DE2517630B2 - PARTIAL SETUP OF A DATA PROCESSING SYSTEM - Google Patents

Description

As is well known, it is advisable to interconnect data processing systems from building blocks.

Γι which are monolithically integrated semiconductor components which are manufactured in particular using MOS technology (see »Electronics 1974«, Pages 379 to 395, especially 3X8 and 389; DOS 2 235 430, 2 336333, 2247 704). Each building block

4 (i is found in a so-called chip that has a limited Number of single pole connections. During the operation of a data processing system Among other things, information has to be entered into one chip from several such chips. It he-

4) therefore gives itself the task of such information to be able to enter using as few connections as possible. It can then be one too severe limitation of the number of different functions that can be performed by the component in the chip

) () stone can be run, avoided. The more different types of functions such a module can perform, the more connections it has he usually has to show.

It is already known (see e.g. DOS

V) 2 336333), memory addresses via a conductor to supply different cells of a parallelizing shift register, each of which has an address in parallel passes on to an instruction memory, and also commands supplied by the instruction memory in each case serially

ίο to spend on the same conductor. An order occurs here inevitably after an address, since it is only called up by an address. Other Information that affects the facilities mentioned or other facilities is provided via the

hi in question head not transferred. For this will be further ladder exploited. Such technical limitations are given below Invention avoided.

in solving the above mentioned challenge a known sub-device of a data processing system is assumed (see DAS 2007216). This sub-facility includes at least one that can be used for internal operations Register in which a multi-bit register information is entered that represents the The operational sequence is also determined and the counting circuit belonging to the partial device according to the specifications further information received as a series of pulses can be changed. This subdivision is according to the invention characterized by the combination of the following features:

a) the further information is integrated on a semiconductor module when working together Subdevice with other subdevices integrated on semiconductor components occasionally delivered via a single-pole module connection;

b) the further information is converted by the counting circuit into register information, which has an effect via one of several output terminals of the operating register that are used as control terminals in the sub-device itself;

c) a reset input is provided through which an externally supplied reset signal the module can be relocated to the initial state for the operational sequence and also the implementation the incoming further information can be caused, so that during the absence of the reset signal the single-pole module connection can be used for the supply of control pulses that trigger further processes in the block.

Further developments of the invention are characterized in the subclaims.

The invention advantageously enables the delivery of various information about brought about a single single-pole block connection. The number of required for the block Connections are therefore kept within narrow limits. This also enables the chips to be used for the various components belonging to a data processing system, one uniform and one may have a small number of connections. This also removes the wiring between these Building blocks relieved. By switching operations within a block it can also be achieved that with the help of a series of pulses several different registers can be supplied with register contents.

In the course of a caused by the reset signal Implementation can e.g. B. a previously contained in the operating register register information is deleted and be replaced by a new register information or it can, for example, the original register information can be changed by an addition process or a subtraction process. Even though the number of block connections is kept small, several different Control the function of the module.

Exemplary embodiments of the invention are explained in more detail below.

Examples of building blocks according to the invention are shown in Figs. Fig. 1 shows a combination module, the input-output ports for peripheral units and a buffer memory. Fig. 2 shows a block that contains a program control unit of a data processing system. Both building blocks also contain at least one register and at least one counting circuit. An operating register can be used as a register be provided, the supplied by series of pulses Saves register information for switching the block to different modes of operation (see also DOS 2 245 284).

The combination module shown in FIG. 1 has the operating register MR and the counting circuit ZM. The counting circuit ZM converts the pulse series supplied via the single-pole module connection / 7 into the register information. The register information recorded in each case affects one of the control terminals a, b, c, d of the operating register MR and the identically labeled control terminals of other sub-devices of the combination module B connected there. Of this combination module, only those partial devices are shown here as far as is necessary for an understanding of the invention. These sub-facilities are part of each other! Connected via the busbar SS , which in turn is connected to the busbar DSl , which leads to other modules. Control information can be supplied via the address busbar AS. Reset signals can be supplied via the reset input R and passed on from there via the control terminal r to the control terminals of other sub-devices with the same name. The combination module has, among other things, the input / output ports Kl .. K4 as sub-devices, to which the peripheral devices / ¹ I ... / '4 are connected. In addition, the input / output gate K5 is also provided, via which the busbar SS can be connected to the busbar DS1 , which leads to other modules. The directions of transmission for the busbars are indicated by arrows. The combination module also contains the buffer memory QS, which has several memory cells and which is equipped with the input counter EZ and the output counter AZ , each of which serves as an address generator for memory cells. Modules with input-output gates are known per se (see Rockwell International Corporation MOS / LSI Parallel Processing System, Rev. May 1973, pages 2-13 to 2-17 and Data Sheet Parallel Processing System (PPS-4) Rev. I. , July 1974, pages 2-1,8-1 to X-3). It is also known to additionally equip such modules with a memory (see Electronics 1974, pages 379 to 395, in particular page 381). The input counter EZ belonging to the buffer memory determines the memory cell receiving an item of information and the output counter A Z each determining the memory cell emitting information, as is already known per se (see DOS 2362245, 2002369). The address decoders ÜE and DA are used to decode the memory cell addresses supplied by the counters. When switching over the module with the aid of the operating register MR , the counting of the counters EZ and / IZ is set in such a way that either only useful data for one memory cell are received or output from the buffer memory QS during the cooperation of the module B with another device, or that a useful data block that takes up several memory cells is received or output. To change the way they count, the counters EZ and AZ must be changed via their control terminals c and d.

schiilthar. When a user data block is recorded, the input counter EZ must accordingly be incremented over several payment points one after the other. The is delivered in each case !; To decode memory cell address so that the associated memory cell can be supplied with pending information. This is repeated until all of the useful data belonging to the useful data block are received one after the other during the same interconnection of two modules in a plurality of memory cells. The output of the useful data belonging to this useful data block is handled in a corresponding manner. namely also during the same interconnection of, for example, two modules. The buffer store QS is connected on the input side and on the output side to the busbar SS . The user data can therefore, if it is necessary in each case, for example. via the busbars / XVl and / XS2 connected to the busbar SS.

The presence of the control terminals <i and /) in the operating register MR indicates that further switchovers, not described in detail, are possible with the aid of the operating register. Via the reset input R , the module is put into its initial state for the operating sequence by an externally supplied reset signal. This reset input leads to the control terminal; how the input-output gates Kl ... KS and the counters EZ, AZ and the counting circuit ZM is connected. The input-output gates Kl ... KS are therefore put into their idle state by a reset signal. Furthermore, the counters EZ and AZ can be brought into their initial counting position. Since the reset signal also acts on the counting circuit ZM , this signal can also cause the series of pulses arriving via the single-pole module connection H to be converted into the register information that is to be recorded by the operating register MR . The decoder /) (", which has the control terminals 1. 2 ... r , is connected to the busbar .4.SVUr via the control terminals 1, 2 ... /. B. affect the devotion output gates Kl.K2 ... and set these in a manner necessary for operation.

In the module C shown in FIG. 2 with a program control unit of a data processing system, the operating register SR is provided for which the series of pulses supplied via the single-pole module connection H are converted into the registration information by tier counting dialing ZS. The operating register .S7 \ 'here belongs to the sequence control device ALS of the program control unit. Switching over block C can therefore either cause the program sequence to be stopped after each program command or only after each jump command, since such functions can be brought about by a sequence control device in a manner known per se. The next command execution can then be triggered by a special control pulse that is fed to the single-pole construction connection //. This control pulse is fed to the reset input R while there is no reset signal and therefore has a different effect than the series of pulses to be converted into register increments. As already described, this conversion is only initiated by the reset signal supplied to the reset input R. In this context, module C is operated in the same way as module B.

Module C has further sub-devices that are used as a program control unit for its operation. These include the information processing unit INW and the stack memory KER, to which the read / write register LSR and the address output device Al) R also belong. The stack memory itself is supplied with addresses from storage locations via the address decoder ADK. These addresses and the stack to be stored and other information found there through the bus line DB, which internal to the module (belonging manifold ZZ is connected. From the stack supplied addresses are output via the line AB and z. B. a read only memory for The process control device ALS can also be supplied with control information from the outside via the bus line SB and information can also be sent to the outside via this bus line from the process control device ALS . Further registers are connected to the inner bus line ZZ, namely the The command counter register HER of the sequence control device ALS, the general register REG and the accumulator AKKV , which receives the program instruction first to be executed can. In the case of the various bus lines and other lines, the directions in which information can be transmitted are indicated by arrows. Only the most important parts of the program are shown here.

The invention has an effect here in particular on the various registers. In this context, by switching over the module (with the help of the operating register SR also the output of register information, in particular the accumulator contents.) To an external device, e.g. a display device, can be initiated inner collecting line ZZ and the collecting line connected to the outside leading I) B.

While it is already known, achieving interoperability gen to a Programmlcitwerk belonging register with Zählschaltun (see Intel MCS-4 microcomputer SET Users Manual, March l ^l '72. Rev. page 2 K)). The associated /, cooling circuits are not used there to convert incoming pulse series into controller information. I vine counting circuit can be assigned individually to one register, or it can also belong to several registers. 2, the general register RE (I and the accumulator / \ KK (i each have their own /, counting circuit, namely the counting circuits ZR and Z / l. The counting circuit ZS , on the other hand, is the operating register SR and jointly assigned to the document counter register AT! tier ablation control device /1/..V

net. Incoming pulse series for all of these registers can be converted into register information with the help of one of these counting circuits. The distribution device M, which is controlled by the sequence control device ALS as a function of control information, serves to distribute incoming series of pulses to be implemented to the counting circuit in question. The single-pole module H can also be supplied with pulse series, which are to be converted in the register information, from an external device, in particular from an operating device.

The technique described above, via a

to feed information to a single single-pole module connection with the help of pulse series, can also be used in a corresponding modification to provide information about a unipolar To transfer the block connection from the block to other blocks. It can be in particular also deal with register information to be delivered. In this case the block also has a block connection provided for this purpose. Here you can also use the existing Counter circuits analogously to the implementation of register information consisting of several bits can be used in series of impulses.

For this purpose, 1 sheet of drawings

Claims (7)

Patent claims: 1. Partial setup of a data processing system, to which at least one register that can be used for internal operations belongs, in which a register information consisting of several bits is entered, which co-determines the operating sequence and which is sent by a to the sub-device associated counting circuit based on further information received as a series of pulses is changeable, characterized by the Combination of the following features: a) the further information is delivered, in some cases, via a single-pole module connection (H) when the partial device integrated on a semiconductor module (Ii) cooperates with other partial devices integrated on semiconductor modules (C); b) the further information is converted by the counting circuit (ZiVf) into register information, which has an effect itself via one of several output terminals of the operating register (MR) used as control terminals (a, b, c, d ) in the sub-device (component ß) ; c) a reset input (R) is provided, via which block B can be set to the initial state for the operating sequence by an externally supplied reset signal and the conversion of the additional information received can also be initiated, so that the single-pole block connection can be made while the reset signal is missing ( H) can be used to supply control pulses that trigger other processes in module ( B). 2. Sub-device according to claim 1, characterized in that it contains as a combination module ( B) input-output gates (Kl ... K4) for peripheral units and a buffer memory (QS) which has several memory cells and which is connected to an input counter ( EZ) and an output counter ( AZ) , each of which serves as an address generator for memory cells, and that when switching over the module (B) the counting of the counters ( EZ, AZ) is set so that the buffer memory (QS) during the cooperation of the module (ß) with another device either only useful data for one memory cell are received or released or that a useful data block that takes up several memory cells is recorded or released. 3. Sub-device according to claim 2, which contains a program control unit of the data processing system, characterized in that by switching the module (C) either a stop of the program run after each program command or est after each jump command can be initiated, and that the next command execution by a special control pulse is initiated, which is fed to the single-pole module connection (H). 4. Part device according to claim 3, characterized in that by switching the Module (C) also outputs register information, in particular the contents of the accumulator, to another, in particular an external, device. 5. Partial device according to one of the preceding claims, characterized in that the module includes an instruction counter register (BFR) into which register information can be entered with the aid of a series of pulses which determines the program instruction to be executed first. 6. Partial device according to one of claims 1 or 3 to 5, characterized in that the module (C) includes an accumulator (AKKU) for receiving data processing results, which also receives register information supplied by series of pulses. 7. Partial device according to one of the preceding claims, characterized in that their respective single-pole module connection (H) pulse series can also be supplied from an external device, in particular an operating device. S. part device according to one of the preceding claims, characterized in that it has a single-pole module connection via the register information in the form of a series of pulses to be delivered to other modules.