DE4438698A1 - Method of loading multi-computer systems - Google Patents

Abstract

The method involves calculating mod-modules (M1 to M9) or computers, the loading unit (LS) and the communications network (KN). The data sets in the loading unit are divided into a first part (CP) common to each group of data sets and a second part (SP) for each group. The two parts are sent over different paths (P1' to p3', P1 to P3) of the network to the appropriate module, and the two parts are re-combined in each module and stored. Each group is formed from a number of sets (SET 1 to SET 2).

Description

The invention relates to a charging method for a multi-computer system according to the preamble of claim 1, a charger according to the preamble of claim 7, a computer module according to the Preamble of claim 8, a multi-computer system according to the Preamble of claim 9 and a switching system according to the Preamble of claim 11.

With one of several interconnected computer modules existing multi-computer system, there is increasing demand that Software for the individual computer modules via a central Load service into the computer modules. Usually here proceeded in such a way that the software for the individual computer modules, thus the data records for the individual computer modules, from one central charging module in which they are stored, one after the other be loaded into the associated computer modules.

However, this procedure has the disadvantage that with one larger multicomputer system with a large number of computer modules much time is required until the charging process is finished. There the multicomputer system usually does not during the loading process  is operational and therefore cannot be used a great interest in keeping this time as short as possible. Another such charging process is in the European Patent application with the application number 84200783.3 and the title "Multiple memory loading system" (our internal file number M. Edmond 3-3). This charging process is special intended for switching systems, since this is a multi-computer system with a large number of computer modules.

With this loading method, a data record that is in a set of several computer modules to be loaded, in the "avalanche procedure" distributed on this. The data record is first of all from Load module loaded into several predetermined computer modules and from This then again in several, by a distribution list certain computer modules.

This loading method ensures that a data record, the should be loaded into several computer modules, very quickly in this is loaded. However, the differ for the Computer modules certain data records, so this brings Loading method no advantage.

The object of the invention is now a variety of Records into a variety of records in the shortest possible time To load computer modules.

The task is solved by a method according to the teaching of Claim 1, by a charging device according to the teaching of claim 7, by a computer module according to the teaching of claim 8, by a Multi-computer system according to the teaching of claim 9 and by a Switching system according to the teaching of claim 11.

The basic idea of the invention is that the data records into one first part common to a group of computer modules and in to separate a second, special part and about different  Load communication channels into the computer modules. This will the effort (e.g. separating and merging records) increases, but so it is possible, depending on the type of transfer (Point to multipoint / point to point) adapted communication channels to choose.

Advantageous embodiments of the invention are the See subclaims.

An advantage of the invention is that the common part of a Data set via a point-to-multipoint connection at the same time can be sent to several computer modules and only the special part transmitted via a point-to-point connection must become. This will, especially with large groups of Data sets and with a large share of the common part on Record, a significant reduction in loading time achieved. These Shortening also results if all computer modules contain different records.

Another advantage of the invention is that the common part and the special part loaded into a computer module at the same time can be. In this way, all communication connections can be one Computer module can be used and a data record can be repeated Max. be loaded faster by a factor of two.

The use of data compression according to the invention special part of the data records has the additional advantage that the loading time of the special part again by a factor of 3 to 4 is shortened. It is particularly advantageous here to compress a special part because that part is due to its composition (mostly parameters, general part mostly Code) better suited for data compression and loading time of the special part goes into the total time to a greater extent because the common part in parallel in several computer modules and so is already loaded faster overall.  

Another advantage is that the choice of groups that Loading procedure to the existing communication network structure can be adjusted and so the resources of the existing Communication network can be optimally used for the charging process.

In the following the invention is based on an embodiment further explained with the aid of the enclosed drawings.

Fig. 1 shows a block diagram of a switching system according to the invention with an inventive charging device and a plurality of computer modules according to the invention.

FIG. 2 shows a detailed block diagram of a detail from the switching system according to the invention according to FIG. 1.

Fig. 3 is a block diagram showing a charging device according to the invention according to FIG. 1 and FIG. 2.

Fig. 4 shows a block diagram of a computer module of the invention according to FIG. 1 and FIG. 2.

In the exemplary embodiment, the application of inventive method in an inventive Switching system with a charging device according to the invention and explained with several computer modules according to the invention. On Switching system is only an example for one Multi-computer system selected. It is also possible to implement the invention in to use other multicomputer systems, for example in one mainframe consisting of several computer modules or in one System in which distributed individual computers work together.  

Fig. 1 shows the switching system having a charging device LS, a communication network CN and nine computer modules M1 to M9. The computer modules M1 to M3, M4 to M6 and M7 to M9 each form a set of SET1, SET2 and SET3 of computer modules, the sets SET1, SET2 and SET3 each being formed by computer modules of a switching center EX1, EX2 and EX3.

Exchange the charger LS and the computer modules M1 to M9 Messages over the communication network SN.

The communication network KN is one or more, via Connection lines interconnected digital Coupling networks and several connected to them Communication buses formed. It is not just for Message transmission on telephone and data connections and thus the actual switching task of the switching system, but also the exchange of information between the computer modules M1 to M9 and between the computer modules and the charging device LS.

It is also possible that the communication network KN is different is designed. It can be from any communication network with distributed or centralized placement procedures be the message exchange between the loading facility LS and the computer modules M1 to M9 guaranteed.

The computer modules M1 to M9 are, for example terminal modules for analog subscriber, MF signaling (MF = M o f requency), clocks and tones or operation and maintenance. They are each made up of at least one processor, at least one memory and corresponding peripheral components. Furthermore, they have at least one connection to the communication network SN, via which they can receive data and control commands.

The number of nine computer modules M1 to M9, the assignment of the Computer modules M1 to M9 for the sets SET1 to SET3 and the The number of three sentences is chosen here only as an example. It is further possible that the computer modules perform other tasks. This is not important for the invention. The exact structure of a digital switching network or the Computer modules M1 to M9 can exemplify the article "Hardware structure", pages 135 to 147 of the magazine "Electrical communications", volume 58, number 213, 1981 or other articles can be found in this volume.

The charging device LS consists of at least one computer corresponding peripheral components and has at least a connection to the communication network KN. There are nine in it Data records saved, one for each computer module. Each of these Data records contains both the control programs and the data, which are necessary for the operation of the respective computer module. Such a record can also be called the function designate software controlling a computer module. These Data records are sent from the charging device LS to the respective one of the Computer modules M1 to M9 sent.

However, it is also possible that not one for every computer module Data record is stored in the charging device LS because for example, the same data record to several computer modules is sent or only to a part of the computer modules M1 to M9 Records are sent. The first can in multi-computer systems, in which a large number of computer modules perform the same tasks have (e.g. connection modules for analog subscribers) quite often be the case, the second may be the case if software is only changed for some of the computer modules should.  

Now new software should be loaded into the computer modules M1 to M9 proceed as follows:

First, the switching system or parts of it Switching system brought into the state of charge. Then sends the Charger LS the data records to the computer modules M1 to M9, in which they are then saved. After that it will Switching system brought back into the operating state, the Computer modules M1 to M9 now start according to the new one Software to work in the records.

It is also possible for the computer modules to perform their functions still run while the battery is charging. This can can be achieved, for example, in that the new software loaded parallel to the old one and only after the loading process has been completed the process of the old software stopped and with the execution of the new software is started.

The exact sequence of the loading process will now be explained with reference to FIGS . 2 to 4 for the set SET1 with the computer modules M1 to M3. The loading procedure for the other two sets SET2 and SET3 is similar.

Fig. 2 shows a detail of the switching system to the charge device LS, the communication network CN and the set SET1 with the three computer modules M1 to M3. The communication network KN has a switching network SN, a bus access module CTM, and a communication bus BUS.

Furthermore, six communication paths P1 to P3 and P1 'to P3' through the communication network KN are shown in FIG . The communication paths P1 to P3 lead from the charging device LS via the switching network SN to the computer modules M1, M2 and M3. The communication paths P1 'to P3' lead from the charging device LS via the switching network SN, via the bus access module CTM and via the communication bus BUS to the computer modules M1 to M3.

The switching network SN is a switching network for a switching system, through which communication connections are switched optionally can. Such a coupling network is for example in the article "Digital coupling network" pages 135 to 147 of the magazine Electrical communications, volume 58, number 2/3, 1981 closer described.

The communication bus BUS comes with an access protocol operated, with which it is possible to receive data from the bus access module Distribute CTM to the computer modules M1 to M3 in one step. The simplest form of such an access protocol is that Data according to a certain clock pattern from that Send CTM bus access module to modules M1 to M3. It is however, it is also possible to use a communication bus BUS Divide multiplexing into different channels or one more complex access protocol, such as CSMA / CD (ETHERNET), TOKEN-BUS or polling. In such Protocols might also require the data packets one after the other from the bus access module CTM to the computer modules M1 to send to M3.

The communication bus BUS is advantageously the Communication bus used in the exchange EX1 is used to send clocks and tones to the computer modules Switch to send.

It is also possible to have data in parallel across several Send communication buses to the computer modules M1 to M3. This would be advantageous, for example, if several Communication buses available within an exchange are.  

The bus access module CTM has the task of sending data to the Computer modules M1 to M3 are directed and it over the Coupling network SN receives via the communication bus BUS to the To forward computer modules M1 to M3. The CTM bus access module is for example from a connection module for clocks and tones formed, the control program is modified so that it this Task takes over. This modification of the control program can be permanent here, d. H. it will be a corresponding one Control program loaded into the bus access module CTM, both in the Operating and charging status is active and both ROUTER function as well as the function of a connection module for Executes bars and tones. A second option is one special control program at the beginning of the state of charge in the Load the bus access module CTM that performs the ROUTER function and at the end of the state of charge another control program in the Load module CTM, which only functions as a connection module for Executes bars and tones. The loading of these control programs can here by direct charging from the charging device LS via the Coupling network SN take place or also with the invention Charging procedure if more than one such bus access module on one Communication bus is connected.

It is also possible that there are more on the communication bus BUS Computer modules are connected, one from the bus connection module CTM received data packet, however, only to the computer modules M1 to M3 is sent. However, this would be a corresponding one Access log required.

It is also possible that the connecting paths P1 'to P3' are not via the internal communication bus BUS of the exchange EX to lead. These connection paths can be via any, for Carry a suitable sub-communication network for broadcast transmission, the arbitrary computer modules and therefore not necessarily the  Computer modules of a switching center connects. At Instead of broadcast connections, several could be used Individual connections are established one after the other.

The charging process runs like this for the computer modules M1 to M3 follows from:

The charging device LS divides the data records for the Computer modules M1 to M3 are intended in a first, for all three computer modules M1 to M3 general part CP and one second part SP, which is special for the respective computer module. The Charging device LS has four different partial data records To distribute computer modules M1 to M3: a general part CP, which it has to send to each of the computer modules M1 to M3 and three special parts SP, which you connect to the computer modules M1, M2 and M3 has to send. It then sends these four partial data records to the computer modules M1 to M3, with the general part CP via the connecting paths P1 'to P3' and the special parts SP sends via the connection paths P1 to P3. In the computer modules M1 to M3 the partial data records are then reassembled and the data record thus restored is saved.

The exact structure of the charging device LS will now be described with reference to FIG. 3.

Fig. 3 shows the loading means LS. The charging device LS has a storage device MEM1, a disassembly device PART, a compression device COMP, a transmission device SEND and a control device CONTR1.

The disassembling device PART swaps with the storage device MEM1 data and sends data to the compression device COMP and to the transmitting device SEND. The sending device SEND receives data from the compression device COMP and from the  Cutting device PART and sends data via the Communication network KN. The control device CONTR1 exchanges the disassembling device PART and with the transmitting device SEND Tax data.

The data records for the are in the memory device MEM1 Computer modules M1 to M9, data on the assignment of these Data sets for the computer modules and data about the System configuration saved. At the storage facility MEM1 is a storage device that has a can store a large amount of data permanently for example, a hard disk space.

The cutting device PART reads the data records and the others Forms data in succession from the memory device MEM1 Groups of records and then splits the records within the group into a common part CP and a special part SP. The special parts SP then sends them to the Compression device COMP and the common part CP to the SEND transmitter.

For the formation of groups of data sets, the Cutting device PART the data on the assignment of Data records for computer modules and the data about the System configuration. From the data on the System configuration receives data about the assignment of the Computer modules M1 to M9 to the exchanges EX1 and EX3 and thus those sets of computer modules that have a Communication bus can be reached. From the data on the It then determines the assignment of data records to computer modules from these sets of computer modules groups of data sets, For example, here from the sets SET1 to SET3 three groups of Data sets that correspond to the computer modules of the sets SET1 to SET3 assigned.  

With a different configuration of the communication network KN would have to the sets of computer modules are put together differently. It would make sense here, depending on the configuration such computer modules for a set of computer modules summarize that over one for broadcast transmission suitable sub-communication network can be reached.

It is also possible to add other or different criteria for the To form groups. For example Records that are very similar since they are used for computer modules same function are grouped together. However, it is also necessary to click on the configuration Consideration, for example, whether the the records computer modules assigned to such a group via a Communication bus can be reached.

It is further possible that in the memory device MEM1 instead of the data about the system configuration, data about an assignment of records to groups are stored.

For dividing the records of a group into one common part CP and a special part SP determines the Cutting device PART the largest common share of the Records of a group and splits it as a common part CP from. However, it is also possible that this decomposition after functional aspects. For example, the Part of the data records that affect the actual control program (e.g. code, batch, replicated relations) as a common part of CT and the part that represents operational and environmental parameters as special part SP can be separated.

The compression device COMP performs data compression for the special part SP of the data records. Suitable for that  Compression and decompression algorithms are for example the algorithms LZ 77 or LZ 78 known to a person skilled in the art Another suitable algorithm is for example in the U.S. Patent US 4,558,302.

However, it is also possible to use data compression and Decompression and thus also the compression device COMP to renounce.

The transmitting device SEND provides the communication services necessary for sending data via the communication network KN and carries out the sending of data and control commands to the computer modules M1 to M9. The transmitting device SEND receives the special parts SP and the general part CP of a group of data records from the cutting device PART. In addition, it receives data RD from it via the assignment of data records to computer modules. Then, via the communication network KN, it establishes first connection paths for the general part CP and second connection paths for the special part SP to those computer modules to which the parts CP and SP are assigned according to the data RD. For example, it builds up three first connection paths P1 'to P3' and three second connection paths P1 to P3 to the computer modules M1, M2 and M3 according to FIG . After sending the parts CT and SP to the corresponding computer modules, she clears the connections again and then repeats this sending procedure for the next group of data records.

It is also possible for the transmitting device to have the parts SP and CP via a connectionless parcel service to the computer modules M1 until M3 sends. It would not be a connection or disconnect necessary and the different communication routes on which the Parts CP and SP would be transported through the Allocation to different packages with different ways surrender.  

It is also possible that the transmitting device SEND simultaneously sent several different groups of records and thus a multitude of different connection paths at the same time served. This parallel processing of several groups can also done in that several sentences of Disassembly facilities, compression facilities and Transmitting devices are available that point to the storage device Access MEM1.

The control device CONTR1 controls the sequence of the charging process. It sends a corresponding one at the beginning of the state of charge Control command via the transmitter SEND to the computer modules M1 to M3, which puts them in the state of charge. Then she points the disassembly device PART and the transmission device SEND to the To distribute data records to the computer modules M1 to M3. Is this Distribution completed, it sends via the sending device SEND a control command to the computer modules M1 to M9, which this returned to the operating state.

The exact structure of the computer modules M1 to M3 is now shown by way of example on the computer module M1.

Fig. 4 shows the computer module M1. It has two receiving devices REC1 and REC2, a decompression device DECOMP, an assembly device COMB, a memory device MEM2 and a control device CONTR2.

The receiving devices REC2 and REC1 receive data on the Communication network KN and sends data to the Merger COMB or via the Decompression device DECOMP to the assembly device COMB. The memory device MEM2 receives data from the  Merger COMB and exchanges data with the Control device CONTR2. The control device CONTR2 exchanges Control data with the receiving devices REC1 and REC2.

The receiving devices REC1 and REC2 provide the necessary ones Communication services ready to transfer data over the switching network SN or via the communication bus BUS. Receive data, sent by the charging device LS to the computer module M1 and the part SP or CP of a data record correspond, they forward this data to the Decompression device DECOMP or directly to the Merging device COMB further.

The decompression device DECOMP does that in the Compression device COMP performed data compression again undone. It leads the inverse for the special part SP Compression algorithm by.

The assembly device consists of the parts SP and CP them from the receiving device REC1 via the Decompression device DECOMP or from the receiving device REC2 receives the original record again. she leads for this purpose the inverse algorithm to that in the cutting device PART performed algorithm. Here it is under It may be necessary for the part SP or CP to be cached until the other part is received. Then it saves the data record in the Storage device MEM2.

The control device CONTR2 controls the Loading process in the computer module M1 and performs during the Operating state with peripheral components not shown here the functions of the computer module, for example as Subscriber connection module through. At a first control command from  the charging device LS, which via the receiving device REC1 received, it changes from the operating state to the charging state above. The data record is loaded into the memory device MEM2 and receives a second control command from the Charging device LS, it goes from the state of charge to the Operating state and performs its function from this point on in accordance with that in the memory device MEM2 stored data record, d. H. under the control of it software included.

With a software implementation for the loading process responsible function of the computer module M1, it is also possible that the software for these functions or for a part of them Functions even at the beginning of the state of charge via the Communication network KN is loaded into the computer module M1. This is particularly useful for the functions of the Receiving device REC2, the decompression device DECOMP and the COMB joining device.

Claims (12)

1. Charging method for a multicomputer system for loading a large number of data records from a charging device (LS) via a communication network (KN) into a large number of computer modules (M1 to M9), characterized in that the data records in the charging device (LS) into the first, for each group of data sets, common parts (CP) and second, special parts (SP) are divided so that the data sets are sent from the loading device (LS) to the computer modules (M1 to M9) for which they are intended, and in doing so the first (CP) and the second part (SP) via different communication paths P1 'to P3', P1 to P3) of the communication network (KN) are sent to the corresponding computer module (M1 to M9), and that the two parts (CP , SP) can be reassembled and saved in the respective computer module (M1 to M9). 2. The method according to claim 1, characterized in that from Data records that a set (SET1 to SET3) of computer modules (M1 to M9) are assigned, a group of data records is formed. 3. The method according to claim 2, characterized in that the Sets (SET1 to SET3) of computer modules (M1 to M9) accordingly the structure of the communication network (KN).   4. The method according to claim 1, characterized in that the Groups of records according to the degree of their match be formed. 5. The method according to claim 1, characterized in that the first part (CP) of a group of records about Broadcast communication paths (P1 'to P3') simultaneously to the Computer modules (M1 to M3) is sent for the records the group of records are determined. 6. The method according to claim 1, characterized in that the second part (SP) of a data record in the loading device (LS) is compressed, in the compressed state to the computer module (M1 to M9), for which it is intended, is sent and in Computer module (M1 to M9) is decompressed again. 7. Charging device (LS) for a multi-computer system for loading one Large number of data records in one communication network (KN) Variety of computer modules (M1 to M9), the charger (LS) with an interface to the communication network (KN), with a transmission device (SEND) and with a storage device (MEM) is provided for storing the data records, thereby characterized in that the charging device (LS) with a disassembly device (PART) is provided that the Cutting device (PART) is designed so that it records in the first parts (CP) common to a group of data records and second, special parts (SP) and that the Sending device (SEND) is designed so that it each first (CP) and the second part (SP) of a data record Different communication channels (P1 'to P3', P1 to P3) of the Communication network (KN) to the corresponding computer module (M1 up to M9).   8. Computer module (M1 to M9) for a multi-computer system, with one Interface to a communication network (KN), with a Receiving device (REC1 + REC2) for receiving data via the Communication network (KN), with a storage device (MEM2) and with a control device (CONTR2), which is designed such that they respond to a control command according to one in the storage device (MEM2) stored data set functions, characterized in that the computer module (M1 to M9) is provided with a joining device (COMB), that the receiving device (REC1 + REC2) is designed such that they parts (CP, SP) of a data set that are from a Charging device (LS) sent to the computer module (M1 to M9) have been forwarded to the combining device (COMB) and that the assembly device (COMB) is designed in such a way that they received two from the receiving device (REC1 + REC2) Parts (CP, SP) of a data record back to the data record merges and the data record in the memory device MEM2 saves. 9. Multi-computer system with a large number of computer modules (M1 to M9), with a charger (LS) for charging a variety of data records in a variety of computer modules (M1 to M9) and with a communication network (KN) via which the computer modules (M1 to M9) and the charging device (LS) connected to each other are, the charging device (LS) with an interface to Communication network (KN), with a transmitter (SEND) and with a memory device (MEM1) for storing the data records is provided, characterized in that the loading device (LS) with a dismantling device (PART) is provided that the cutting device (PART) designed so is that they have records in first, for each group of Common parts (CP) and second, special parts (SP) records divides, and that the transmitter (SEND) is designed so  that they each have the first (CP) and the second part (SP) Data record via different communication channels (P1 ′ to P3 ′, P1 to P3) of the communication network (KN) to the corresponding one Computer module (M1 to M9) sends. 10. Multi-computer system according to claim 5, characterized in that the communication network (KN) from a first subnetwork (SN) a central placement procedure and at least a second one Subnetwork (BUS) with a distributed switching process exists. 11. Switching system with a large number of computer modules (M1 to M9) for performing switching functions, with a charger (LS) for charging a variety of Data records in a variety of computer modules (M1 to M9) and with a communication network (KN), via which the computer modules (M1 to M9) and the charging device (LS) are connected to each other, wherein the charging device (LS) with an interface to Communication network (KN), with a transmitter (SEND) and with a memory device (MEM1) for storing the data records is provided, characterized in that the loading device (LS) with a dismantling device (PART) is provided that the cutting device (PART) designed so is that they have records in first, for each group of Common parts (CP) and second, special parts (SP) records divides, and that the transmitter (SEND) is designed so that they each have the first (CP) and the second part (SP) Data record via different communication channels (P1 ′ to P3 ′, P1 to P3) of the communication network (KN) to the corresponding one Computer module (M1 to M9) sends. 12. Switching system according to claim 10, characterized in that that computer modules (M1 to M3) an exchange of the Switching system with each other via a communication bus (BUS) are connected, and that these computer modules (M1 to M3) so are designed to be the first part (CP) of a data record received via this communication bus (BUS).