DE2644188B2 - Multi-user, multi-processor system - Google Patents

Description

The present invention relates to a multi-user multi-processor system with a plurality of work processors each comprising a central unit and memory and several independent data stations which communicate with them and which are connected to the work processors via a data rail step,

Computer network systems in which several computers work together are already known. It is also known known to connect a number of data stations to a central computer, in particular in the Tirne-sharing operation in »Dialogue traffic. The one here for

ι ° Application dialogue systems are complex and confusing.

A multi-user, multi-processor system with the features cited above is disclosed in US patent specification 36 34 830 already known The entire control system including the choice of worker processors is done here by a central computer. There is a significant disadvantage of the known system furthermore in the fact that each data station only has its own stored in the corresponding disk storage

Program is available

From NTZ 28 (1975) No. 6, pages K 2i4 to K. 218 is a remote data processing system consisting of a central data processing system with large storage data transmission control elements and several data stations known functions whose data stations include microprocessors.

From DE-OS 2f 15 993 a data processing system is known in which a set of instructions Data transfers to and from peripheral units,

^{J0 of} a device unit and controls the memory. For this purpose, all peripheral units are connected to a single connecting transmission path. Furthermore, the system can be controlled by a peripheral unit during the data transmission genes that the control requests for this and after Completion of their operation returns to the device unit

The present invention is based on the object of a multi-level master processor system

specify that can be built up from microcomputers or microprocessors, in which the dialog system is decentralized and divided between several computers can be. The invention proposes to solve this problem

Multi-user multi-processor system of the type mentioned above, which is characterized in that the data stations comprise computers formed by microprocessors for controlling the dialog traffic and that the data stations the dialog functions

* 'including the requirement of the individual work processor functions and the data rail the selection which is assigned to worker processors

In contrast to a data processing system are the individual as Arbettsprozessoren or in the

Data stations did not use microcomputers or only exceptionally with peripheral devices equipped, do not have an operating system in the true sense of the word, but only a process control and can not addressed individually by the user and

programmed. The individual micro-computers therefore do not act as data processing systems Appearance and only together with the structure form a computer system. The control of the data flow the data rail takes over within the system. A

^M dialog system is broken down into several independent functions during implementation on the computer structure. The individual functions are carried out by the elements of the structure and the micro-computers

carried out.

Dialog computers are provided in each of the data stations, each of which has the pure dialog functions assigned to the system. In addition, according to a first embodiment of the invention individual functions can also be permanently assigned to the individual work processors

According to a second embodiment of the invention, the individual work processors are none assigned to fixed functions. Rather, they are available on a second data rail with program memories and in connection with data storage devices via a third data rail. If necessary, therefore, a free one Work processor can be assigned a function that is currently required.

To further explain the invention, reference is made to the following exemplary embodiments described with reference to the figures referenced.

F i g. 1 shows a block diagram of the first embodiment of the invention,

2 shows a block diagram of a second embodiment of the invention,

Figure 3 shows a block diagram of an alternative designed part of the embodiment according to FIG. 2,

4 shows a block diagram of the in Embodiment in FIG. I used data rail,

Fig. 5 shows a block diagram of one used in the embodiment of Figs Data rail,

F i g. 6 shows the circuit of the data rail according to FIG. 4 in detail,

7 shows the circuit of the data rail according to FIG. 5 in detail,

Fig. 8 shows a block diagram for explaining the practical use of a system according to FIG. 1.

In the embodiment of the invention according to pi g. 1 there is a series of data stations with dialog computers D \, D ₂ to D _K and associated display devices S ₁ , S ₂ to S _K via a data rail in connection with work processors Fu to F _71n . The dialog computers Du Di to Dk are assigned the pure dialog functions. Furthermore, _{fixed functions are assigned to the work processors F u} to F _11n , whereby two or more work processors can be provided for those functions that occur very frequently or that place very high demands on reliability such as B. the worker processors Fu and F \ j or the worker processors F _n , \ to F _11n .

The function of a system according to FIG. Described 1: the dialogue computer D ₁ is requested by dialogue computer D ₂ example, the function I, then passes the request to the function 1 to the data rail DNE The data rail DNE searches the service processor pair Fu and F] ₃ and then selects such a free working processor. B. Fu. If no work processor is free, a message is sent to the dialog computer D ₂ . If a free work processor is found, the identification of the dialog computer D ₂ is first stored in the work processor, then the work processor's program runs. During the expiry time, the data rail is free again for other data stations. After the program has run, the work processor, e.g. B. Fu, now in turn the data rail and as a return parameter first the identifier of the dialog computer D ₂ and then the result data of the program. The data rail delivers this data to you. waiting dialog computer D ₂ . With this system, the management of central data is very easy to solve. One or more dedicated work processors are connected to manage the data.

With this structure, new work processors can be added without the need for system hardware and System software become much more complicated. This means that critical functions can be doubled if necessary thereby increasing the reliability and the speed of the overall system.

ίο For each software function, one own work processor required

In the case of the in FIG. 2, on the other hand, the same work processor can perform different tasks. Here, too, there are a number of dialog computers D \, D ₂ to Dk with associated display devices S \, S ₂ to Sk via a data rail DNEi in connection with work processors Au Az to Ac . 1 the work processors in their memories permanently assigned ^r . ograms and contain the required data, standea in the embodiment according to FIG. 2 the work processors -4 |, A ₂ to A _n connected via a data rail DNE2 with program memories Pu P ₂ to Pj and via a data rail DNE3 with data memories DS ₁ , DS ₂ to DS _m , from which a program and the can take over required data in their memory.

In this system, if a dialog box gives an example

If D \ shows a request to the data rail DNE 1 for a function, the data rail DNE 1 searches for any free work processor among the work processors A \, A ₂ to A _n and transmits this in addition to the code of the requesting dialog computer

ti D \ the code number of the requested function. The first data rail is immediately free again for requests from other dialog computers. The work processor, for example A ₂ , now sends the request for the corresponding program to the data rail DNf 2

■ to function. These programs are stored in the program memories P), P ₂ to Pj. Is the desired program, for example, stored in the program memory P2, the program is transferred from the program memory Pi in the working processor A _2, and processed there After completion of the program, the data rail DNE \ is triggered again by the working CPU A ₂ and the results of the waiting Dialog computer D \ given. To start the loading process from the program memories P \, Pi to

To optimize w Pj in the memory of the work processors A \, Ai to A _n , the respectively loaded program is initially kept in the work processor. When requested by a dialog computer , the data rail ONEi does not only look for a free one

*>*> Work processor, also change whether a free work processor with the program desired by the dialog computer is available. If none of the free work processors contains the desired program, the program must be included in one of the free work processors.

w) processors are loaded.

The advantage of the system according to FIG. 2 is that the number of work processors is essential can be less than the number of programs required. In addition, in the event of failure of individual

^hl > work processors the overall system continues to work.

In the embodiment shown in Figure 2 there is access to the data in the data memories D5 |,

DSi to DS _n stored data directly by the work processors A \, Ai to A _n via the data rail DNEi. According to the embodiment of FIG. 3, however, this can also be done with the interposition of special database processors DPi, DPi to DP _P , to which the work processors A \, Ai to A _n have access via the data rail 3 and which in turn have access to the data memories DSu D & to DS via a data rail 4 _m

FIG. 4 shows the block diagram of a data rail, as it is used in particular in the embodiment according to FIG. In addition to the control and data lines, this data rail includes a logic for handling the data rail requirements DA L, a logic for address decoding of the source and target computer AD and a logic for the data transmission procedure DÜL. The data rail is connected to a number of computers R \ to R _n . The various computers R \ to R _m are all connected to the data rail in the same way, although very different functions can be assigned to them. Some of these computers will serve, for example, as work processors Fu to F _11n in FIG. 1, while a further part of the computers will be used as dialog computers Dj, Dj to Dk . According to the function assigned to them, the memories of the various computers contain the required dialog or work programs.

In Fig. 5 is the block diagram of the data rail 2 in FIG. 2 reproduced. The structure of the data rail 4 in FIG. 3 agrees with that of the data rails 2 and 3 in FIG. 2 completely match. Furthermore, the structure of the data rail 3 in FIG. 3 corresponds to the structure of the data rail 1 according to FIG. 4. The data rail 2 comprises a logic for handling the data rail request DAL, a data multiplexer and demultiplexer DM, an address decoding AD. a logic for memory module selection SMA and a logic for address calculation AR as well as data lines 1 and control lines 1 via which the data rail is connected to processors P, \ to Prm, this can be the work processors A \, Ai to A _n according to FIG . 2 or the data processors DP ₁ , DPi to DPp according to FIG. 3 act and control lines Z data lines 2 and address lines with which the data rail 2 is connected to the memory modules SM \ to SM _n .

F i g. 6 shows the complete circuit of a data rail according to FIG. The circuit includes one Multiplexer 1, a counter 2, two decoders 3 and 6, a monostable multivibrator 4, a register 5, an inverter 7, an AND element 8, three OR elements 9, 14 and 17, tristate AND element 10, 11, 12, 13, 15, 16, 18, 19 and 20, a delay element 27, input resistors 24, 25 and 26 at the inputs of the multiplexer 1. The The data rail shown here is connected to three microcomputers 21, 22, 23, corresponding to the computers 1 to m in FIG. 4. Of course, a significantly higher number of microcomputers can be used here !! are provided, which then require a correspondingly higher number of associated gates.

> Fig. 7 shows the complete circuit of a data rail according to FIG. 5. The circuit comprises one Multiplexer 1. the counters 32, 39, 40, two decoders 33 and 36, a monostable multivibrator 34, a register 35, an inverter 37, three AND gates 38, 4 (,

in 42, a NOR element 43, tristate AND elements 44, 45, 46, 47, three delay elements 48, 49, 50, input resistors 51, 52, 53 at the inputs of the multiplexer 31. The data rail shown is here connected to two microcomputers 54, 55, corresponding to the Computers P, \ to Prm in FIG. 5 and the memory modules 56, 57 corresponding to the memory modules SM ₁ to SM _n in FIG. 5. Of course, a significantly higher number of microcomputers and memory modules can be provided here, which then have a correspondingly higher number

2 (i need the number of associated links.

F i g. 8 serves to explain the practical use of a system according to FIG. 1. This system is intended serve here to control the fire brigade. in the

The example shows only one data station from the dialog computer D \ and the display device Si: of course, any further number of such data stafons can be connected to the data rail DNE 1. For the various functions are

provided in work processors, namely for the vehicle search the work processor Fi, for the location search the work processor F2, for the Wegsuchc the work processor Fj, for the documentation the work processor Ft and as a traffic computer the

)> Work processor F5. If the dialog computer Di is an inserter; reported, it is first checked by the location search computer F7 whether the location was entered correctly. At the same time, the area around the destination is examined and it is determined whether it is in the vicinity particularly endangered objects are located, e.g. B. Tank farm, etc. Depending on this location check is then the degree of use determined. It is then determined by the vehicle search computer Fi where the for appropriate degree of deployment required next

^ own vehicles can be made available. In addition, the route finder F3 determines the cheapest route from the place where the vehicles are available to the place of use. If these data are fixed, the traffic computer Fs

V) the traffic is switched in such a way that the emergency vehicles can get to the place of use unhindered. The documentation computer F «ensures at the same time that all operations are saved in connection with the other data. The result of the salaried Determinations are then output to the display device S ₁ via the dialog computer A.

In addition 5 sheets of drawings

Claims (8)

Patent claims: 1. Multi-user multi-processor system with several work processors each comprising a central unit and memory and several independent data stations operating in dialogue with these, which connect to the work processors via a data rail, characterized in that the data stations are computers formed by microprocessors (D \ .., DK) to control the dialog traffic and that the data stations include the dialog functions including the request of the individual work processor functions and the data rail (DNE) the selection of work processors (Fl ... Fn; A i ... An) is assigned Multi-user multi-processor system according to Claim 1, characterized in that individual functions are permanently assigned to the working pressors (Fi ... Fn) (Fig. 1). 3. Multi-user multi-processor system according to claim 1, characterized in that the work processors (Ai ... An) can be assigned different functions (F i g. 2). 4. Multi-user multi-processor system according to claim 3, characterized in that the individual work processors (Ai ... An) via a second data rail (DNE2) with the program memories (Pi ... Pj) and a third data rail (DSEJi) can be connected to a data memory (DS 1 ... DSm) (FIG. 2). 5. Multi-user multi-processor system according to claim 4, characterized in that the work processors (Ai ... An / via the third data rail (DNEd) with database processors (DP 1 ... DPn) can be connected, which in turn have a fourth data rail (DNEAt) each have access to one data memory (DS i ... DSm). 6. Multi-user multi-processor system according to claim 5, characterized in that the program memory (Pi ... Pj) and the data memory (DSi ... DSm) consist of individual memory modules. 7. Multi-user multi-processor system according to one or more of claims 1 to 6, characterized in that the first data rail (DNEi) has a logic (DAL) for handling the data transmission request, a logic (AD) for address coding of source and target computers, a logic (DÜL) for the data transmission procedure as well as control and data lines (Fig. 4). 8. Multi-user multi-processor system according to one or more of claims 1 to 7, characterized in that the second data rail (DNE2) has a logic (DAL) for handling the data request rails, a data multiplexer and demultiplexer (DM), a logic (AD ) for address coding, a logic (SMA) for the memory module selection and an Ixjgik (AR) for the address calculation.