DE2756266A1 - Programmed digital computer system - has three data buses each comprising several data memory circuits, one for each digit in computer - Google Patents

Abstract

The buses(3, 6, 7) transfer operands, instructions, intermediate and final results between respective inputs and outputs of a data memory(9) for storing data for the period of executing one instruction. It also has a program memory(1), a control unit(8), a control register unit(10), a computing unit(11), a data shifter(12), a masking unit(13) a data address unit(14), a data receive and transfer unit(15) and a instruction address unit(16) which generates the address of the next micro instruction. A control data memory(18) is connected to the other units and a data analysis bus(30). Pref. this increases the operation speed of the system and reduces the amount of hardware.

Description

description

The invention relates to information processing systems and relates in particular to program-controlled number calculators.

It can be used successfully in universal computers, control devices for Production execution and real objects are exploited.

The middle class number calculators need a whole range of requirements. With small dimensions and simple circuits must they have a low energy requirement, high operational reliability and flexible functional options have and work quickly.

In addition, the new machines must face a large amount the currently collected complex software have a possibility that Effectively emulate command systems of legacy machines The problem persists currently in the process of developing such a structure for calculating machines, the it Permitted equipment of the same type with different To achieve command systems by substituting the microprogram memory, with keeping the effectiveness of the machine at a high level and the universal Command systems faster than those based on traditional structures Machines of the same class must be run.

They are number calculating machines (see C. Hasson ~ microprogram control ", Issue 2, Moscow, 1974, 5. 144 to 222, System / 360 Model 513 - Comprehensive Introduction, Field Engineering Manual, Form X23 - 2821-0; System / 360 Model 50 - Functional Units, Field Engineering Manual, Form Y22-2822-1) known that a storage device for program information storage, whose information input to a data line connected to the transmission of to be stored during processing and operands, instructions, intermediate and final results to be shifted are provided is a unit of control registers for storing commands and program status words, whose control input is connected to the Ause, ang the control unit, whose input is connected to the output of a storage unit for the control information whose address input is the address of the next microinstruction and the electrical is coupled to the output of the unit of the control register, included. The machine also includes a Computing unit, the information output of which is sent to the Data line is connected to which also the information input and output a data recording and transmission unit is connected, a data address unit whose Electrical information input with the information output of the control register unit and whose control input is connected to the output of the control unit also the control inputs of the memory device for program information storage, the data acquisition and transmission unit and the computing unit are connected. The other control input of the arithmetic unit is connected to the other output of the memory unit connected for the control information, which is also connected to the address input of the memory device is switched to program information storage.

In the known calculating machine, the transmission paths for the Information in their processing is fixed and have a very limited Number of variants.

In arithmetic processing, an operand becomes an input the arithmetic unit (the summator), the other operand its other input and the calculation result is fed to the output line (rail of the summator8). The information shift takes place during the transmission of information via the said shifting circuit of the summator, shifting the information to the left or right in Word length allowed by only one or four places. the any other shifts must be carried out several times Shift types are realized. The direction of shift and the number of digits, which is shifted are determined by specific micro-instructions. To expand the format of the information to be moved up to a double word exists e ..- a group of four overflow triggers that are used to maintain or from the outer left or outer right exit of the Sull.mator exiting places can be used. The overflow or leaked spots can be on at the positions of the output register released for the shifting of the next word be transmitted. The information is shifted from a double word format so for several phases.

The operands, commands, intermediate and final results are used in the known machine stored in a Lokaispeicher. The Lokaispeicher is in divided into several quadrants, one of which is used as working cells for storing Intermediate results, two others are used to store the program information. The information can be read from the local memory to one of two buffer registers and into local memory either from these registers or from flip-flops for the provisional Storage registered.

Only one data word can therefore be used for one work cycle of the local memory can be read out and registered. The mentioned peculiarity of the well-known machine slows down their speed.

The logical processing of the data in the known machine will taken over by a special unit for logical one-byte operations. The said Unit "is a limited number of functions and links to the registers and units of the machine in small format paths for recording processing information (word quarters). Hence the speed of the machine insufficient when performing certain class operations. Furthermore assumes the presence of separate equipment with special couplings, which is only used for part of the machine's working hours, the regularity the structure, deteriorates the reliability and complicates the control.

The disadvantage of the known machine is the presence of various Lines for data and address transmission, said lines being tight are specialized, i.e. they have different numbers of digits and peculiar couplings on. The use of one and the same line for the transmission of both data as well as from addresses is impossible because of the requirements of the transmission of the Data as well as addresses are satisfactory couplings of the mentioned Lines are missing. In the known machine, the data is transmitted between the units and circuits either by a full word of the usual basic format or in parts, for example in bytes or nibbles, the mentioned fractions Couplings are fixed.

In the structure of the known machine is the introduction of the mentioned fractional couplings are enforced, and they are only in the circuits and registers where this is extremely necessary. The control of such fractional transfers is made more difficult because the inclusion of corresponding, the fractional couplings realizing valves special micro-commands and consequently special control devices requires, which reduces the operational safety of the machine and complicates the control.

The presence of a perfectly definite limited number of fractional Coupling causes difficulties in information processing because of the aforementioned Couplings should only be provided for the most frequently occurring transmissions. The transmission of the data of any one of those provided by the circuit Cases of a different format is all the more impossible because the known machines are unsuitable for use in the form of information processing systems with universal Application because of the substitution of the command system or the processing algorithms the The absence of any fractional couplings in the apparatus is immediately noticeable power.

The number of couplings of the full format between the units the known machine is also limited and by the processing algorithms conditional. As a result, data is often transmitted via a register chain in stages and in a detour, which makes the processing speed essential reduced and a universality prevented. In the known machine mentioned is the logical data processing in a logical byte processing unit summarized. As a result, the task of conservation that is often encountered falls apart a part of the calculation result of parts of two operands in stages of one separate maintenance of the operand parts in the unit for logical one-byte operations: The Stage of preservation of the actual result and the stage of preservation of a Part of the result. The ability to perform logical processing while the information transfer is in the known machine (except for the displacement ~ not provided, which significantly reduces their performance.

The known machine also has the disadvantage that it is impossible is, the local memory at the same time two or more operands after two or more To take addresses and to send the calculation result to a third address.

An essential defect of the known machine is that as a result a close specialization of their circuits and units and the inhomogeneity the couplings between them building a machine with large integrated Circuits is difficult. The known machine also has a disadvantage The fact that there is a comprehensive control of the data transmission paths between It is necessary for the units to have their own control device for each coupling to have. But since the couplings are individual and peculiar, so is the control device of different types. As a result, the control device's share is in the total volume the apparatus of the machine increased. The large volume of the control device increased in turn, the probability of failure.

The aim of the invention is to increase the speed of the number calculator to increase.

The invention is based on the object of a numerical calculating machine to create that has such units and couplings between them that allow to increase the regularity of the structure, its speed and to simplify the controls.

The problem posed is achieved in that in a number calculator, the one program information storage device whose information input a data line is connected, which is used for transmission from at operands to be saved and moved during processing, commands, intermediate and final results is provided a unit of control registers for storage of commands and a program status word, their control input to the output a control unit is connected, the input of which is connected to the output of a memory unit for the control information, at whose address input the address of the next microinstruction arrives and electrically connected to the output of the unit of the Control register is coupled, a computing unit whose information output to the Data line is connected to which the information input and output of a Data acquisition and transmission unit is connected, a data address unit, whose information input is electrically connected to the information output of the unit Control register and its control input connected to the output of the control unit is to which the control inputs of the storage device for program information storage, the data acquisition and transmission unit and the computing unit are connected, its other control input to the other output of the storage unit for the control information is connected, which is also connected to the address input of the memory device for program information i ons storage is switched, contains, according to the invention are provided: two additional data lines, a memory device for data storage for the Execution time of a command, its information inputs and outputs are connected to the main data line and to the additional data lines, a device for data shifting, one of which is information input to the main data line and their other information inputs and outputs to the additional data lines are connected, a masking unit intended for applying a mask to the data, their information outputs to the main data line and to the additional data lines are connected, a formation unit for the address of the next ldicro instruction, whose input for the start address at the output of the unit of the cost register, Output to the address input of the memory unit for the control information and Address input connected to the output of the storage unit for the control information which is connected to the address input of the program information storage device and to which the information input of the masking unit and the address input the storage device for data storage for the execution time of a command, an analysis line for the transmission of information about the status of the storage device for data storage for the execution time of an instruction, the program information storage device, the unit of the control register, the arithmetic unit, the device for data management shift and the formation unit for the address of the next Microinstruction in response to a request from the formation unit for the address of the next microinstruction are connected to which the Arxalysenausgän @; e der Storage device for data storage for the execution time of a command, the program information storage means, the unit of control registers, the Arithmetic unit, the device for data shifting as well as the analysis input and -output of the formation unit connected for the address of the next microinstruction are, whereby information outputs of the program information storage device are also connected to the additional data lines, Information inputs and outputs of the control register unit, information inputs the computing unit, information outputs of the storage unit for the control information, Information inputs and outputs of the data acquisition and transmission unit, information and outputs of the data address unit, the information output to the main data line the storage unit for the control information, the other information input and output of the data address unit and the control inputs at the output of the control unit the masking unit, the formation unit for the address of the next microinstruction, the storage device for storing data for the execution time of an instruction and the unit for data movement are connected.

The main data line and the additional data lines expediently contain in each place a data storage circuit for the execution time at least one Microinstruction.

The data storage circuit preferably contains the current execution time at least one microinstruction, at the output of which a signal for the transmission of masked and unmasked data is formed, at least one section of the main data line or the additional data lines for each point for data transmission in two-way traffic, a logical AND-NOT element for the transmission of masked data, one of which as The input of the data storage circuit serves as an input to the corresponding information output ler masking unit whose other inputs according to the number of sections of the data line are connected to the corresponding section of the data line and their output serves as the output of the data storage circuit, logical AND -NOT elements with each two inputs according to the number of sections of the data line, one input masked at the output of the logical AND-NOT element for transmission Data connected, the other occurring as an input of the data storage circuit Input with the corresponding information output of the storage unit for the control information is electrically connected and its output to the input of the logical AND -NOT-member for transmission masked data is connected, a logical AND-NOT element for the transmission of non-masked Data whose inputs according to the number of sections of the data line to the corresponding Section of the data line are connected and its output as the output of the Data storage circuit is used, an additional logical AND-NOT gate with two Inputs, one of which is used as the input of the data storage circuit with the corresponding information output of the storage unit for the control information electrically connected, the other input to the output of the logical AND-NOT gate for the transmission of unmasked data and its output to one of the sections the data line is connected, and a circuit to restore the L potentials of the sections of the data line, which is electrically connected to them coupled and connected to an L potential source and an O potential source is.

The calculating machine preferably contains a unit for converting numbers from one computing system to the other, whose information inputs to the main and to the first additional data line, its information output to the other additional data line Data line and its control input connected to the output of the control unit are.

It is advantageous that the device for data shifting has two data shift registers, their information input and outputs as information inputs and outputs of the device are used to move data, while the information input and output of the first of them to the additional data lines and the information 8 input and output of the second register to one of the additional data lines and others, also serving as information input to the device for data movement Information input connected to the main data line, a register for the next following quotient number whose information output is that of the additional data lines is connected to which the first data shift register is switched, has two control units for data shifting, in which the Control output of the first of them to the control input of the register for the next one Quotient number is connected, their analysis output as the analysis output of the The device is used to move data, its information input to the main data line, its other two inputs and outputs connected to the two data shift registers while the output of the second control unit to the second data shift register connected, the information inputs of the register for the next following Quotient digits serve as inputs of the device for data shifting and on the computing unit and the storage unit for the control information are connected are while the Control inputs of the two data shift registers, of the control units and the other control input of the register for the next one Quotient number are interconnected and as a control input of the device for Serving data movement.

The masking unit preferably contains at least two mask memory registers, whose information inputs are interconnected and as information input of the Masking unit are used, and a changeover switch whose two inputs to the outputs of the two mask storage registers, the third input of which is connected to the interconnected Inputs of the mask storage register are connected and its outputs as information outputs serve the masking unit, the control inputs of the two mask memory registers and the switch are combined and serve as a control input of the masking unit.

The computing machine preferably contains a diagnostic unit for Isolation of disturbances, their information input and output to the main data line, its control input and output to the control unit, its address input to the Output of the formation unit for the address of the next microinstruction whose Lock input connected to that output of the control register unit is that of the input for the start address of the formation unit for the address of the next microinstruction is switched to the control input of the diagnostic unit, the main and additional data lines and the control output qnge of the device for data shifting, the arithmetic unit, the unit of the control registers, the program information storage means, the storage means for data storage for the execution time of an instruction, the storage unit for the control information, the formation unit for the address of the next microinstruction, the unit for Data acquisition and transmission, the unit for a data address and the masking unit are connected, the output of the diagnostic unit as the output of the computing machine and its address output to the address input of the forming unit for the address of the next microinstruction and to the address input of the unit for a data address is connected.

The memory device preferably contains data storage a data storage unit with information input for the execution time of an instruction and outputs according to the number of main and additional data lines, their each is connected to the corresponding data line, three changeover switches for commutation an address for data recording from the corresponding data line, whose Outputs connected to the corresponding inputs of the data storage unit are, three changeover switches for commutation an address for the data output to the corresponding data line, whose outputs also to the corresponding Inputs of the data storage unit are connected, a counter unit for changing addresses the data storage unit, the output of which is connected to the input of each switch holder is, and a control information register whose information output to the control inputs of each of the changeover switches, whose control input is connected to the control input of the counter unit is connected and as a control input of the memory device for data storage is used for the execution time of a command, the information inputs of the Control information register and the counter unit are connected and as an address input the storage device for storing data for the execution time of an instruction serve, while the other input of each changeover switch also serves as an address input the entire storage device for data storage for the execution time of a Serves command.

The (present) invention allows the regularity of the To increase the structure of the number calculator and its speed. The invention allows to simplify the control of the number calculator, the equipment to reduce and to increase the operational reliability of the number calculator.

Based on the embodiments shown in the drawing the invention explained in more detail. The figures show: FIG. 1 a functional diagram of the inventive Numeric calculator; Fig. 2 shows a data storage circuit according to the invention for Execution time of at least one microinstruction; Fig. 3 is a working diagram of the invention Data storage circuit; Fig. 4 is a functional diagram of the invention Device for moving data; Fig. 5 is a functional diagram of the invention Mask unit; 6 shows a functional circuit diagram of the memory device according to the invention for data storage for the execution time of an instruction, and FIG. 7 shows a structure diagram the data storage unit according to the invention of the storage device for data storage for the execution time of a command.

The numeric calculator includes program information storage means 1 (Fig. 1), its information input 2 to a data line 3 and its information outputs 4 and 5 are connected to data lines 6 and 7, respectively.

The machine also has a control unit 8, the outputs of which at the control inputs of a memory device 9 for data storage for or during the execution time of an instruction, the storage device 1, a unit 10 of control registers, a computing unit 11, a device 12 for data shifting, a masking unit 13, a data address unit 14, a data recording and transmission unit 15 and a formation unit 16 for the address of the next microinstruction connected are. The input of the control unit 8 is connected to the output 17 of a memory unit 18 for the control information, the other output of which is connected to address inputs 19, 20 and 21 of the memory device 9 for data storage, the memory device 1 and the formation unit 16 for the address of the next microinstruction, to a other control input 22 of the arithmetic unit 11 and to an information input 23 the masking unit 13 and its information outputs 24, 25 and 26 respectively to the Data lines 3, 6 and 7 are coupled. The address input 27 of the memory unit 18 is connected to the output of the formation unit 16 for the address whose Input 28 for the start address at the output of the unit 10 of the control register and the analysis input and output 29 of which are connected to an analysis line 30. The analysis outputs 31, 32, 33, 34 and 35 are also connected to the analysis line 30 Storage device 9 for data storage, the storage device 1, the unit 10 of the tax registers, of the arithmetic unit 11 bz #. '. the facility 12 connected for data movement. Information inputs are to be made on data lines 3, 6 and 7 and outputs 36 of the memory device 9 for data storage for the execution time of a command, information inputs and outputs 37 of the data recording and transmission unit 15, information inputs and outputs 38 of the data address unit 14 and information outputs 39 of the masking unit 13 is connected. Information inputs are to be found on data lines 6 and 7 and outputs 40 of the unit 10 of the control registers, information inputs and outputs 41 of the device 12 for data shifting and information inputs 42 of the computing unit 11 connected. The information output 43 of the arithmetic unit is connected to the data line 3 11 and the information input 44 of the device 12 for data shifting connected.

The input of the unit serves as input 45 of the number calculator 15 for data acquisition and transmission, the input of which serves as the input 46 Data address unit. The output serves as output 47 of the number calculator the data recording and transmission unit and as its other output 48 of the Output of the data address unit.

The data lines 3, 6, 7 each contain a circuit in each position a data storage during the execution time of at least one microinstruction. This data storage circuit for the execution time at least a microinstruction, at the output of which a signal for the transmission of masked and unmasked data is formed, has at least one for each position Section of one of the data lines for data transmission in two-way traffic. The below The variant of a data storage circuit shown is similar for each of the data lines 3, 6 and 7.

The circuit includes a section 49 (Fig. 2) of one of the foregoing Data lines to which the input 50 of a logical AND-NOT element 51 for transmission masked data is connected, the input 52 of which is used as an input of the data storage circuit acts and is coupled to the corresponding output 39 of the masking unit 13 (FIG. 1) is. The other inputs 53 (FIG. 2) and 54 of the logical AND-NOT element 51 are connected to other sections 55 and 56 of the same data line. Of the Output 57 of the logical AND-NOT gate 51 serves as the output of the data storage circuit and is connected to the inputs of logical AND-NOT elements with two inputs after the Number of sections of the data line, in the variant described, to the inputs 58 of the logical AND-NOT elements 59, 60 and 61 with two inputs are connected. The other input 62 of the logical AND-NicHT gates 59, 60 and 61 serves as the other Input of the data storage circuit and is electrical with the corresponding output the storage unit 18 for the Tax infoxination coupled while the outputs of the logical AND-NOT elements 59, 60 and 61 to the corresponding inputs 50, 53 and 54 of the logical AND-NOT {; song 51 are connected.

The sections 49, 55 and 56 of the data line are each connected to the Inputs 63, 64 and 65 of a logical AND - NOT element 66 for the transmission of unmasked Data connected, and its output 67 acts as the output of the data storage circuit and is connected to the input 68 of an additional logical AND-NOT element 69 two inputs connected. The other input 70 of the logical AND-NOT gate 69 serves as the third input of the data storage circuit and is electrically connected to the corresponding output of the memory unit 18 for the control information. The output 71 of the logical AND-NOT4liedes 69 is to the section mentioned 49 coupled to the data line.

In turn, each of the sections 49, 55, 56 is the data line to a circuit 72 for restoring the L potential of these sections 49, 55, 56 connected, which is composed of resistors 73 and 74 and with one connection 75 to an L potential source 76 and with another connection 77 is coupled to an O-potential source, which is the logical earth of the number calculator occurs.

The number calculator also includes a unit 78 (Fig. 1) for Number conversion from one area system to the other, their first input of information to the data line 3, the other information input 79 to the data line 7, its output 80 to the data line 6, and its control input 81 to the output 8 of the control unit 8 is connected.

For a better understanding of the present numerical calculator are in Fig. 3 diagrams a, b, c, d, e, f, g shown, where on the abscissa axis the Time t is plotted in clocks and on the ordinate axis U in 0 and L levels. In Fig. 3a is a synchro series of the first half cycle of the work of the machine, in Fig. 3 b a synchro series of the second half cycle of the work of the machine, in 3c shows a signal for restoring the L potential of the sections of the data line, in FIG. 3d a change in potential at a section of the data line during readout a 0, in Fig. 3e a change in potential at the other section of the data line when reading a 0, in Fig. 3 f a change in potential at the third section of the Data line when reading out a 0, in FIG. 3 g a write signal from the data line shown for the registers.

The device 12 (FIG. 4) for data shifting has according to the Invention a data shift register 82, the information inputs and outputs 83 and 84 as information and outputs of the facility 12 serve to shift data and are connected to data lines 6 and 7, respectively. The information input and output 85 of another is also connected to the data line 6 Data shift register 86 connected, while the information input 87 this register 86 is coupled to the data line 3. The information input and output 85 and the information input 87 of the register 86 also as Information inputs and outputs of the device 12 for data shifting. To the Data line 7 is the output 88 of a register 89 for the next following quotient digit connected, the information inputs 90 and 91 as additional inputs of the Device 12 are used and to the computing unit 11 and the storage unit 18 for the control information is connected. l.in oteueringang 92 of the register 89 for the next following quotient digit is at the control output 93 of a control unit 94 coupled to the data shift, the analysis input 95 as analysis output the device 12 for data shifting occurs and to the analysellleitux 30 (Fig. 1) is connected.

The information input 96 (FIG. 4) of the control unit 94 for data shifting is connected to data line 3, while the other inputs and outputs 97 and 98 are connected to data shift registers 82 and 86, respectively. The exit 99 of another control unit 100 for data shifting is on an input 101 of the data shift register 86 is connected. The control inputs 102 of the registers 86, 82 and 89 and the control units 94 and 100 for data shifting are via a control input 103 of the device 12 for data shifting with the Control unit 8 (Fig. 1) connected.

As mentioned earlier, the number calculator includes one with yours Information input 104 to the output of the storage unit 18 for the control information connected masking unit 13 (Fig. 5). Interconnected ones serve as information input 104 InfoImation inputs 105 and 106 as well as an input 107 connected to them Misk storage registers 108 and 109 and a changeover switch 110.

The other inputs 111 and 112 of the switch 110 are to the Outputs of registers 108 and 109, respectively, and its outputs serve as Information outputs 113, 114 and 115 of the masking unit and are each to the Data lines 3, 6 and 7 connected. The control inputs of registers 108 and 109 and the switch 110 are combined they form the control input 116 of the Masking unit 13 and are connected to the control unit 8 (FIG. 1).

The machine also includes a diagnostic unit 117 (Fig. 1) for Delimitation of disturbances via an information input and output 118 the data line 3 is coupled. The control input and output 119 of the diagnostic unit 117 is to the control unit 8, its address input 120 to the output of the formation unit 16 for the address of the next microinstruction, the disable input 121 to that one Output of the unit 10 of the control register connected to the input 28 of the Formation unit 16 for the address is connected to a control input 122 are control outputs 123 of the memory device 9 for data storage, the Storage device 1, the device 12 for data shifting, the unit 10 the control register, the arithmetic unit 11, the storage unit 18 for the control information, the formation unit 16 for the address of the next microinstruction, the unit 15 for data acquisition and transmission, the unit 14 for a data address, the Masking unit 13 and the data lines 3, 6, 7 connected, the output 124 the diagnostic unit 117 serves as the output of the numeric calculator, and the Address output 125 is connected to address inputs 126 and 127 of the unit 14 for the Data address and the formation unit 16 for the address of the next microinstruction connected.

The storage device 9 for data storage for the execution time an instruction contains according to the invention a data storage unit 128 (Fig. 6), their information inputs and outputs 36 are connected to the respective data lines 3, 6, 7 sind0 The storage device 9 also has changeover switches 129, 130 and 131 for commutation an address for data recording from the respective data line 3, 6 and 7, their outputs 132, 133 and 134 each to the write address inputs the memory unit 128 are connected, and switches 135, 136 and 137 for Commutation of an address for data output on the respective data line 3, 6 and 7, whose outputs 138, 139 and 140 are connected to the read address inputs of the memory unit 128 are connected. The address inputs 141 of the switches 129, 130, 131, 135, 136, 137 serve as address inputs of the memory device 9 for data storage and are connected to the output of the storage unit 18 for the control information. The other address inputs 142 of the aforementioned switches 129, 130, 131, 135, 136, 137 are at the output of the counter unit 143 for changing the address of the data storage unit 128 and the control inputs 144, 145, 146, 147, 148 and 149 of the switch 129, 135, 130, 136, 131 and 137 each to an information input 150 of a control information register 151 of the storage device 9 is connected. Information inputs 152 and 153 the unit 143 of the counters and the register 151 are each combined and serve than connected to the output of the storage unit 18 for the control information Address input 154 of the memory device 9 for data storage. The control input of the register 151 is connected to the control input of the unit 143 of the counter and serves as to the output of the control unit 8 (Fig. 1) connected Control input 155 of the memory device 9 for data storage.

Lie data storage unit 128 (Fig. 6) is based on a matrix carried out, which is composed of cells 156 (Fig. 7) of a homogeneous matrix structure whose information inputs and outputs 157 on location information lines 158 are connected. The write address inputs 159 of cells 156 are on digit lines 160 for write signals and the read address inputs 161 on digit lines 162 connected for read signals. The data storage unit 128 sees the presence of decipherers (not shown), which are operated by switches 129 (FIG. 6), 130, 131, 135, 136, 137 incoming addresses on lines 160 (Fig. 7) and 162 convert control signals fed to the matrix.

The numeric calculator operates according to the invention as follows.

The fastest and most versatile is such a calculating machine, each of which is in direct contact with all other units. In this case, the information is the fastest from one unit to another transmitted, and the couplings between the units are independent of each other and consequently versatile. Here, however, the control is in such machines much more complicated, and the large number of couplings leads to deterioration your operational safety.

However, at any given point in time, there is no need to information at the same time about all existing between the units of the machine Transfer connections. The number of information transfers at a time is limited and is determined by the algorithm of a corresponding processing. Take in most of the individually taken moments (steps) of processing usually three values participate: two operands (summands, factors, etc.) and a result (sum, product, etc.).

So it is necessary to have a limited number at any one time to have direct couplings between the units.

The numerical calculator according to the invention is most sufficient for the alternative requirements, direct couplings from each unit to each easy control and low number of couplings. The units and the facilities of the machine have inputs and outputs that connect to the data lines 3 (Fig. 1), 6 and 7 are connected. The data lines 3, 6 and 7 combine the Information inputs and outputs of the equipment and the units of the machine, realize an electrical adaptation of the inputs and outputs to be interconnected of the units and facilities and monitor the resulting information. All Data lines 3, 6 and 7 are identical and work independently of one another and have a number of digits corresponding to the basic format word. The information input and outputs of the equipment and units of the machine are designed in such a way that that they are by a Verdrchtung, for example in circuits with an open Collector output or on elements with a three-state output, can be united.

Since all inputs and outputs of the facilities and units of the Machine interconnected by the three independent data lines 3, 6 and 7 are, you can have three at any given point in time (work cycle of the machine) Establish direct information links between three groups of units. In the next point in time (in the next cycle) you can have three independent connections establish between other three groups of units between which the information transfer is determined by a data processing algorithm.

For each work cycle of the machine, the couplings between optimally adjusted to the units. The effect of a coupling of everyone arises the units with each other via the shortest coupling.

The number of lines is based on considerations of an optimal parallel connection chosen by data flows. As mentioned earlier, it is in the vast majority the work cycles of the machine necessary, three independent data flows - - for two operands and a calculation result - to organize. Necessary and sufficient is therefore the presence in the machine of the three independent data lines 3,6 and 7.

The versatility of the coupling of the units and facilities of the machine "each with each" remedies an essential deficiency of the known machines - the presence of special couplings. In practice, the adding machine does not lose any Performance in setting to any command system, in execution any algorithm.

Since data is also transmitted via lines 3, 6 and 7, control can be concentrated on one point, namely on these lines. This eliminates the need to have multiple control circuits after the number indi To have visual couplings between the units, as is the case with the known ones Machines is the case. The mentioned peculiarity of the number calculator has a reduction in the control device, a reduction in the number of couplings and result in an increase in their reliability. Major advantage of the Calculating machine's own coupling system is that any, an input from or an output on the lines owning unit as an element of an interconnected unit Units of composite memory field can be viewed, which allows to assign its own address to each unit, which is why the control of the machine, for example a microprogram control, is made considerably easier.

The content of several, for example, two registers entering a unit can be read out. The possibility mentioned allows a logical processing of one Register data read out from another register with the help of information, for example a Boolean AND function, i.e. an operand part secrete with the help of a mask. Such a possibility allows the fragile Exclude couplings between the units, thereby also controlling the Calculating machine is simplified. The presence of a mask to be transmitted However, data through any variable allows any fractional Carry out transfers, which in the with the help of circuit solutions fractional couplings carried out by the units is impossible.

Here, the masking information can be both a constant and also be a result of previous operations, i.e. processed in the machine or from the outside, for example by a similar machine.

The presence of the three lines 3, 6 and 7 allows the operations mentioned simultaneously and independently on different (or the same) data to execute. For example, the data line 6 becomes part of the first operand and the data line 7 Part of the second operand taken, while on the data line 3 the removal of part of it from the information output 43 of the arithmetic unit 11 and its loading into a the register of the memory device 1 for storing program information via their information in passage 2.

Since the units and facilities of the machine multiple with multiple Data lines coupled and independently controlled outputs and inputs it is possible to display the content of a register entering any unit can be read out on several lines at the same time and transmitted in several directions as well as information from several lines at the same time in a register to write several inputs, which allows logical processing to be carried out, for example an overlap operation, i.e. a Boolean OI) ER function, to execute.

By using the Boolean functions mentioned, you can to carry out a logical processing of information during its transmission, which significantly increases the performance of the calculating machine. Combined with the possibility of inversely acquiring the data on the line from the output of the units (i.e. to perform a Boolean NOT function), form the aforementioned logical Operations a functionally complete system of switching functions of the Boolean algebra.

The calculating machine processes the data according to one of the commands existing program. The address of the next command is in the unit 10 of the tax registers. In response to a signal from the control unit 8, the address of the the next command via one of the data lines 6 or 7 into the data address unit 14 and arrives via the outer output 48 of the machine in the (not indicated) Operational memory. The called command arrives from the operational memory via the external input 45 to the data acquisition and transmission unit 15 "from the data acquisition and transmission unit 15 is the command via its information outputs 37 and one of the lines 6 or 7 to the unit 10 of the control register via its information inputs 40 delivered where he was also in the course of running the whole, by the command specified operation is saved.

The calculating machine is controlled according to the microprogram principle. Each of the operations specified by the command is executed accordingly in execution cycles subdivided according to the selected execution algorithm. The state of all valve circuits of the machine is in the storage unit 18 for the control information with the aid of contained control words. Each control word (L'ikro command) describes the state of the valve actuation of the machine for one work cycle. By the Control words of the memory unit 18 rur ciie Tax information taken one after the other in a sequence determined by a processing algorithm and the individual control instructions (micro-commands) are decrypted the valve circuits open and locked, the processing data on the corresponding units and lines are transmitted. The start address of the Control word sequence (microprogram) is specified by the control register unit 10 and is numerically equal to an instruction code. The command code comes from the unit 10 of the control register to input 28 for the start address of the formation unit 16 for the address of the next microinstruction.

The latter forms the address of the introductory microinstruction of the microprogram to be processed and delivers it to the address input 27 of the memory unit 18 for the tax information. The first control information word selected from unit 18 arrives from the output 17 of the unit 18 at the control unit 8, where it decrypts and in the form of control signals in the unit 10 of the control register, the arithmetic unit 11, the unit 78 for converting numbers from one computing system to the other, the formation unit 16 for the address of the next microinstruction, the data acquisition and transmission unit 15, the data address unit 14, the masking unit 13, the storage device 9 for data storage for the execution time of an instruction, the program information storage device 1 and the device 12 to the Data movement arrives, thereby making the work; of the machine in the course of a work cycle is controlled. Part of the called microinstruction gives the address of the next one Microinstruction. The address of the next microinstruction comes from the memory unit 18 to the address input 21 of the formation unit 16 for the address that the Forced address of the next microinstruction and an address input 27 of the memory unit 18 provides for the control information, whereby the next microinstruction is addressed will.

In such a way, the microinstruction sequence is used to execute a through selected the command specified operation. The last microinstruction of the microprogram calls the next instruction from operational memory as described above has been.

When processing the microprogram, however, a situation can arise where the processing process is depending on the output data, intermediate results, Must change the state of the control register and similar conditions. In this case the call sequence for the microinstructions must be disturbed, i.e. the microprogram branches into several execution paths. To analyze the situations that have arisen the analysis line 30 is provided. If necessary, the state of this or those units of the machine (this information is contained in a microinstruction) to check, the formation unit 16 asks for the address of the next Microcommand via its analysis output 29 a unit or a group of units about the condition to be checked. The information about the state of the units reaches the formation unit 16 for the address via the analysis line 30 of the next microinstruction, which via its address input 21 from the memory unit 18 for the control information received address in accordance with one of the analysis line 30 obtained analysis changes. On the address input 27 of the unit 18 comes a modified address, whereby the call sequence for the Microinstructions and consequently the path of the operational sequence is changed. This or that analysis of the state of the unit or device of the machine is carried out by this Unit or device performed on a control signal from the control unit 8. The analysis results are transferred to analysis line 30 from the storage device 9 for data storage for the execution time of a command via its analysis output 31, from the program information storage device 1 via its analysis output 32, from the unit 10 of the control register via its analysis output 33, from the Computing unit 11 via its analysis output 34 and from the device 12 for data shifting via their analysis output 35. Each of the units and facilities mentioned is to all (not shown) control lines of the analysis line 30 connected, but provides the information for such a number of the lines that are used to transmit information about the status of this unit or Establishment is sufficient.

The formation unit 16 for the address of the next microinstruction can receive the analysis results taken over by the analysis line 30 and him use for address modification after several work cycles have elapsed. This allows it is to carry out a preliminary information analysis during the transmission.

The process of command execution consists of calculation stages of the Operand addresses, reading of operands from memory, processing of operands, Storage of the result and fixing of the result characteristic. Dependent on Depending on the type of command, this or that level can be omitted. The operands can resides in the program information storage device 1 in which (not shown) Operational memory are located and in an instruction in the form of a part of it (immediate Operand). The addresses of those located in the memory device 1 Operands are transferred to this device 1 via its information input during the command call 2 sent from the data recording and transmission unit 15 via the data line 3.

Let us consider a sequence of operations where the operands are in the Program information storage means 1 are, strictly speaking, an operation of addition (subtraction) for two numbers, the operation result is to be put in place of the first operand.

The operational code of addition (subtraction) comes from the unit 10 of the control register via input 28 for the start address in the formation unit 16 for the address of the next microinstruction. From the storage unit 18 for the Control information is based on an address supplied to its address input 27 a microinstruction for addition (subtraction) is read out and via its output 17 given to the control unit 8. The control unit 8 supplies the program information storage device 1 control signals, whereby a readout via its output 4 on the data line 6 of the first operand and via output 5 to data line 7 of the second Operand is controlled. The first and second operand # arrive via the information inputs 42 to the arithmetic unit 11. The control input 22 of the unit 11 is sent from the Storage unit 18 for the control information, a code of the function to be performed (in the present example of an addition or subtraction).

The arithmetic unit 11 executes the specified function and outputs the calculation result via its information output 43 to the data line 3. To reached this point in time from the control unit 8 to the program information storage means 1 a microinstruction for writing in the result. The result is saved in the storage device 1 is written in via its input 2 from the data line 3.

If one of the operands (or both operands) is in the operational memory, so its address usually consists of several components: index, base and Shift. Only the addresses of the registers are specified in the command where the indices and bases are stored while the shift is immediately given will. In this case, the operand address must be determined arithmetically. The investigation the address is also made as described above, with the program information storage means 1 the contents of their registers containing the bases and indices are taken and the Result in the memory device 9 for data storage for the execution time of a command via its information input connected to the data line 3 36 and sent to the unit 14 for a data address. From unit 14 for a data address, the operand address is sent via the external output 48 of the Calculating machine in the operational memory. The selected operand arrives via the input 45 of the calculating machine into the data acquisition and transmission unit 5. In the Performing the above operation becomes one of the operaids on the data line 6 from the memory device 1 and the other operand on the Data line 7 is read from the data recording and transmission unit 15. That The result is transferred to the memory device 1 via its input 2 from the data line 3 loaded into the arithmetic unit 11 after processing.

If the two operands are in the operational memory, the Calculation of the operational addresses and their removal from the operational memory one after the other performed while the operands, including the variable length, are stored in the storage device 9 can be brought to data storage for the execution time of an instruction. In in this case the output operands are transferred to the data lines during processing 6 and 7 are read out from the memory device 9 via its information outputs 36. The calculation result can be stored both in the memory device 9 and in the data recording and transfer unit I5 for subsequent loading of the operational memory via the output 47 of the calculating machine after an at the output 48 by the Unit 14 for a data address specified address are loaded.

In complicated data processing where the algorithm is in is processed in several stages, the intermediate results of the calculations are and the output operands from the operational memory in the storage device 9 for Data storage saved for the execution time of a command.

The memory device 9 has three to every three data lines 3, 6 and 7 connected and independently and simultaneously controlled information inputs and outputs 36. The register addresses of the memory device 9 appear the address input 19 of the memory device 9 from the memory unit 18 and the read and write micro-commands from the control unit 8. As a result, the Storage device 9 an operational exchange of information with any three Perform units of the machine at the same time.

In information processing, the have data moving operations a significant weight. They are both in the form of move commands as well in other operations, for example when adjusting orders of magnitude and normalization, in floating point operations, when the result is stored in the multiplication and division operations, exploited. To run Shift operations is the device 12 for data shifting in the machine intended.

The data to be shifted are entered in the device 12 for data shifting loaded from data lines 3, 6 and 7 via their information inputs 41 and 44, while the shift parameter, if known in advance, via the control input the device 12 is supplied by the control unit 8. If the move parameter is unknown in advance (as is the case with normalization or balancing chung of the order of magnitude is the case), it is calculated in the arithmetic unit 11 and from the data line 3 via the input 44 to the control units 94 (Fig. 4), 100 given to the device 12 for data shifting. The Eirrichtung 12 leads predefined number of shifts and delivers the result via the information outputs 41 (Fig.

1) to data lines 6 and 7 for further evaluation.

When transmitting the data via the data lines 3, 6 and 7 they are masked in order to isolate part of the information to be transmitted. The masks can be transferred from the storage unit 18 for the control information to the data line 3 via the information output 24, to the data line 6 via the information output 25 and to the data line 7 via its information output 26.

The Boolean AND functions for the data to be transmitted and the mask codes carried out. The separate data points are transferred to the units of the machine for further evaluation. The masks are also on the data lines 3, 6, 7 via the information outputs 39 of the Masking unit 14, where it is sent via its input 23 from the memory unit 18 for the control information can be loaded. But if the unit 18 over their Outputs 24 through 26 on lines 3, 6, 7 at the same time the mask only of any kind, so the masking unit 13 has by placing it on its registers several Mask types stores, one way of accessing the different Lines 3,6,7 simultaneously apply a mask of different types. The possibility, Masking the information to be transmitted allows the fractional connections avoiding between the units performs the operation of transferring a part of the information back to a microprogram procedure of the masking increases the Operational safety of the machine.

To explain how the machine works using In masks we consider the execution of an often occurring procedure - an enrollment in three different cells of the memory device 9 for data storage for the Execution time of an instruction of the sign, characteristic and mantissa of a operands arrived at the data acquisition and transmission unit 15 in equation it point.

The operand from the data acquisition and transmission unit 15 becomes via the information outputs 37 simultaneously for the three data lines 3, 6 and 7 called. At the same time for the same lines: for the data line 3 a mask for providing the sign from the masking unit 13 for which Data line 6 from the same unit 13, a mask for providing the characteristic and from the storage unit 18 for the control information via its output 26 for the data line 7 a mask for provision the mantissa called. The sign provided as well as the characteristic and mantissa will be into the memory device 9 for data storage for the execution time of a Command written into three different cells (not shown) via their inputs 36, their addresses by the storage unit 18 for the control information about the input 19 of the storage device 9 are specified. The said operations are simultaneous executed in the course of a work cycle of the calculating machine.

From the example given it can be seen that the presence (in the case of the units and devices of the calculating machine) of several with different Lines connected and independently controlled inputs and outputs as well as the presence a masking machine, the speed of the machine and the flexibility of its Significantly increase control.

When performing operations, there is a need for constants to use. A mask can be used as a constant if it is on in this There are currently no lines transmitting data.

In the data processing process, situations arise in which the information read out from any unit or device after a conversion must be written to the same address. If the information is not in the Time division method is read, processed and written, so can a distortion of the surgical result occur, To eliminate this effect the data lines 3, 6 and 7 contain a data storage circuit in each position for the execution time of at least one microinstruction.

The work cycle T (Fig. 3) of the machine is divided into two half cycles T / 2. In the first half cycle (Fig. 3a) the information is on any data line 3,6,7 (Fig. 1) read out. The storage elements of this line store the in they read in information and store it in the course of a predetermined period of time. In the second half cycle (Fig. 3b) the information is in the units and arrangements the calculating machine from the lines 3 (Fig. 1) 6.7 inscribed. Since the operation of reading out the information on the line is completed at the time of writing there is no change to the information on the line at the time of writing, i.e., there is no distortion of the operation result even in the case of writing into the register from which the information was read in the first half cycle is before. The mentioned special feature of the lines 3, 6 and 7 increases the stability the work of combinational circuits whose inputs to the lines, for example the computing unit 11 are connected.

It will now turn to the work of the data storage circuit for the Execution time of at least one Liikro command received. The circuit leads the following operation: Storage of unmasked data, masking an information coming into the circuit, storage of masked data and electrical Decoupling of units and facilities of the Machine. The electrical decoupling of the units is achieved by subdividing the Lines reached. A sufficiently long line has a distributed capacity that as a capacitive load for the output circuits for reading out the data on the lines provided units of the machine. Exceeds the line capacity a certain value for these circuits, the signal parameters deteriorate, what a limitation of the speed of information transmission over the lines and results in a deterioration in the stability of the work of the machine. In addition, each output of the circuits is for a particular output load factor designed, which limits the number of participants connected to the lines. To remedy the defects mentioned, the management is divided into sections (in this Variant there are three). To sections 49 (Fig. 2), 55 and 56 of the Line are the iAin and outputs of the units and facilities of the machine connected. The information arriving at any of the sections 49, 55, 56 must be spread over all other sections, but each of the sections has no galvanic coupling to the other sections what whose distributed capacity significantly reduced. In the initial state it is due to the sections 49, 55 and 56 have an L potential.

In the first stroke of the machine's work (Fig. 3d) the on the section 55 (Fig. 2) of the line via the input 63 of the AND-NOT gate 66 O information read out at a high level for the transmission of unmasked information to the input 68 of the logical AND-NOT4liedes 69 with two inputs other input 70 a high level (Fig. 3c) comes. At the output 71 of said AND-NOT gate (Fig. 2) forms a low level, the other Section 49 of this line and to the input 63 of the AND-NOT element 66 (Fig. 3e).

The feedback is closed and the AND-NOT gates 66 (Fig. 2) and 69 form a latch flip-flop.

The unmasked information is obtained from the output 67 of the AND-NOT element 66 on the control circuits to check the correctness of the information transmission (not shown) given. When the synchronous signal subsides (Fig. 3a), this coirms Reading out the information on section 55 (Fig. 2) of the line at the end, however, the information is still present at the other section 49 of the line and arrives to the input 50 of the logical AND-NOT gate 51 for the transmission of the masked Information. The O information from input 50 of AND-NOT element 51 occurs its output 57 with high Level up and reaches the inputs 58 of the logical UI4D - NICH £ 4 songs 59 to 61 with two inputs. On their other Inputs 62 are entered in the second half cycle of the work (Fig.

3b) given a high level, thereby preventing the passage of the information to the outputs of the AND-NOT gates 59 (Fig. 2), 60, 61 is enabled. the O information applies to all three line sections 49, 55, 56 (Fig. 3d, e, f) to Time of arrival of a write signal (Fig. 3g) at any unit the adding machine. When reading out the information on the lines in the first iial cycle (Fig. 3a) it is thus stored by the data storage circuit, and in the second Half-cycle (Fig. 3b) it spreads over all line sections.

The mode of operation of the data storage circuit is when it is applied to the Section 55 (Fig. 2) of a 0 potential described. When L arrives, it changes the state of the circuit does not change, because in the initial state it has an L-Infor mation saved.

The logical AND-NOT element 51 for the transmission of the masked information has an additional input 52, via which a mask arrives at it the supply of a zero mask (a 0 potential) at input 52 becomes the logical one AND-NOT element 51 at output 57 always has an L potential regardless of the potentials at its other inputs 50, 53 and 54, i.e. independent of the one on the management read out information. If on input 52 of the logical AND-NOT gate 51 an L mask is supplied, the line sections 49, 55 and 56 become one information read out from the units is supplied. This is how the isolation operation goes part of the information on lines 3 (Fig. 1) 6, 7, i.e. the masking operation, in front of you. The information and in the places where the mask had zeros become independent of the information supplied to the line fixed zeros.

The output 57 (Fig. 2) of the logical AND-NOT gate 51 for transmission The marked information is sent to the circuits of the machine at its inputs need to have the information earlier than in the second half measure of the work, for example connected to the inputs 42 (FIG. 1) of the arithmetic unit 11. this works the arithmetic unit 11 in inverse cord. The AND NOT VALID 51 (Fig. 2) forms together the AND-NOT gates 59, 60 and 61 a flip-flop, which the masked information at sections 49, 55, 56 of the line until the signal at the inputs has decayed 62 of the AND-NOT gates 59, 60 and 61 (the signal is indicated in Fig. 3b) is delayed.

After the end of the recording of information from the lines must their original state can be restored.

This is done by applying a 0 potential to input 70 (Fig. 2) of the AND-NOT element 69 is reached. That through the AND-NOT elements 66 and 69 The latch flip-flop formed opens, and the sections 49, 55 and 56 reach the L output potential. The voltage divider formed by resistors 73 and 74 containing circuit 72 for restoring potential of portions of the Data line speeds up the process of restoring L on the sections 49, 55, 56. The restore signal (Fig. 3c) is deactivated after the write signal (Fig. 3g) given.

The calculating machine can use the binary and decimal systems in the form of The numbers shown in binary decimal codes work.

For quick number conversion from one computing system to the other there is the unit 78 (Fig. 1) for number conversion in the structure of the machine from one computing system to the other.

The number is transferred to the data lines in the output number system 3 and 7 and comes via the inputs of the unit 78 for converting numbers into a corresponding conversion circuit (not shown). In response to a control signal from the control unit 8, which arrives at the input 81 of the unit 78 for number conversion, it delivers the result of the conversion to the data line via output 80 6. The result can be obtained in parts. In this case the bottom line will be from partial results in the device 12 for data shifting saved. Since the conversion process in the combination circuits of the unit 78 for number conversion in the general case the machine lasts more than one work cycle, a signal to restore L potential (Fig. 3c) not so many cycle times delivered as the conversion process takes. Retain lines 3 (Fig. 1) and 7 So the information in the course of the entire process of converting numbers from one dike system into the other.

The line direction 12 (FIG. 4) for data shifting performs a shifting operation over the double length words on the first shift register 82. The information are recorded in the first shift register 82 by the data lines 6 and 7. The shift takes place to the right and to the left, controlled by the first unit 94 for data shifting to which either a fixed shift parameter of the control unit 8 (FIG. 1) via the input 102 (FIG. 4) or a computation parameter is given by the data line 3. The first control unit 94 generates a control signal sequence according to the move parameter and controls the move process on the first shift register 82. In the case of a logical right or left shift leads the control unit 94 to move the data into the released positions of the Shift register 82 zeros and plants in an arithmetic right shift the Operand prefix continued. With an arithmetic left shift the control unit 94 monitors the overflow during the shift and signals this via output 95.

When performing a division operation, the shift register 82 the quotient is saved. The next quotient digit comes into the register 89 for the next following quotient digit either from the arithmetic unit 11 via the input 90 or from the storage unit 18 for the control information about the Input 91. In the next following cycle for quotient storage, the next following The quotient digit is read out from the register 89 onto the data line 7. Synchronous for this purpose, the already stored quotient is converted from the shift register 82 to the Data lines 6 and 7 read out with a shift, with on the data line 7 space is released for the next quotient digit. After that, the The information generated is entered again in the shift register 82. The storage cycle repeats itself until the entire quotient has been formed.

The second shift register 86 also shifts the numbers twice Length by taking it from data lines 3 and 6 via inputs 87 and 85, respectively takes over. The shift can be done on shift registers 86 and 82 independently go ahead, because the register 86 becomes through its control unit 100 for the data shift controlled ~ the control signals elaborated and they of their exit 99 delivers to input 101 of shift register 86. The two displacement rules Esters 82 and 86 can be shifted over four words Execute numbers synchronously, with the transition; the information from the lower ones Place the second shift register 86 in the more significant places of the first Shift register 82 and vice versa by the control unit 94 via its link and outputs 97 and 98 happens.

The determination of the operating mode of the registers 82, 86, 89 and their entire synchronization; are taken over by the control unit 8 (#ig. 1), which send the control signals to the input 103 (FIG. 4) of the device 12 for data shifting and from this to the inputs 102 of the control units 100 and 94 for data shifting and the register 82,86,89 supplies the means 12 for data shifting.

The cascading unit 13 (FIG. 5) contains mask storage registers 108 and 109, the inputs 105 and 106 of which are alternately a mask from the memory unit 18 for the control information is supplied to the masking unit 13 via the input 104 will. The changeover switch 110 switches via the outputs 113, 114 and 115 of the masking unit 13 to the respective data lines 3, 6 and 7 either from this or that mask the mask storage registers 108 and 109 or directly from the storage unit 18 for the tax information under the action from at the entrance 116 of the masking unit 13 from the control unit 8 (FIG. 1) ankorimenden control signals at. The toggle switch 110 (FIG. 5) can be any of the inputs 107, 111 and Switch 112 to any of the outputs 113, 114 and 115, which allows on any of the lines 3, 6 and 7 three different masks at the same time in any combination, including an equal mask on all three Lines to apply.

The mentioned special feature of the classification unit 13 expands the possibilities the calculating machine, makes it possible to avoid the fractional connections, simplified the control, increases the reliability and increases the speed of the machine.

To search for and narrow down those that arise in the calculating machine The diagnostic unit 117 (FIG. 1) is provided for malfunctions. The ones in most Units and equipment of the machine provides built-in control device when a fault occurs via its outputs 123 fault signals for the Diagnostic unit 117 via its control input 122. Diagnostic unit 117 immediately sets the process of performing the operation in the machine by locking it the control unit 8 by sending a blocking signal to it via the control input 119 there.

It should be emphasized that the diagnostic unit 117 works with only in the case starts when this is done by the control unit 10 of the Control register is enabled. The release signal for the work of the diagnostic unit 117 is given to their blocking input 121.

After the machine has been switched off, the diagnostic unit 117 delivers into the operational memory (not shown) via its output 124 a series of commands, whereby he is used to take over and record the situation, i.e. the state of everyone Units, lines and equipment of the machine for the moment of creation being prepared for the fault. The token address unit 14 is accessed via its input 126 the address of the beginning of the recording of the situation and of the formation unit 16 for the address of the next microinstruction via input 127 the addresses given the micro-commands to record the situation. After the recording the situation, the diagnostic unit 117 tries to repeat the command several times, in which the fault occurred. If the repetition was successful and no errors have occurred, the malfunction is considered to be coincidental and the program will continue to be processed. If the error occurs every time it is repeated, it is judged to be a failure and unit 17 begins containment procedures of the disturbances.

The procedures come to an end when certain microinstructions are called of the control information storage unit 18 by supplying previously known ones Addresses at entrance 127 of the formation unit 16 for the address of the next microinstruction, a control via input 120 of the diagnostic unit 117 on the correctness of the passage of the address to the memory unit 18 and a Activation of certain micro-commands via the input 119 in the control unit 8 out.

The diagnostic unit 117 can by a special command "Dia; nose" be operated. The diagnostic unit 117 is via the input 121 from the unit 10 of the tax registers operated. The additional information reaches the diagnostic unit 117 from the data line 3 via the Informa.

input 118.

The presence of coupling of the units and facilities the calculating machine with several identical data lines via several inputs and From £; ange makes the task of automatic troubleshooting much easier. It is sufficient, several transmissions over other lines as well as other inputs and outputs to be carried out by adding a register or a unit to said coupling chain is switched on alternately from the group where the error was discovered, to quickly and precisely narrow down the failed route. The mentioned peculiarity considerably facilitates the diagnosis of the machine, increases its effectiveness, requires not a large number of special diagnostic compounds because they are based on the Realized basic equipment as well as relieving it of the need for an extensive one and own extensive test software.

The storage device 9 (FIG. 6) for data storage for the execution time an instruction is for storing intermediate results of the calculations, of Addresses and operands are provided for information processing in the course required to execute a command. When performing operations at the numbers introduced into the data storage unit 128, they are in the first Half cycle of the work of the machine on the data lines 3,6 and 7 called in second half cycle of the work of the calculating machine is the data from the data lines 3, 6 and 7 into the data storage unit 128 via the information outputs and inputs 36 of unit 128 enrolled. In the course of one work cycle of the machine six addresses - three read and three write addresses - are controlled. This allows independent and simultaneous transmissions over three data lines 3,6,7 to realize, two operands at the same time for processing in the first half measure and write the result in the second half measure, etc.

The storage unit 18 serves as an address source for the control information. Each of the write and read addresses is independent of the memory unit 18 specified to the others via the address inputs 141. As other addresses.

a counter unit 143 occurs. Changeover switches 129, 130, 131, 135, 136 and 137 determine which of the address sources to the data storage unit 128 must be connected.

When addressing the data storage unit containing 2n storage cells 128 through the control information storage unit 18 is derived from the latter put the (n + 1) th tunnel address on toggle switches 129, 130, 131, 135, 136 and 137, where n places the cell name ax; precisely, while the (n + 1) -th place is a field feature represents. If the (n + 1).

-th digit has a value L, the n address digits are through the switches 129, 130, 131, 135, 136 and 137 passed and through the data storage unit 128 added as active address. But if the state of the (n + 1) th digit Is 0, there is no reading (writing) in the given work cycle of the I machine on the corresponding data line 3, 6 and 7. The address positions to develop other microinstructions for reading information (writing in) the corresponding data line 3,6,7 from the other units of the calculating machine exploited. The value O in all (n + 1) address positions means an absence of the Operation, i.e. there is no address and no microinstruction. The said connection of the units significantly increases the flexibility of the utilization of the storage device 9 for data storage for the execution time of an instruction, facilitates micro-programming and saves the capacity of the control information storage unit 18 by utilizing it the same locations both for addressing the data storage unit 128 and for coding microinstructions for the other units of the machine.

This is how the read and write addresses are stored with the help of the memory unit 18 explicitly and unambiguously for the tax information; egebelì what happens during processing of most processing algorithms is also necessary. But when it comes to processing longer operands, the format of which corresponds to the number of digits in the data storage unit 128 exceeds a multiple, additional apparatus is required. It fits so that the information for processing is only partially, namely word by word, accordingly the number of digits of the data storage unit 128 can be called up. On every part the same operation must be performed. For example, it's two 10 words add long operands. The first operand is in cells 1 to 10, the second in cells 11 through 20, while the result in cells 21 through 30 too send is. In the first mjkro command the first and the eleventh cell are called, perform an addition and send the result to the twenty-first cell, in the second microcommand the second and twelfth cells are controlled, one Addition performed and the result sent to the twenty-second cell, and so on. It can be seen that with an explicit address specification of the data storage unit 128 the L'ikroprogramn be linear and many cells of the storage unit 18 for the Control information, in the present example ten, will take. If you take into account that on a processing cycle in reality more than one Microinstruction (6 to 10 microinstructions), it becomes apparent that such a Addressing system is extensive. In addition, the operand lengths are not constant and can move within wide limits.

An address change is required to process the long operands the data storage unit 128 is used via the counter unit 143 into which the address of the first consecutively arranged cells to be processed is entered. The microprogram is processed cyclically, with the counter value in each cycle advanced (decreased or increased by a certain value). aside from that a new group of cells is processed in each cycle. Here is the saving of the cells of the storage unit 18 for the control information obviously.

When executing complicated microprograms as they are processing operations for the long operands, the need arises with explicit addressing in the same way as to work with the change of address, whereby some of the addresses are explicit, the others given by the unit 143 of the counter or not at all can be exploited while the corresponding locations of the storage unit 18 encode the other control microinstructions for the control information. The combination number is very large with six addresses, and all combinations can be used second hand will. In addition, in the course of the execution of the cycle, the need arises to specify the address both explicitly and through the unit 143 of the counters. To switch on; of the address change operation reaches each of the changeover switches 129, 130, 131, 135, 136 and 137 from the storage unit 18 for the control information a switching signal to change the address. The presence of the switching signal to change the address at the inputs 141 means that as an address source for the data storage unit 128 the unit 143 of the counter must be used.

However, not all addresses of the storage unit 128 can be used in the address change participate, but it is known in advance which of them will be in this company work vjerden. Before it is used in the processing cycle, a control information register 151 entered a constant via its input 153 which determines which of the switches 129, 130, 131, 135, 136, 137 operate in the address change mode have to. The address change mode is activated by the switches mentioned above Inputs 142 specified. Each of the locations of the control information register 151 is connected to their switch 129 to 131, 135 to 137 and releases (or blocks es), a corresponding counter when signaling to switch on the address change the unit 143 to connect.

The constant is stored in the control information register 151 for the Execution time of a command of the entire processing cycle entered. if but in the current work cycle the corresponding address is not activated is needed, the (n + 1) th address position is not sent via input 141 issued. To switch on the address change operation according to the present Address, the following conditions must be met. Presence of the (n + 1) th Address position at input 141 of changeover switches 129, 130, 131, 135, 136, 137; To be available of L in the corresponding location of the control information register 151 and its Transmission via input 142 to the corresponding switch mentioned, presence of the address change switching signal from the control information storage unit 18. Here, the position of the register 151 determines the addresses to which the address change is made occurs, the (n + 1) -th address position at input 141 determines whether the relevant Address in this clock works while the address change signal from the memory unit 18 for the control information to all changeover switches 129, 130, 131, 135, 136 and 137, that the counter unit 143 is to be connected as an address source when the above necessary conditions are met.

As from the description of the work of the storage device 9 for Data storage for the execution time of a command it appears their adrebs system is very flexible and allows the possibility of addressing to the data storage unit 128 to evaluate a maximum of several addresses.

The data storage unit 128 is based on a matrix of cells 1'6 (Fig. 7) executed a homogeneous matrix structure. The decrypted read address reaches corresponding inputs 161 of the via read signal points lines 162 Cells 156. The information is transferred from the addressed cells 156 to the corresponding, connected to the respective data line 3, 6 or 7 via the output 36 (FIG. 6) Place information lines 158 read out. When recording information from The information arrives at the data lines 3, 6 or 7 via the inputs 36 of the memory device 9 for data storage eurythmy for the execution time of an instruction on the location information lines 158 (Figure 7).

On from the decipherers (not shown) via the corresponding Write signals given to write signals digit lines 160 become the information written into the cells 156 via their information inputs 157.

The presence of some inputs and some outputs on each cell 156 of the homogeneous matrix structure, when it is interconnected to form a matrix, read the information in several directions at the same time. The presence of some Address inputs of the matrix allow reading and writing from different Control directions simultaneously and independently.

L e r s e i t e

Claims (8)

NUMBER CALCULATING MACHINE Patent claims Digit calculating machine that a program information storage device, the information input to a Data line is connected, which is used for the transmission of when processing too Operands, commands, intermediate and final results to be stored and shifted is provided, a unit of control registers for storing commands and Program status word whose control input is connected to the output of a control unit whose input is connected to the output of a storage unit for the control information is connected, at whose address input the address of the next Nikrobefehis arrives and which is electrically coupled to the output of the unit of control registers, a processing unit whose information output is connected to the data line is, to which also the information input and output of a data recording and transmission unit is connected, a data address unit whose information input is electrical with the information output of the unit of the control register and its control input is connected to the output of the control unit, to which the control inputs are also connected the program information storage means of the data recording and transmission unit and the computing unit are connected, the other control input to the other Output of the storage unit for the control information is connected to that too at len address input of the memory device for storing program information is connected, contains that it is two additional data lines (6, 7), a memory device (9) for data storage for the execution time of a command, its information inputs and outputs (36) connected to the main data line (3) and to the additional data lines (6, 7) are, a device (12) for data shifting, one of which is information input (44) to the main data line (3) and its other information inputs and outputs (41) are connected to the additional data lines (6, 7), one for application a mask on the data provided masking unit (13), the information outputs (39) to the main data line (3) and to the additional data lines (6, 7) are connected, a formation unit (16) for the address of the next microinstruction, whose input (28) for the start address to the output of the unit (10) the control register, the output of which goes to the address input (27) of the memory unit (18) for the control information and its address input (21) to the output of the Storage unit (18) for the control information is connected to the address input (20) of the storage device (1) for program information storage and to which the information input (23) of the masking unit (13) and the address input (19) the memory device (9) for data storage for the execution time of a Command are connected, an analysis line (30) for transmitting the information on the state of the memory device (9) for data storage for the execution time an instruction, the program information storage means (1), the unit (10) the control register, the computing unit (11), the device (12) for data shifting and the formation unit (16) for the address of the next microinstruction in response a request from the formation unit (16) for the address of the next microinstruction contains, the analysis outputs (31, 32, 33, 34, 35) of the storage device (9) for data storage for the execution time of a Instruction, the program information storage device (1), the unit (10) of the Control register, the computing unit (11) of the device (12) for data shifting and the analysis input and output (29) of the formation unit (16) for the address of the next micro command are connected to the additional data lines (6, 7) also information outputs (4, 5) of the program information Storage facility (1), information input and output (40) of the unit (10) of the control register, information inputs (42) of the computing unit (11), information outputs (25, 26) of the memory unit (18) for the control information, information input and output (37) of the data recording and transmission unit (15), information input and output (38) of the data address unit (14), the information output (24) of the memory unit to the main data line (3) (18) for the control information and the other information input and output (38) the data address unit (14), the control inputs to the output of the control unit (8) the masking unit (13), the formation unit (16) for the address of the next Mikrobefehis, the memory device (9) for data storage for the execution time of a command and the unit (12) for data movement are connected. 2. Machine according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the main data line (3) and the additional data lines (6, 7) a data storage circuit for the execution time at least one in each place Micro instruction included. 3. Machine according to claim 2, d a d u r c h g e k e n n -z e i c h n e t that the data storage circuit for the execution time at least one Microinstruction, at the output of which a signal for the transmission of masked and unmasked Data is formed, at least one section (49) of the main data line (3) or the additional data lines (6, 7) for each point for data transmission in two-way traffic, a logical AND-NOT element <51) for the transmission of masked data, one of which as the input of the data storage circuit serving input (52) to the corresponding Information output (39) of the masking unit (13), the other inputs of which after the Number of sections of the data line to the corresponding section (49) of the data line are connected and its output (57) as the output of the data storage circuit serves, logical AND-NOT elements with two inputs each according to the number of sections the data line, one input (58) each to the output (57) of the logical AND-NIGHT element (51) is connected for the transmission of masked data whose other input (62) serving as the input of the data storage circuit in each case with the corresponding information output of the storage unit (18) for the control information electrically connected and its output to the input (see above) of the logical AND-NOT element (51) is connected for the transmission of masked data, a logical AND-NOT element (66) for the transmission of non-masked data, the inputs of which are according to the number of sections the data line is connected to the corresponding section (49) of the data line and whose output (67) serves as the output of the data storage circuit, an additional one logical AND-NOT element (69) with two inputs, one of which is the input of the Data storage circuit occurring input (70) with the corresponding information output the storage unit (18) for the control information electrically connected, its another Input (68) to the output (67) of the logical AND-NOT element (66) for the transmission of non-masked data and its output (71) to one of the Sections (49) of the data line is connected, and a circuit (72) for Restoring the L potential of the sections of the data line that contains electrically coupled to these and to an L potential and an O potential source connected. 4. WEschine according to one of claims 1 to 3, d a d u r c h g e k Note that it is a unit (78) for converting numbers from a Computing system in the other, whose information inputs to the main line (3) and to the first additional data line (7) whose information output (80) to the other additional data line (6) and its control input (81) to the output the control unit (8) are connected. 5. WI machine according to one of claims 1 to 4, d a d u r c h g e k It is noted that the means (12) for data shifting has two data shift registers (82, 86), whose information inputs and outputs (83, 84, 85) are each used as information inputs and outputs of the device (12) are used to move data, while the information input and output (83 or 84) of the first (82) of them to the additional data lines (6, 7) and the information input and output (85) of the second register (86) one of the additional data lines (6) and its other, also as an information input the device (12) for data shifting serving information input (87) are connected to the main data line (3), a register (89) for the the next ouotient number whose information output (88) is that of the additional data lines is connected to which the first data shift register (82) is connected, has two control units (94, 100) for the data shift, the control output (93) of the first of them to the control input (92) of the Register (89) for the next following quotient digit is connected, its analysis output (95) serves as the analysis output of the device (12) for data shifting, its information input (96) to the main data line (3), its two other inputs and outputs (97, 98) the two data shift registers (82, 86) are connected while the output (99) of the second control unit (ion) to the second data shift register (86) is connected, the information inputs (90, 91) of the register (89) for the next following quotient number as inputs of the device (12) for data shifting occur and to the computing unit (11) and to the memory unit (18) for the Control information are connected, while the control inputs (102) of the two Data relocation registers (82, 86), the control units (94, 100) and the other Control input (102) of the register (89) for the next quotient digit connected together and serve as a control input (103) of the device (12) for data shifting. 6. Machine according to one of claims 1 to 5, d a -d u r c h g e k It is noted that the masking unit (13) has at least two Jjasking memory registers (108, 109), whose information inputs (105, 106) are interconnected and as Information input (104) of the masking unit (13) are used, and a switch (110) contains, whose two inputs (111, 112) to the outputs of the two mask storage registers (108, 109) are connected, the third input (107) fight back with the interconnected SingEngen (105, 106) of the mask storage registers (108, 109) are connected and the Outputs serve as information outputs (113, 114, 115) of the masking unit (13), the control inputs of the two mask memory registers (108, 109) and of the switch (110) are combined and serve as a control input (116) of the masking unit (13). 7. Machine according to one of claims 1 to 6, d a -d u r c h g e k It is noted that it has a diagnostic unit (117) for the limitation of Has disturbances whose information input and output (118) to the main data line (3), its control input and output (119) to the control unit (8), its address input (120) to the output of the formation unit (16) for the address of the next microinstruction, its blocking input (121) to that output of the unit (10) of the control register is connected to the input (28) for the start address of the formation unit (16) for the address of the next microinstruction is switched at the control input (122) of the diagnostic unit (117) the main and additional Data lines (3, 6, 7) and the control outputs (123) of the device (12) to Data shift, the arithmetic unit (11), the unit (10) of the control register, the program information storage device (1), the storage device (9) for Data storage for the execution time of a command, the storage unit (18) for the control information, the formation unit (16) for the address of the next Microinstruction, the data acquisition and transmission unit 15, the data address unit 14 and the masking unit (13) are connected, the output (124) of the diagnostic unit (117) serves as the output of the calculating machine and its address output (125) to the Address input (127) of the formation unit (16) for the address of the next Nikrobemehls and is connected to the address input (126) of the data address unit (14). 8. Machine according to one of claims 1 to 7, d a d u r c h g e k It is noted that the memory device (9) is used to store data for the execution time of a command a data storage unit (128) with information input and - outputs according to the number of main and additional data lines (3, 6, 7), each of which is connected to the corresponding data line (3, 6, 7), three Changeover switch (129, 130, 131) for commutating the address for data recording from the corresponding data line (3, 6, 7), their outputs (132, 133, 134) are connected to the corresponding inputs of the data storage unit (128) are, three changeover switches (135, 136, 137) for commutating the address for the data output to the corresponding data line (3, 6, 7), whose outputs (138, 139, 140) likewise are connected to the corresponding inputs of the data storage unit (128), a counter unit (143) for changing the address of the data storage unit (128), whose Output to the input (142) of each changeover switch (129, 130, 131, 135, 136, 137) is connected, a control information register (151) up, 1eist, whose information output (150) to the control inputs (144, 146, 148, 1zu5, 147, 149) of each of the changeover switches (129, 130, 131, 135, 136, 137), control input to the control input of the counter unit (143) is connected and as a control input (155) of the storage device (9) is used to store data for the execution time of a command, P! 0-bei die Information inputs (153, 152) of the control information register (151) and the counter unit (143) are interconnected and as an address input (154) of the memory device (9) serve to store data for the execution time of a command, during which other input (141) of each of the switches (129, 130, 131, 135, 136, 137) as well as the address input of the entire memory device (9) for data storage for the execution time of an instruction is used.