SE521585C2 - Procedure, computer programs and process control systems for isolating resources from applications - Google Patents

Abstract

The present invention relates to a resource module (38, 40, 42), a resource platform comprising a resource module, an application resource system comprising a resource platform, a process control system comprising an application resource system, a computer program product containing program code for realizing a resource module and a method of isolating a resource from an application. The resource is associated with one of the resource types and comprises said resource module as well as a physical resource (32) and/or an interface to the physical resource (30), at least one action handler for handling a specific action to be performed, by the application, on or for the physical resource and a registrator for registering itself and associated actions handlers (f1, f2, f3) in a register (46) associated with the application, so that the aplication can call an action handler in the resource module for performing an action specialized for the resource type on or for a physical resource.

Description

25 30 521 585 2 also indicates how to handle connection of the physical device to a frame system.

WO93 / 25962 describes a system in which a task running on a local computer can use job execution running on a remote computer. The local task there uses a handle to establish contact with the task on the remote computer.

The computers here have already established some kind of contact or means for establishing contact, before the remote task of the remote computer is used.

EP-A-424 758 describes a method for sharing serially reusable resources among a number of processes. A handle is used here to indicate which resource to use. There is no indication as to what type a resource belongs to, so all the resources must be the same.

US-A-5 313 978 describes a computer system in which different, simultaneously run processes in a network of computer systems communicate data blocks of variable size between each other. A call process retrieves a message handle to be used to indicate to which process a particular data block belongs. This handle is thus connected to the data being transmitted and not to any function to be run on or for the resource or type of function.

J P-A-7 114 476 describes inter-window communications between windows using memory handles.

EP-A-752 646 describes a system for changing the byte representation used for different computers in a computer network, where the computers share the same device drive unit. A handle was used here to indicate in which way data is supposed to be read.

All the resources mentioned above are in each case of only one type. However, there is a problem with interconnecting such resources, when they are of different types, ie. if they contain different functions and have different hardware, requiring different type of information. There is no way in which an application can differentiate between different types of resources in the above-mentioned documents.

US-A-5 388 258 discloses a telecommunication system comprising a software structure in which the present invention can be realized. It also describes the use of modules for controlling physical resources or the handling of communication with such physical resources in a telecommunication exchange system.

SUMMARY OF THE INVENTION The present invention solves the problem of enabling isolation between an application running in a process control system and at least one resource, which the application uses when the resource is one of your possible types.

This problem is solved according to the invention by a method for a computer system comprising a platform server resource which cooperates with an application such as a tool for establishing telecommunication connections and services, for controlling a process system, the platform server resource comprising at least one physical resource and at least one operational resource module such as a tone generator, a switch and / or a signaling means, which method is characterized by the steps of: - the operational resource modules belonging to the platform server resource are identified by means of a platform manager, - a request for activation of at least one operational resource module is sent from the application to each platform manager, operative resource module is registered with functions and management instructions in a register depending on such a request, and the operational resource module is activated to perform an action, .ör a .. the form server resource independent of the application. Thus, an object of the present invention is to provide a method for isolating a resource from an application, both of which are arranged in a process control system and the resource is one of at least two different types.

The method preferably also includes the steps of - a platform manager name for enabled operational resource modules being registered in a system server to notify the application, the registration being performed by the platform manager, - a request for configuration of the operational resource module being sent from the application to the system server by sending the platform manager name the platform manager name, - the platform manager name is returned to the application of the system server, whereby - each activation of an operational resource module includes sending a platform manager name from the application to the platform manager.

The method may also comprise the further steps of: - the operational resource module is activated by the application using activation parameters, such as the module name and / or an activity name, - a so-called broker is used to send data in connection with management instructions, whereby an identity for a particular process can be determined, - the process identity is returned via the broker, and - the physical resource is called using the determined and returned process identity, from the operational resource module.

According to the invention there is also provided a computer program for use in a process control system in a telecommunication system, which computer program consists of executable program code included in a storage medium for use in associating physical resources with the process control system, which supervisor program comprises means for performing the above said procedure. The computer program product is preferably written in a declarative programming language, such as Erlang. According to the invention, there is also provided a process control system for use in a telecommunication system for controlling traffic connections in a telephone network, comprising a platform server resource and at least a functional application, wherein the platform server resource is provided with at least one physical resource and at least one operational resource module, such as a tone generator, a switch and a signaling means, characterized in that - a platform manager is in two-way communication with the functional application and at least one operational resource module, the operational resource module is adapted to be registered together with functions and management instructions in a register, and that - the application is adapted to send a request for activation of at least one operational resource module via the platform manager.

The process control system is characterized according to a preferred embodiment in that - the platform manager comprises means for registering the operational resource modules in a system server intended to be used by the application to obtain information about operational resource modules, - the application comprises means for sending a configuration request the operational resource modules using platform manager names in the system server, and the system server includes means for sending management instructions to the platform manager, thereby enabling the operational resource module to be registered in the application.

Preferably, the application comprises means for activating at least one operational resource module using a notation for the operational resource module, a function and at least one haritization instruction, all of which have been registered, at the same time as the means for activating the operational resource module uses a so-called broker to return the process identity. 10 15 20 25 30 in r \) __ \ u * \, / ll one embodiment is the application, and possibly all units associated with the application, arranged on a first hardware unit comprising one or fl your hardware cards with central processor capacity, and a physical resource is provided in the form of at least one additional hardware card.

The registration is performed to dissolve the connection between the application in the process control system and at least a part of the actual physical resource on which it is run, while at the same time the type of resource is taken into account. In this way, isolation of an application run in a process control system is obtained from the resources used by this application. The advantage of this arrangement is that the application does not need to be changed when the process control system is to be run on a new physical resource. This facilitates the adaptation of the software in the process control system to the physical resource it is to run, and therefore large sums of money can be saved from being consumed on unnecessary software development.

The invention will now be described by means of preferred embodiments and with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a block diagram of a process control system in accordance with the invention, Fig. 2 shows a block diagram of a resource platform in accordance with the invention, connected to an application support system, Figs. 3 shows a block diagram depicting a system administration together with a resource control in a resource platform, which control is connected to a platform handle, a physical resource via a resource interface and an application support system, fig. Fig. 4 'shows a resource module according to the redesign, Fig. 5 shows a flow chart depicting a method for registering a resource in an application in accordance with a first embodiment of the invention, [vw w]. r ~ .- kJ I F ig. Fig. 6A shows a first part of a flow chart depicting a method for registering a resource in an application according to a second embodiment; Fig. 6B shows a second part of the flow diagram depicting a method for registering a resource module in accordance with a second embodiment. with the second embodiment example, and Fig. 7 shows a fate diagram of a method for performing an activity on a resource, which is registered in an application.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS Pig. 1 is a block diagram of a process control system in accordance with the present invention. The process control system is arranged in a computer system and is arranged to run, in accordance with a preferred embodiment of the invention, in a telecommunication system and then preferably arranged to handle a switch, such as Lex. a subscriber exchange, although other types of uses are conceivable. The computer system mainly comprises an application 10, an application support system (ASU) 12, an application resource system (ARE) 16 and an open telecom platform (OTP) 14. The application 10 and the application support system 12 jointly take care of the connection of telecommunication connections and different types of services that can be used for the connected connections, where the services can be such services as, for example, waiting calls. The manner in which these units function is further described in the document US-A-5 388 258, which document is hereby explained to be incorporated by reference. The application and ASU are preferably arranged on at least one central hardware card, comprising at least one processor with associated memories.

The application and ASU 12 are preferably arranged in the form of one or more software modules, written in a declarative programming language, which in the preferred embodiment is Erlang, although other declarative programming languages are conceivable. Erlang is described in the article “Erlang ~ A New Programming Language” by B. Däcker, Ericsson Review No. 2, 1993. ARE 16 includes a system administration 18, three resource platforms 20, 22 and 24, and a system library 26.

The three resource platforms 20, 22 and 24 are connected to the system administration 18 as well as to the system library 26. A first resource platform, the resource platform 1 20, is shown connected to the open telecom platform 14 and connected to the ASU unit via a first interface layer 28. , although in reality all the resource platforms are connected to ASU and OTP in the same way. ASU 12 is also connected to OTP 14. Likewise, the system administration 18 is connected to ASU 12 via said first boundary layer 28.

OTP 14 is a toolbox used by ARE, which OTP includes various tools and libraries for designing process control systems. The open telecom platform is based on the language Erlang and is described in more detail in the article “Open Telecom Platform” by S. Torstendahl, Ericsson Review no. 1, 1997, which article is hereby declared included by reference. It should be emphasized that the open telecom platform is only a tool used to realize the resource platforms, and that they can be realized without this system. The first boundary layer is a so-called SPI (Service Provider Interface) and is preferably arranged in the form of Erlang module, which is affected by some of the functions mentioned in the specification S.300 from ECTF (Enterprise Computer Telephony Forum). This boundary layer is general for physical resources of different types, which are delivered from different suppliers. An interface layer in accordance with the specification S.300 is arranged in the form of a function, written in C or C ++, which means that the SPI in the system in accordance with the present invention is arranged at a higher logic level. The system library 26 is a library used by all platforms and contains components used by all the resource platforms, such as common protocol components, e.g. for signaling over telecommunication lines. The application and ASU also do not have to be separate units, so that ASU can just as easily be arranged in the application.

The manner in which a particular platform is arranged will now be described with reference to Fig. 2, which shows a block diagram of a first resource platform 20, connected to ASU 12 and the various contents of this platform. In the figure, SPI has been omitted. = omitted for clarity, but would of course be arranged between the resource platform and the ASU 12. The resource platform comprises a platform manager 36, which communicates with the ASU 12 as well as with the system administration within the ARE unit (not shown). The resource platform also includes a resource controller 29 and a resource boundary layer 30, both of which communicate with the platform manager as well as with the platform library 34. The resource controller 29, the resource boundary layer 30 and the platform library 34 all communicate with the OTP unit (not shown). The resource boundary layer 30 can be arranged in the form of an Erlang module which handles communication between physical resources and the application together with suitable drive units for driving hardware or other means of communication. It can be arranged in the form of the above-mentioned ECTF S.300 interface layer or implemented using socket communication. The resource boundary layer is used i.a. to provide an opportunity for the application and ARE, which are processes written in Erlang, to be able to communicate with other environments, for example environments written in the language C.

However, it can also be an Erlang module arranged for communication with other Erlang modules arranged on the physical resource. Resource control 29 also communicates with ASU l2. The figure finally comprises a physical resource 32, connected to the resource boundary layer 30. The resource control 29 comprises resource modules of different types, which will be described in more detail later, and the platform library comprises functions common to these different resource modules. These functions are preferably also written in Erlang and may include drive support with common routines for use in encoding / decoding data.

The application, ASU and OTP as well as the entire ARE except the physical resource are preferably arranged on a central hardware card, which comprises a processing unit belonging to memory units. Of course, it is also possible to leave them on different hardware cards or arrange the application and ASU and OTP on one hardware card and OTP and ARE without physical resources on another hardware card. Of course, other combinations are also conceivable. Another possible variation is to arrange the application, ASU, OTP, ARE and the physical resource on the same hardware card. A physical resource may, when the process control system is arranged for controlling a telephone exchange, be a hardware card which comprises the switching core of the exchange and is then of the disconnector type, a hardware card which handles so-called media resources such as tone generation, ine- 10 15 20 25 30 521 5 t: 5 10 slide type and a hardware card for handling so-called network resources, such as handling physical links through signaling, network type. The network type of resources is also called a primary resource, which is a resource controlled by the end user in a process control system. Such an end user may be a subscriber to a telephone network. The media and switch resource types are also called secondary resources, which means resources controlled by the application. In telecommunications, the hardware card can also be another type of card with some or all of the above-mentioned functionalities. Such a different hardware card can be a so-called exchange card, which is a node connected in a ring network. Such a card is described in Swedish patent application SE-9604708-9, which is hereby declared to be incorporated by reference. The switchboard is both part of a connection core and manages network and media resources for this part of the connection core. Another type of physical card may be a hardware card for a computer, such as a PC.

The physical resource can also be arranged as a remote independent resource, such as a database, which the process control system has access to but which is not a hardware card that is directly connected to and controlled by the application. An application only communicates with this physical resource to allow this resource to perform an activity of some kind. The physical resource would then, in the case of a database, have its own computational possibilities, and ARE would be delivering a boundary layer to handle communication with this physical resource instead of handling any activity to be performed on the resource instead. As mentioned earlier, several resource modules can be included in one platform. In the same way, several physical resources can be connected to the resource management 29.

The physical resource is normally connected to the central hardware card via a network of some kind, regardless of the type of physical resource, and then normally via a local area network (LAN).

A resource platform normally handles one type of switching hardware. For example, the above-mentioned media, switching and network hardware cards would be grouped together in one platform, while switchboards would be grouped in a separate platform. There may also be a platform which comprises physical resources which are common to the above-mentioned platforms, and such a platform may then comprise common protocols, such as for example for signaling.

Fig. 3 shows a block diagram with three modules 38, 40 and 42 of different types, arranged in a resource controller 29 in the platform, as well as the platform manager 36 and the system administrator 18, all from fi g. l. A first 38 of the resource modules, module l, is of a type called the media type and handles so-called media resources, such as tone generation, a second 40 of the resource modules, module 2, is of the exchange type and handles the exchange core in a telephone exchange, and the third 42, module 3, is of the network type and handles the trunks and terminals connected to the exchange core, as well as the signaling for such trunk lines. These modules are designed to manage the resources of these types, regardless of where they are delivered, ie. regardless of whether a resource type is present on a specific hardware card, dedicated to that resource type, or on a hardware card, which is arranged for fl your resource types. The modules are written in a declarative programming language, which in this embodiment is Erlang. The figure also shows a system server 44, a platform server 46 or registers, arranged in ASU 12. ASU 12 also comprises the first boundary layer 28, which, as previously stated, constitutes one or more modules, written in Erlang. The system server 44 comprises for each platform a name for a platform, PL1, the name of at least one function in the platform, start card. The register 46 comprises for each resource module in a platform the functions f1, f2 and B with associated handles, handles 1, handles 2 and handles 3. The platform manager 36 communicates with the system server 44 via the first boundary layer 28, and the first resource module 38 communicates with the platform server 46 via the first boundary layer 28. A specific physical resource 32 in the form of a hardware card is also shown connected to a second or resource boundary layer 30. The second boundary layer 30 is connected to the pre-cache module 38. The figure finally shows a broker 50 connected to the first m F * p: H 38 of the resource modules. A broker is a process written in Erlang, which when called with a handle returns the identity of a particular process. The term process is 10 15 20 521 5 å) 5 12 well known in the Erlang world, and Erlang and its structure are described in, for example, the articles “Prototyping Cordless Using Declarative Programming” by I. Ahlberg, J-O. Bauner and A. Danne, Ericsson Review No. 2, 1993, which is hereby declared to be incorporated by reference, and the above-mentioned article “Erlang - A New Programming Language” by B. Däcker, Ericsson Review No. 2, 1993. The other resource modules would normally also be linked to physical resources and may as well include brokers. The figure shows only one platform server, and this platform server keeps track of all the platforms and resource modules in each platform. However, it is possible to arrange several platform servers, one for each platform.

Fig. 4 shows the contents of the first module, which as mentioned above is a media type module and has a name Medial and comprises a means 52, for registering the module or the registrar, and means f1, f2, f3 for handling activities to be performed on a physical card in the form of various functions included in the module. These functions are also called activity managers. The means for registration include a registration function that can be activated by the platform manager as well as the name of all functions in the module, and for at least one of the functions, a handle cooperating with the function.

Fig. 5 shows a fate diagram illustrating a method for registering a resource in an application according to a first embodiment of the invention.

Figs. 6A and B show a flow chart illustrating a method of registering a resource in an application according to a second embodiment of the invention.

The method of registering a resource in an application according to the first embodiment will now be described with reference to Figs. 1, 2, 3, 4 and 5.

In this first embodiment, the resource type is the above-mentioned media type. (X) LJ] 13 What first happens, assuming that system administration 18 is started in ARE 16 and that system server 44 and platform server 46 are started in ASU, is that system administration 18 starts each platform 20, 22, 24 by starting resp. tive platform manager 36 in procedure step 60. Since these different units are in reality processes written in a declarative programming language, Erlang, a platform manager 36 is started by the system administration by calling the module platform manager. Thereafter, the platform manager 36 identifies the physical resources connected to the platform, procedure step 62. In the present case, the hardware card 32 is a media type card. The media-type resource module is then initialized, procedure step 76 ??. For media resources, this is done by the platform manager by calling a media module, which in turn connects to a resource boundary layer 30. The resource boundary layer examines the actual physical resources that are allocated and the types, ie. what kind of hardware card they are.

Through the above identification, the platform manager has been provided with a list of physical resources to be used as indie resources. The platform manager then calls the first module 38 and starts it, after which the resource module registers itself in the platform server. Instead of the platform manager starting the resource module, the resource module may also have been started by a supervisor in ARE, which supervisor could also be an Erlang module. This monitor, also arranged in the form of an Erlang module, would then start all resource modules.

To start the resource module media 1 38, the platform manager comprises a function for calling the associated resource module. This function is first retrieved, procedure step 64, which call function then requests registration of a resource module in the platform server, procedure step 68. In the present case, the first resource module 38 is requested to register itself in the platform server 46. The resource module therefore registers itself in the platform server during use of the resource module name, ie. media l, the functions of the module together with possible handles connected to the functions, procedure step 70. The registration is of course performed via the first boundary layer 28. 10 15 l \) Out 30 521 Ešiålšš 14 When the resource module registers, it registers its name, media l , the functions present in the module, which are the functions f1, f2 and f3, together with the function handles, handle 1, handle 2, handle 3, which are connected to the functions.

Not all features may need handles.

The registration is performed so that the application can perform a certain activity on or for the registered resource. An activity on a resource can be such as activating tone generation on the physical resource, while an activity for a resource can be such as setting up a connection to the physical hardware to send a request and receive a response to this request from the physical resource. The activity of a resource can also be the protocol conversion to be used to interface the application to a remote database, which database can perform any activity, such as collecting certain information and returning it to the application. The registration is performed by the registration means 52 or the registration function located at the top of the module 38.

Then all other resource modules are registered in the platform server 46.

The method of registering a resource in an application will now be described in accordance with the second embodiment, with reference to Figs. 1, 2, 3, 4, 6A and 6B. In this second embodiment, the resource type is the above-mentioned network type.

What happens first is, assuming that the system administration 18 is started in ARE 16 and that the system server 44 and the platform server 46 are started in ASU, that the system administration 18 starts a specific platform 20, 22, 24 by starting the respective platform manager 36, procedure step 72. Next, the platform manager 36 identifies the physical resources connected to the platform, procedure step 74.

For the sake of simplicity and for the description of the invention, here is a single resource module cooperating with a single physical resource. Once the platform manager 36 has identified the physical resources, it registers itself in the system server 44 via the SPI or first boundary layer 28, procedure step 78. This registration is done by the platform manager sending its own name, the platform manager name PL1 together with at least one function per resource included in the platform manager that can be called by the application to start a resource, as well as the hardware mode that the resource occupies.

The functions of the call manager that can be called are functions for associating resource modules with the application.

For the boot platform 20, the platform manager 36 registers the platform name PL1, a function boot card, and the network card hardware mode. Then the application 10 is called the system server 44 in ASU 12 and requests the system configuration, procedure step 80. This is done so that the application will gain knowledge of the resources it has available to be able to run different resources in the process. The system configuration is called by the application calling the Erlang-inodul system server. In response to this call, the application receives the above information about each platform, procedure step 82.

The application then proceeds by requesting the start of the resource module by calling the platform manager 36 using the platform manager name, the function start card and the hardware mode of the card where the network interface layer is located, procedure step 84. The call is of course sent via the first interface layer 28.

Alternatively, only the platform manager name would have been used to call a module. In that case, the platform manager would come into contact with a function that calls a resource module using a broker.

The platform manager then calls a function that handles the network resource module, procedure step 86. This function then calls the cooperating network resource module and requests registration of the network resource module in the platform server, procedure step 10 l5 20 30 Såššš 16 88. The network resource module therefore registers itself in the platform the media resource did in the first embodiment, procedure step 90.

When a network resource is registered in the register, the name of a so-called callback function in the network module of the application. This redial function must be called by the network module in the event of a specific event. Thus, there are different callback functions in the application for different events.

In the procedure described above in the first embodiment, only one media resource was started in the platform. It is possible to start more than one resource module for the physical resources within a platform. Thus, the platform server could contain several media modules and several network modules. When there are fl such modules of one type in one platform and several hardware cards of media type, there may be another Erlang module in the resource management. This module is an allocator that is registered in or for the application in the same way as the media module described in the first embodiment. This allocator is used to allocate a resource and therefore, when called, returns a selected hardware card and a resource in that card. However, the switch or gear module is normally only one module.

A switch module is further registered in the same manner as the inediain module described in the first embodiment of the invention.

An activity on or for an exchange resource comprises setting up or disconnecting a connection between a secondary resource and a primary resource, between two or more primary resources and between two secondary resources. An activity on or for a media resource, for example transmitting a tone, comprises allocating a media resource, by obtaining a media resource via the above-mentioned allocator, as well as ordering the media card to start broadcasting tones. In order for someone to hear a tone, of course, the media resource must also be linked to a primary resource via switching resource. 10 20 30 521 53:35 17 If the physical resource had been a so-called private exchange, a media module, an exchange module, module 2, and a network module, module 3, would have been started for the exchange. If the network comprises several switches connected by an optical ring, as stated in the above-mentioned Swedish patent application, all three of these modules could cooperate with fl your such switches.

The registration is performed to release or slightly dissolve the connection between the application and the actual hardware on which it is running, while taking into account the type of resource. In other words, it is performed to isolate an application running in a process control system from the physical resources used by this hardware. The big advantage of this arrangement is of course that the application and ASU do not need to be changed when the process control system is to be run on new hardware. This makes the adaptation of the software in the process control system to the hardware on which it is to be run easier, and consequently large economic values can be saved from consumption of unnecessary software development, which development is only done to modify an application to the software. on which it is run.

To exemplify how the dependence between the application and the hardware is made less strong, a short example will now be given of how the application can use a registered resource module.

The description is made with reference to tig. 1, 2, 3, 4 and 7, which later figure shows a flow chart of a method for performing the tone generation activity on the resource module 38. First of all, when running, the application 10 receives information that a media function is to be performed. This is done by the network resource module receiving a certain event. This event can be information about a user of a tele- _ _ ° 1. ._ TT "_. Aren from kiykaii. Rrandelseri is routed from there to a function in the network p ^ fl A“ “n .M- fl- QAVV. l-, Û4 ^ .. l LUUCIIJPGLGL, bUlll lylLCl l the resource module that handles an appropriate callback function The function that handles the callback function calls the first boundary layer using an event reporting function, where the name of the callback function and the event was used as an argument, of course several arguments can also be included in the call.

The event reporting function in the first boundary layer then calls the callback function in the application and thereby reports the event to the application.

The application therefore decides that one tonne shall be generated. The application 10 contacts the platform server 46 to obtain information about the correct resource module and function, procedure step 92. Thereafter, the application calls the function fl in the module media 1 38 using the function handle 1, procedure step 94. Thereafter, the called function fl i begins. the module media 1 to run and in turn calls the broker 50 using handle 1, procedure step 96. The broker returns a process identity, obtained by means of handle 1, to the function fl, procedure step 98. Then the function fl calls a part of the resource module media 1, which handles a specific part of the physical resource 32, procedure step 100. This part of the module is arranged to order a specific part of the hardware to start a production of one ton. In doing this, the second boundary layer is used to actually call the specific part of the hardware. The process identity returned by the broker depends on the physical resources used. For example, a certain media hardware card has a process identity and another media hardware card has a different process identity. At a gear, ie. a hardware card that handles switchboard, media and network resources, a process identity is arranged for a specific card in all three types of resource modules.

The example given above has been provided with reference to a media card. The same principles for calling a certain part of a hardware card can be applied to a network card, for example when it comes to signaling. In the case of network cards and signaling, there are different types of signaling that can be applied. Different handles can be used here to designate different signaling schemes to be used on a telecommunication line. In the case of a hardware card that contains a change core, handles do not need to be used when a part of the card is called. 10 15 20 19 What is described above is a decision on which part of a hardware card is to generate toner. Of course, the tones generated must be delivered to a telecommunication line. This is done by connecting the part of the media hardware, where the tone is generated, to a part of the network card, where the terminal is located. How such a connection is made is something that is well known to those skilled in the art, which is why it will not be further described here.

In the case of a private exchange, arranged as a node in a network of nodes, connected by optical fiber, several resource modules would call the same hardware card. In the same way, some or parts of the functions in a resource module can be arranged on the hardware card so that the resource module calls an Erlang function on the physical card via the second boundary layer. This can be achieved by using distributed Erlang, when the function is constructed on the gear.

The ARE and each platform within it, in addition to the physical resources, can also be arranged in the form of one or more computer software products or data carriers, such as CD-ROMs or floppy disks, which become operational after being loaded on a hardware card.

The invention is of course not limited to the embodiments described above and shown in the drawings, but can be modified within the scope of the following claims.

Claims (1)

1. 0 15 20 25 30 521 sss§ft_i “20 Patentkrav. A method for a computer system comprising a platform server resource (20) which cooperates with an application (10) such as a tool for establishing telecommunication connections and services, for controlling a process system, the platform server resource (20) comprising at least one physical resource (32) and at least one operational resource module (38, 40, 42) such as a tone generator (38), a switch (40) and / or a signaling means (42), which method is characterized by the steps of: the operational resource modules ( 38, 40, 42) belonging to the platform server resource (20) is identified (step 74) by means of a platform manager (36), a request for activation of at least one operational resource module (38, 40, 42) is sent (step 84) from the application (10) to the platform manager (36), each operational resource module (3 8, 40, 42) is registered with functions (f1, 12, f3) and management instructions (handle 1, handle 2, handle 3) in a register (46) (step 70; step 90) in dependence on such a request and the operational resource module (3 8, 40, 42) is activated (step 94) to perform an action, to make the platform server resource (20) independent of the application (10). . The method of claim 1, characterized by the further steps of registering a platform manager name (PL1) for activated operational resource modules (38, 40, 42) (step 78) in a system server (44) to communicate the application (10), wherein the registration is performed by the platform manager (36), a request for configuration of the operational resource module (38, 40, 42) is sent (step 80) from the application (10) to the system server (44), by sending the platform manager name (PL1) via the platform manager ( 36), the platform manager name (PL1) is returned (step 82) to the application (10) of the system server (44), each activation (step 84) of an operational resource module (3 8, 40, 42) includes transmitting a platform manager name (PL1) from the application (10) to the platform manager (36). Method according to one of the preceding claims, characterized by the further steps of: - activating the operational resource module (38, 40, 42) (step 94) by means of the application (10) using activation parameters, such as the module name, and / or an activity name, - a so-called broker is used (step 96) to send data in connection with handling instructions (handle, handle2, handle3), whereby an identity for a certain process can be determined, - the process identity is returned (step 98) via the broker, and - the physical resource (32) is called (step 100) using the determined and returned process identity, from the operational resource module (38, 40, 42). Method according to one of the preceding claims, characterized in that the process control system is provided in a telecommunication system, for controlling traffic connections in a telecommunication network. A computer program for use in a process control system in a telecommunication system, the computer program comprising executable program code contained in a storage medium for use in associating physical resources (32) with the process control system, characterized in that the computer program comprises means for performing the method according to any one of claims 1-4. Computer program product according to claim 5, characterized in that the program code is written in a declarative programming language, such as Erlang.. Process control system for use in a telecommunication system for controlling track connections in a telephone network, comprising a platform server resource (20) and at least one functional application (10), the platform server resource being provided with at least one physical resource (32) and at least one operational resource module (38, 40, 42), such as a tone generator (38), a switch (40) and a signaling means (42), characterized in that a platform manager (36) is in two-way communication with the functional application (10) and at least one operational resource module (38, 40, 42), the operational resource module ( 38, 40, 42) is adapted to be registered together with functions (f1, f2, f3) and handling instructions (handles, handles2, handles3) in a register (46), and that the application (10) is adapted to send a request for activation of at least one operational resource module (38, 40, 42) via the platform manager (36). . Process control system according to claim 7, characterized in that the platform manager (36) comprises means for registering the operational resource modules (38, 40, 42) in a system server (44) intended to be used by the application (10) to obtain information about operational resource modules (3 8, 40, 42), the application (10) comprises means for sending a request for configuration of the operational resource modules (3 8, 40, 42) using platform manager names (PL1) in the system server ( 44), and the system server (44) includes means for sending handling instructions (handles, handles2, handles3) to the platform manager (36), thereby enabling the operational resource module (38, 40, 42) to be registered in the application. Process control system according to one of Claims 7 to 8, characterized in that: the application (10) comprises means for activating at least one operational resource module (38, 40, 42) using of a notation for the operational resource module (medial, media2, media3), a function (f1, f2, f3) and at least one management instruction (handle, handle2, handle3) which have all been registered, and - the means for activating it The operational resource module (38, 40, 42) uses a so-called broker (50) to return the process identity A process control system according to any one of claims 7-9, characterized in that the application (10) is arranged on a first hardware unit comprising one or more several hardware cards with central processor capacity and a physical resource (32) are provided in the form of at least one additional hardware card. 15 l. Process control system according to any one of claims 7-10, characterized in that all units associated with the application (10), including the register (46), are arranged in the first hardware unit.