   service-discipline-property-
                   cfile
TIB.sub.-- PROP.sub.-- SUBJECT
                   subject-property-list
TIB.sub.-- PROP.sub.-- SUBJECT.sub.-- CFILE
                   subject-property-cfile
______________________________________
 
    
     TIBINFO Message Structure 
     The component information of a TIBINFO message can be accessed through the following macros: 
     
         ______________________________________
         tib.sub.-- msg.sub.-- clientdata(msg)
         tib.sub.-- msg.sub.-- subject(msg)
         tib.sub.-- msg.sub.-- size(msg)
         tib.sub.-- msg.sub.-- value(msg)
______________________________________
 
    
     The following macros return TRUE (1) or FALSE (0): 
     
         ______________________________________
         tib.sub.-- msg.sub.-- is.sub.-- buffer(msg)
         tib.sub.-- msg.sub.-- is.sub.-- form(msg)
______________________________________
 
    
     5. TIB™ Forms 
     5.1 Introduction 
     The Forms package provides the tools to create and manipulate self-describing data objects, e.g., forms. Forms have sufficient expressiveness, flexibility and efficiency to describe all data exchanged between the different TIB™ applications, and also between the main software modules of each application. 
     The Forms package provides its clients with one data abstraction. Hence, the software that uses the Forms package deal with only one data abstraction, as opposed to a data abstraction for each different type of data that is exchanged. Using forms as the only way to exchange user data, facilitates (i) the integration of new software modules that communicate with other software modules, and (ii) modular enhancement of existing data formats without the need to modify the underlying code. This results in software that is easier to understand, extend, and maintain. 
     Forms are the principal shared objects in the TIB™ communication infrastructure and applications; consequently, one of the most important abstractions in the TIB™. 
     The primary objective in designing the forms package were: 
     Extensibility - It is desirable to be able to change the definition of a form class without recompiling the application, and to be able introduce new classes of forms into the system. 
     Maintainability - Form-class definition changes may affect many workstations; such changes must be propagated systematically. 
     Expressiveness - Forms must be capable of describing complex objects; therefore, the form package should support many basic types such as integer, real, string, etc. and also sequences of these types. 
     Efficiency - Forms should be the most common object used for sending information between processes-both for processes on the same workstation and for processes on different workstations. Hence, forms should be designed to allow the communication infrastructure to send information efficiently. 
     Note that our use of the term &#34;form&#34; differs from the standard use of the term in database systems and so-called &#34;forms management systems.&#34; In those systems, a &#34;form&#34; is a format for displaying a database or file record. (Typically, in such systems, a user brings up a form and paints a database record into the form.) 
     Our notion of a form is more fundamental, akin to such basic notions as record or array. Our notion takes its meaning from the original meaning of the Latin root word forma. Borrowing from Webster: &#34;The shape and structure of something as distinguished from its material&#34;. Forms can be instantiated, operated on, passed as arguments, sent on a network, stored in files and databases. Their contents can also be displayed in many different formats. &#34;templates&#34; can be used to specify how a form is to be displayed. A single form (more precisely, a form class) can have many &#34;templates&#34; since it may need to be displayed in many different ways. Different kinds of users may, for example, desire different formats for displaying a form. 
     5.2 Description 
     Forms are self-describing data objects. Each form contains a reference to its formclass, which completely describes the form. Forms also contains metadata that enables the form package to perform most operations without accessing the related formclass definition. 
     Each form is a member of a specific form class. All forms within a class have the same fields and field&#39;s labels (in fact, all defining attributes are identical among the forms of a specific class). Each form class is named and two classes are considered to be distinct if they have distinct names (even though the classes may have identical definitions). Although the forms software does not assign any special meaning or processing support to particular form names, the applications using it might. (In fact, it is expected that certain form naming conventions will be established.) 
     There are two main classification of forms: primitive versus constructed forms, and fixed length versus variable size forms. 
     Primitive forms are used to represent primitive data types such as integers, float, strings, etc. Primitive forms contain metadata, in the form header information header and the data of the appropriate type, such as integer, string, etc. 
     Constructed forms contain sub-forms. A constructed form contains other forms, which in turn can contain subforms. 
     Fixed length forms are simply forms of a fixed length, e.g., all the forms of a fixed length class occupy the same number of bytes. An example for a fixed length primitive form is the integer form class; integer forms always take 6 bytes, (2 bytes for the form header and 4 bytes for the integer data). 
     Variable size forms contain variable size data: variable size, primitive forms contain variable size data, such as variable length string; variable size, constructed forms contain a variable number of subforms of a single class. Such forms are similar to an array of elements of the same type. 
     5.3 Class Identifiers 
     When a class is defined it is assigned an identifier. This identifier is part of each of the class&#39;s form instance, and is used to identify the form&#39;s class. This identifier is in addition to its name. Class identifiers must be unique within their context of use. Class identifiers are 2 bytes long; bit 15 is set if the class is fixed length and cleared otherwise; bit 14 is set if the class is primitive and cleared otherwise; 
     5.4 Assignment semantics 
     To assign and retrieve values of a form (or a form sequence), &#34;copy&#34; semantics is used. Assigning a value to a form (form field or a sequence element) copies the value of the form to the assigned location-it does not point to the given value. 
     Clients that are interested in pointer semantics should use forms of the basic type Form Pointer and the function Form --  set --  data --  pointer. Forms of type Form Pointer contain only a pointer to a form; hence, pointer semantics is used for assignment. Note that the C programming language supports pointer semantics for array assignment. 
     5.5 Referencing a Form Field 
     A sub-form or field of a constructed form can be accessed by its field name or by its field identifier (the latter is generated by the Forms package). The name of a subform that is not a direct descendent of a given form is the path name of all the fields that contain the requested subform, separated by dot. Note that this is similar to the naming convention of the C language records. 
     A field identifier can be retrieved given the field&#39;s name and using the function Form-class --  get --  field --  id. The direct fields of a form can be traversed by using Form --  field --  id --  first to get the identifier of the first field, and then by subsequently calling Form --  field --  id --  next to get the identifiers of each of the next fields. 
     Accessing a field by its name is convenient; accessing it by its identifier is fast. Most of the Forms package function references a form field by the field&#39;s identifier and not by the field&#39;s name. 
     5.6 Form-class Definition Language 
     Form classes are specified using the &#34;form-class definition language,&#34; which is illustrated below. Even complex forms can be described within the simple language features depicted below. However, the big attraction of a formal language is that it provides an extensional framework: by adding new language constructs the descriptive power of the language can be greatly enhanced without rendering previous descriptions incompatible. 
     A specification of a form class includes the specification of some class attributes, such as the class name, and a list of specifications for each of the class&#39;s fields. Three examples are now illustrated: 
     
         ______________________________________
short {
IS.sub.-- FIXED      true;
IS.sub.-- PRIMITIVE  true;
DATA.sub.-- SIZE     2;
DATA.sub.-- TYPE     9;
}
short.sub.-- array {
                # A variable size class of shorts.
IS.sub.-- FIXED false;
FIELDS  {
{
  FIELD.sub.-- CLASS.sub.-- NAME short;
}
}}
example.sub.-- class {
IS.sub.-- FIXED true;
FIELDS {
first {
  FIELD.sub.-- CLASS.sub.-- NAME short;
}
second {
  FIELD.sub.-- CLASS.sub.-- NAME short.sub.-- array;
}
third {
  FIELD.sub.-- CLASS.sub.-- NAME string.sub.-- 30;
}
fourth {
  FIELD.sub.-- CLASS.sub.-- NAME integer;
}
}
}}
______________________________________
 
    
     To specify a class, the class&#39;s name, a statement of fixed or variable size, and a list of fields must be given. For primitive classes the data type and size must also be specified. All the other attributes may be left unspecified, and defaults will be applied. To define a class field, either the field class name or id must be specify. 
     The form-class attributes that can be specified are: 
     
         ______________________________________
o      The class name.
o      CLASS.sub.-- ID - The unique short integer identifier of
       the class. Defaults to a package specified value.
o      IS.sub.-- FIXED - Specifies whether its a fixed or
variable
       size class. Expects a boolean value. This is a
       required attribute.
o      IS.sub.-- PRIMITIVE - Specifies whether its a primitive
or
       constructed class. Expects a boolean value.
       Defaults to False.
o      FIELDS.sub.-- NUM - An integer specifying the initial
       number of fields in the form. Defaults to the
       number of specified fields.
o      DATA.sub.-- TYPE - An integer, specified by the clients,
       that indicates what is the type of the data. Used
       mainly in defining primitive classes. It does not
       have default value.
o      DATA.sub.-- SIZE - The size of the forms data portion.
Used
       mainly in defining primitive classes. It does not
       have default value.
o      FIELDS - Indicates the beginning of the class&#39;s
       fields definitions.
The field attributes that can be specified are:
o      The class field name.
o      FIELD.sub.-- CLASS.sub.-- ID - The class id for the forms to
       reside in the field. Note that the class name can
be
       used for the same purpose.
o      FIELD.sub.-- CLASS.sub.-- NAME - The class name for the
       forms
to
       reside in the field.
______________________________________
 
    
     Here is an example of the definition of three classes: 
     Note that variable length forms contains fields of a single class. &#34;integer&#34; and &#34;string --  30&#34;, used in the above examples, are two primitive classes that are defined within the Formclass package itself. 
     5.7 Form Classes are Forms 
     Form classes are implemented as forms. This means functions that accept forms as an argument also accept form classes. Some of the more useful functions on form classes are: 
     
         ______________________________________
o      Form.sub.-- pack, Form.sub.-- unpack - Can be used to pack
and
       unpack form classes.
o      Form.sub.-- copy - Can be used to copy form classes.
o      Form.sub.-- show - Can be used to print form
classes.
______________________________________
 
    
     5.8 Types 
     
         ______________________________________
        typedef   Formclass
          A form-class handle.
        typedef   Formclass.sub.-- id
          A form-class identifier.
        typedef   Formclass.sub.-- attr
______________________________________
 
    
     A form-class attribute type. Supported attributes are: 
     
         ______________________________________
o    FORMCLASS.sub.-- SIZE - The size of the class form
     instances.
o    FORMCLASS.sub.-- NAME - The class name.
o    FORMCLASS.sub.-- ID - A two byte long unique identifier.
o    FORMCLASS.sub.-- FIELDS.sub.-- NUM - The number of (direct)
     fields in the class. This is applicable only for
     fixed length classes. The number of fields in a
     variable length class is different for each
     instance; hence, is kept in each form instance.
o    FORMCLASS.sub.-- INSTANCES.sub.-- NUM - The number of
     form instances of the given class.
o    FORMCLASS.sub.-- IS.sub.-- FIXED - True if its a fixed length
     form, False if its a variable length form.
o    FORMCLASS.sub.-- IS.sub.-- PRIMITIVE - True if its a form of
     primitive type, False if its a constructed form,
     i.e. the form has sub forms.
o    FORMCLASS.sub.-- DATA.sub.-- TYPE - This field value is
assigned
     by the user of the forms a to identify the data
     type of primitive forms. In our current
application
     we use the types constants as defined by the
     enumerated type Form.sub.-- data.sub.-- type, in the file
forms.h.
o    FORMCLASS.sub.-- DATA.sub.-- SIZE - This field contains the
data
     size, in bytes, of primitive forms. For
instance,
     the data size of the primitive class Short is
two.
     Because it contains the C type short, which is
kept
     in two bytes.
typedef   Formclass.sub.-- field.sub.-- attr
______________________________________
 
    
     A form-class field attribute type. Supported form class field attributes are: 
     
         ______________________________________
o        FORMCLASS.sub.-- FIELD.sub.-- NAME - The name of
         the class field.
o        FORMCLASS.sub.-- FIELD.sub.-- CLASS.sub.-- ID - The
         class id of
the
         field&#39;s form.
typedef   Form
A form handle.
typedef   Form.sub.-- field.sub.-- id
An identifier for a form&#39;s field. It can
identifies
fields in any level of a form. A field
identifier
can be retrieved form a field name, using the
function Form-class.sub.-- get.sub.-- field.sub.-- name. A
form.sub.-- field.sub.-- id
is manipulated by the functions:
Form.sub.-- field.sub.-- id.sub.-- first and Form.sub.-- field.sub.--
id.sub.-- next.
typedef   Form.sub.-- attr
______________________________________
 
    
     A form attribute type. Supported form attributes are: 
     
         ______________________________________
o    FORM.sub.-- CLASS.sub.-- ID - The form&#39;s class identifier.
o    FORM.sub.-- DATA.sub.-- SIZE - The size of the form&#39;s data.
     Available only for constructed, not
primitive,
forms or for primitive forms that are of
variable size. For fixed length primitive
forms
this attribute is available via the form
class.
o    FORM.sub.-- FIELDS.sub.-- NUM - The number of fields in the
     given form. Available only for constructed,
not
     primitive forms. For primitive forms this
     attribute is available via the form class.
typedef   Form.sub.-- data
______________________________________
 
    
     The type of the data that is kept in primitive forms. 
     
         ______________________________________
typedef   Form.sub.-- pack.sub.-- format
______________________________________
 
    
     Describes the possible form packaging types. Supported packing formats are: 
     
         ______________________________________
o     FORM.sub.-- PACK.sub.-- LIGHT - Light packing, used mainly
for
      inter process communication between processes
on
      the same machine. It is more efficient then
      other types of packing. Light packing
consists
      of serializing the given form, but it does
not
      translates the form data into machine
      independent format.
o     FORM.sub.-- PACK.sub.-- XDR - Serialize the form while
      translating the data into a
machine-independent
      format. The machine-independent format used
is
      Sun&#39;s XDR.
______________________________________
 
    
     5.9 Procedural Interface to the Forms-class Package 
     The formclass package is responsible for creating and manipulating forms classes. The forms package uses these descriptions to create and manipulate instances of given form classes. An instance of a form class is called, not surprisingly, a form. 
     
         ______________________________________
Formclass.sub.-- create
     Create a class handle according to the given
     argument list. If the attribute CLASS.sub.-- CFILE is
     specified it should be followed by a cfile handle
     and a path.sub.-- name. In that case formclass.sub.-- create
     locates the specification for the form class in
the
     specified configuration file. The specification
is
     compiled into an internal data structure for use
by
     the forms package.
     Formclass.sub.-- create returns a pointer to the class
data
     structure. If there are syntax errors in the
class
     description file the function sets the error
message
flag and returns NULL.
Formclass.sub.-- destroy
     The class description specified by the given
class
     handle is dismantled and the storage is
reclaimed.
If there are live instances of the class then the
class is not destroyed and the error value is
updated to
&#34;FORMCLASS.sub.-- ERR.sub.-- NON.sub.-- ZERO.sub.-- INSTANCES.sub.--
NUM&#34;.
Formclass.sub.-- get
Given a handle to a form class and an attribute
of a class (e.g. one of the attributes of the
type Formclass.sub.-- attr) Formclass.sub.-- get returns the
value of the attribute. Given an unknown
attribute the error value is updated to
&#34;FORMCLASS.sub.-- ERR.sub.-- UNKNOWN.sub.-- ATTRI-BUTE&#34;.
Formclass.sub.-- get.sub.-- handle.sub.-- by.sub.-- id
Given a forms-class id,
Formclass.sub.-- get.sub.-- handle.sub.-- by.sub.-- id returns the handle
to
the appropriate class descriptor. If the
requested class id is not known
Form-class.sub.-- get.sub.-- handle.sub.-- by.sub.-- id returns NULL,
but
does not set the error flag.
Formclass.sub.-- get.sub.-- handle.sub.-- by.sub.-- name
Given a forms-class name,
Formclass.sub.-- get.sub.-- handle.sub.-- by.sub.-- name returns the
handle
to the appropriate class descriptor. If the
requested class name is not known
Formclass.sub.-- get.sub.-- handle.sub.-- by.sub.-- name returns NULL,
but
does not set the error flag.
Formclass.sub.-- get.sub.-- field.sub.-- id
Given a handle to a form class and a field name
this function returns the form id, which is used
for a fast access to the form. If the given
field name does not exist, it updated the error
variable to
FORMCLASS.sub.-- ERR.sub.-- UNKNOWN.sub.-- FIELD.sub.-- NAME.
Formclass.sub.-- field.sub.-- get
Returns the value of the requested field&#39;s at-
tribute. If an illegal id is given this
procedure, it updated the error variable to
FORMCLASS.sub.-- ERR.sub.-- UNKNOWN.sub.-- FIELD.sub.-- ID.
Formclass.sub.-- iserr
Returns TRUE if Formclass error flag is turned
on, FALSE otherwise.
Formclass.sub.-- errno
Returns the formclass error number. If no error,
it returns FORMCLASS.sub.-- OK. For a list of supported
error values see the file formclass.h.
5.10 The Forms Package
Form.sub.-- create
 Generate a form (i.e., an instance) of the form
class specified by the parameter and return a
handle to the created form.
Form.sub.-- destroy
The specified form is &#34;destroyed&#34; by reclaiming
its storage.
Form.sub.-- get
Given a handle to a form and a valid attribute
(e.g. one of the values of the enumerated type
Form.sub.-- attr) Form.sub.-- get returns the value of the
requested attribute.
The attribute FORM.sub.-- DATA.sub.-- SIZE is supported only
for variable size forms. For fixed size form
this information is kept in the class description
and is not kept with each form instance.
Requiring the FORM.sub.-- DATA.sub.-- SIZE from a fixed length
form will set the error flag to
FORM.sub.-- ERR.sub.-- NO.sub.-- SIZE.sub.-- ATTR.sub.-- FOR.sub.--
FIXED.sub.-- LENGTH.sub.-- FORM.
The attribute FORM.sub.-- FIELDS.sub.-- NUM is supported only
for constructed forms. Requiring the
FORM.sub.-- FIELDS.sub.-- NUM from a primitive form will set
the error flag to
FORM.sub.-- ERR.sub.-- ILLEGAL.sub.-- ATTR.sub.-- FOR.sub.-- PRIMITIVE.sub
.-- FORM.
If the given attribute is not known the error
flag is set to FORM.sub.-- ERR.sub.-- UNKNOWN.sub.-- ATTR. When the
error flag is set differently, then FORM.sub.-- OK
Form.sub.-- get returns NULL.
Form.sub.-- set.sub.-- data
Sets the form&#39;s data value to the given value.
The given data argument is assumed to be a
pointer to the data, e.g., a pointer to an
integer or a pointer to a date structure.
However for strings we expect a pointer to a
character.
Note that we use Copy semantics for assignments.
Form.sub.-- get.sub.-- data
Return a pointer to form&#39;s data portion. In case
of a form of a primitive class the data is the an
actual value of the form&#39;s type. If the form is
not of a primitive class, i.e., it has a non zero
number of fields, then the form&#39;s value is a
handle to the form&#39;s sequence of fields.
Warning, the returned handle points to the form&#39;s data
structure and should not be altered. If the returned
value is to be modified is should be copied to a
private memory.
Form.sub.-- set.sub.-- data.sub.-- pointer
Given a variable size form, Form.sub.-- set.sub.-- data.sub.-- pointer
assigns the given pointer to the points to the
forms data portion. Form.sub.-- set.sub.-- data.sub.-- pointer
provide a copy operation with pointer semantics,
as opposed to copy semantics.
If the given form is a fixed length form then the
error flag is set to
FORM.sub.-- ERR.sub.-- CANT.sub.-- ASSIGN.sub.-- POINTER.sub.-- TO.sub.--
FIXED.sub.-- FORM.
Form.sub.-- field.sub.-- set.sub.-- data
This is a convenient routine that is equal to
calling Form.sub.-- field.sub.-- get and then using the
retrieved form to call Form.sub.-- set.sub.-- data. More
precisely: form.sub.-- field.sub.-- set.sub.-- data(form, field.sub.--
id,
form.sub.-- data, size) ==
form.sub.-- set.sub.-- data(form.sub.-- field.sub.-- get(form,
field.sub.-- id),
form.sub.-- data, size), plus some error checking.
Form.sub.-- field.sub.-- get.sub.-- data
Note that we use Copy semantics for assignments.
This is a convenient routine that is equal to
calling Form.sub.-- field.sub.-- get and then using the
retrieved form to call Form.sub.-- get.sub.-- data. More
precisely: form.sub.-- field.sub.-- get.sub.-- data(form, field.sub.--
id,
form.sub.-- data, size) ==
form.sub.-- get.sub.-- data(form.sub.-- field.sub.-- get(form,
field.sub.-- id),
form.sub.-- data, size) plus some error checking.
Warning, the returned handle points to the form&#39;s data
structure and should not be altered. If the returned
value is to be modified is should be copied to a
private memory.
form.sub.-- field.sub.-- id.sub.-- first
Form.sub.-- field.sub.-- id.sub.-- first sets the given field.sub.-- id
to
identify the first direct field of the given form
handle.
Note that the memory for the given field.sub.-- id
should be allocated (and freed) by the clients of
the forms package and not by the forms package.
form.sub.-- field.sub.-- id.sub.-- next
Form.sub.-- field.sub.-- id.sub.-- first sets the given field.sub.-- id
to
identify the next direct field of the given form
handle. Calls to Form.sub.-- field.sub.-- id.sub.-- next must be
preceded with a call to Form.sub.-- field.sub.-- id.sub.-- first.
Note that the memory for the given field.sub.-- id
should be allocated (and freed) by the clients of
the forms package and not by the forms package.
Fomr.sub.-- field.sub.-- set
Sets the given form or form sequence as the given
form field value. Note that we use Copy
semantics for assignments.
When a nonexistent field id is given then the
error flag is set to FORM.sub.-- ERR.sub.-- ILLEGAL.sub.-- ID.
Form.sub.-- field.sub.-- get
Return&#39;s a handle to the value of the requested
field. The returned value is either a handle to a
form or to a form sequence.
Warning, the returned handle points to the form&#39;s
data structure and should not be altered. If the
returned value is to be modified is should be
copied to a private memory, using the Form.sub.-- copy
function.
When a nonexistent field id is given, then the
error flag is set to FORM.sub.-- ERR.sub.-- ILLEGAL.sub.-- ID and
Form.sub.-- field.sub.-- get returns NULL.
Form.sub.-- field.sub.-- append
Form.sub.-- field.sub.-- append appends the given, append.sub.-- form
argument to the end of the base.sub.-- form form
sequence. Form.sub.-- field.sub.-- append returns the id of
the appended new field.
Form.sub. -- field.sub.-- delete
Form.sub.-- field.sub.-- delete deletes the given field from
the given base.sub.-- form.
If a non existing field id is given then the
error flag is set to FORM.sub.-- ERR.sub.-- ILLEGAL.sub.-- ID and
Form.sub.-- field.sub.-- delete returns NULL.
Form.sub.-- pack
Form.sub.-- pack returns a pointer to a byte stream that
contains the packed form, packed according to the
requested format and type.
If the required packed type is FORM.sub.-- PACK.sub.-- LIGHT
then Form.sub.-- pack serializes the form, but the forms
data is not translated to a machine-independent
representation. Hence a lightly packaged form is
suitable to transmit between processes on the
same machine.
If the required packed type is FORM.sub.-- PACK.sub.-- XDR then
Form.sub.-- pack serializes the form and also translates the
form representation to a machine-independent
representation, which is Sun&#39;s XDR. Hence form packed
by an XDR format are suitable for transmitting on a
network across machine boundaries.
Formclass.h. are implemented as forms, hance Form.sub.-- pack
can be used to pack form classes as well as forms.
Form.sub.-- unpack
Given an external representation of the form,
create a form instance according to the given
class and unpack the external representation into
the instance.
Form classes are implemented as forms, hence
Form.sub.-- unpack can be used to unpack form classes
as well as forms.
Form.sub.-- copy
Copy the values of the source form into the
destination form. If the forms are of different
classes no copying is performed and the error
value is updated to FORM.sub.-- ERR.sub.-- ILLEGAL.sub.-- CLASS.
Formclasses are implemented as forms, hence
Form.sub.-- copy can be used to copy form classes as
well as forms.
Form.sub.-- show
Return an ASCII string containing the list of
field names and associated values for indicated
fields. The string is suitable for displaying on
a terminal or printing (e.g., it will contain
new-line characters). The returned string is
allocated by the function and need to be freed by
the user. (This is function is very useful in
debugging.)
Formclasses are implemented as forms, hence
Form.sub. -- show can be used to print form classes as
well as forms.
Form.sub.-- iserr
Returns TRUE if the error flag is set, FALSE
otherwise
Form.sub.-- errno
Returns the formclass error number. If no error,
it returns FORMCLASS.sub.-- OK. The possible error
values are defined in the file forms.h.
______________________________________
 
    
     GLOSSARY 
     There follows a list of definitions of some of the words and phrases used to describe the invention. 
     Access Procedure: a broader term than service discipline or service protocol because it encompasses more than a communications protocol to access data from a particular server, service, application. It includes any procedure by which the information requested on a particular subject may be accessed. For example, if the subject request is &#34;Please give me the time of date&#34;, the access procedure to which this request is mapped on the service layer could be a call to the operating system on the computer of the user that initiated the request. An access procedure could also involve a call to a utility program. 
     Application: A software program that runs on a computer other than the operating system programs. 
     Architectural Decoupling: A property of a system using the teachings of the invention. This property is inherently provided by the function of the information layer in performing subject-based addressing services in mapping subjects to services and service disciplines through which information on these subjects may be obtained. Subject-based addressing eliminates the need for the data consuming processes to know the network architecture and where on the network data on a particular subject may be found. 
     Attribute of a Form Class: A property of form class such as whether the class is primitive or constructed. Size is another attribute. 
     Class: A definition of a group of forms wherein all forms in the class have the same format and the same semantics. 
     Class/Class Descriptor/Class Definition: A definition of the structure and organization of a particular group of data records or &#34;forms&#34; all of which have the same internal representation, the same organization and the same semantic information. A class descriptor is a data record or &#34;object&#34; in memory that stores the data which defines all these parameters of the class definition. The Class is the name of the group of forms and the Class Definition is the information about the group&#39;s common characteristics. Classes can be either primitive or constructed. A primitive class contains a class name that uniquely identifies the class (this name has associated with it a class number or class --  id) and a specification of the representation of a single data value. The specification of the representation uses well known primitives that the host computer and client applications understand such as string --  20 ASCII, floating point, integer, string --  20 EBCDIC etc. A constructed class definition includes a unique name and defines by name and content multiple fields that are found in this kind of form. The class definition specifies the organization and semantics or the form by specifying field names. The field names give meaning to the fields. Each field is specified by giving a field name and the form class of its data since each field is itself a form. A field can be a list of forms of the same class instead of a single form. A constructed class definition contains no actual data although a class descriptor does in the form of data that defines the organization and semantics of this kind of form. All actual data that define instances of forms is stored in forms of primitive classes and the type of data stored in primitive classes is specified in the class definition of the primitive class. For example, the primitive class named &#34;Age&#34; has one field of type integer --  3 which is defined in the class definition for the age class of forms. Instances of forms of this class contain 3 digit integer values. 
     Class Data Structure: All the data stored in a class manager regarding a particular class. The class descriptor is the most important part of this data structure, but there may be more information also. 
     Class Definition: The specification of a form class. 
     Class Descriptor: A memory object which stores the form-class definition. In the class manager, it is stored as a form. On disk, it is stored as an ASCII string. Basically, it is a particular representation or format for a class definition. It can be an ASCII file or a form type of representation. When the class manager does not have a class descriptor it needs, it asks the foreign application that created the class definition for the class descriptor. It then receives a class descriptor in the format of a form as generated by the foreign application. Alternatively, the class manager searches a file or files identified to it by the application requesting the semantic-dependent operation or identified in records maintained by the class manager. The class definitions stored in these files are in ASCII text format. The class manager then converts the ASCII text so found to a class descriptor in the format of a native form by parsing the ASCII text into the various field names and specifications for the contents of each field. 
     Client Application: a data consuming or data publishing process, i.e., a computer program which is running, other than an operating system program that is linked to the communication interface according to the teachings of the invention. 
     Computer Network: A data pathway between multiple computers by hardware connection such as a local or wide area network or between multiple processes running on the same computer through facilities provided by the operating system or other software programs and/or shared memory including a Unix pipe between processes. 
     Configuration Decoupling: The property of a computer system/network implementing the teachings of the invention which is inherently provided by the distributed communication layer. This layer, by encapsulating the detailed protocols of how to set up and destroy communication links on a particular configuration for a computer network, frees client processes, whether data publishers or data consumers from the need to know these details. 
     Configuration File: A file that stores data that describes the properties and attributes or parameters of the various software components, records and forms in use. 
     Constructed Field: A field which contains another form or data record. 
     Consumer: a client or consumer application or end user which is requesting data. 
     Data Distribution Decoupling: The function of the communication interface software according to the teachings of the invention which frees client applications of the necessity to know and provide the network addresses for servers providing desired services. 
     Decoupling: Freeing a process, software module or application from the need to know the communication protocols, data formats and locations of all other processes, computers and networks with which data is to be interchanged. 
     Distributed Communication Layer: the portion of the apparatus and method according to the teachings of the invention which maps the access procedure identified by the service layer to a particular network or transparent layer protocol engine and sets up the required communication channel to the identified service using the selected network protocol engine. 
     Field: One component in an instance of a form which may have one or more components each named differently and each meaning a different thing. Fields are &#34;primitive&#34; if they contain actual data and are &#34;constructed&#34; if they contain other forms, i.e., groupings of other fields. A data record or form which has at least one field which contains another form is said to be &#34;nested&#34;. The second form recorded in the constructed field of a first form has its own fields which may also be primitive or constructed. Thus, infinitely complex layers of nesting may occur. 
     Foreign: A computer or software process which uses a different format of data record than the format data record of another computer or software process. 
     Form: A data record or data object which is self-describing in its structure by virtue of inclusion of fields containing class descriptor numbers which correspond to class descriptors, or class definitions. These class descriptors describe a class of form the instances of which all have the same internal representation, the same organization and the same semantic information. This means that all instances, i.e., occurrences, of forms of this class have the same number of fields of the same name and the data in corresponding fields have the same representation and each corresponding field means the same thing. Forms can be either primitive or constructed. A form is primitive if it stores only a single unit of data. A form is constructed if it has multiple internal components called fields. Each field is itself a form which may be either primitive or constructed. Each field may store data or the class --  id, i.e., the class number, of another form. 
     Format Operation: An operation to convert a form from one format to another format. 
     Format or Type: The data representation and data organization of a structural data record, i.e., form. 
     Handle: A pointer to an object, record, file, class descriptor, form etc. This pointer essentially defines an access path to the object. Absolute, relative and offset addresses are examples of handles. 
     ID: A unique identifier for a form, record, class, memory object etc. The class numbers assigned the classes in this patent specification are examples of ID&#39;s. 
     Information Layer: the portions of the apparatus and method according to the teachings of the invention which performs subject based addressing by mapping information requests on particular subjects to the names of services that supply information on the requested subject and the service disciplines used to communicate with these services. 
     Interface: A library of software programs or modules which can be invoked by an application or another module of the interface which provide support functions for carrying out some task. In the case of the invention at hand, the communication interface provides a library of programs which implement the desired decoupling between foreign processes and computers to allow simplified programming of applications for exchanging data with foreign processes and computers. 
     Interface Card: The electronic circuit that makes a physical connection to the network at a node and is driven by transparent layer protocol programs in the operating system and network and data-link protocol programs on the interface card to send and receive data on the network. 
     Native Format/Form: The format of a form or the form structure native to an application and its host computer. 
     Nested: A data structure comprised of data records having multiple fields each of which may contain other data records themselves containing multiple fields. 
     Network Protocol Engine: a software and hardware combination that provides a facility whereby communication may be performed over a network using a particular protocol. 
     Node: Any computer, server or terminal coupled to the computer network. 
     Primitive Field: A field of a form or data record which stores actual data. 
     Process: An instance of a software program or module in execution on a computer. 
     Semantic-Dependent Operation: An operation requiring access to at least the semantic information of the class definition for a particular form to supply data from that form to some requesting process. 
     Semantic Information: With respect to forms, the names and meanings of the various fields in a form. 
     Server: A computer running a data producer process to do something such as supply files stored in bulk storage or raw data from an information source such as Telerate to a requesting process even if the process is running on the same computer which is running the data producer process. 
     Server Process: An application process that supplies the functions of data specified by a particular service, such as Telerate, Dow Jones News Service, etc. 
     Service: A meaningful set of functions or data usually in the form of a process running on a server which can be exported for use by client applications. In other words, a service is a general class of applications which do a particular thing, e.g., applications supplying Dow Jones News information. Quotron datafeed or a trade ticket router. An application will typically export only one service, although it can export many different services. 
     Service Discipline or Service Protocol: A program or software module implementing a communication protocol for communication with a particular service and including routines by which to select one of several servers that supplies a service in addition to protocols for communicating with the service and advising the communication layer which server was selected and requesting that a communication link be set up. 
     Service Access Protocol: A subset of the associated service discipline that encapsulates a communication protocol for communicating with a service. 
     Service Instance: A process running on a particular computer and which is capable of providing the specified service (also sometimes called a server process). For a given service, several service instances may be concurrently providing the service so as to improve performance or to provide fault tolerance. The distributed communication component of the TIB™ communication software implements &#34;fault-tolerant&#34; communication by providing automatic switchover from a failed service instance to an operational one providing the same service. 
     Service Layer: the portion of apparatus and method according to the teachings of the invention that maps data received from the information layer to the access procedure to be used to access the service or other source for the requested information to provide service decoupling. 
     Service Decoupling: The function of the service layer of the communication interface software according to the teachings of the invention which frees client applications of the necessity to know and be able to implement the particular communication protocols necessary to access data from or otherwise communicate with services which supply data on a particular subject. 
     Service Record: A record containing fields describing the important characteristics of an application providing the specified service. 
     Subject Domain: A set of subject categories (see also subject space). 
     Subject Space: A hierarchical set of subject categories. 
     Subscribe Request: A request for data regarding a particular subject which does not specify the source server or servers, process or processes or the location of same from which the data regarding this subject may be obtained. 
     Transport Layer: A layer of the standard ISO model for networks between computers to which the communication interface of the invention is linked. 
     Transport Protocol: The particular communication protocol or discipline implemented on a particular network or group of networks coupled by gateways or other internetwork routing.