CH406678A - Data processing system in which data words can be automatically prepared for printing - Google Patents

Description

  

      Additional patent to main patent No. 386 734 Data processing system in which data words can be automatically prepared for printing The main patent describes a data processing system in which two data words to be linked are taken character by character from a memory and the result of the connection is then fed back to the memory ,

   in which, under the control of a clock pulse distributor, an address register serving to control the. Spei cher with its input optionally to the output of two address intermediate registers provided for receiving the memory addresses each one character of the two data words to be linked and with its output via an address converter , which increases or decreases the address contained in the address register by a certain amount,

      to the input of one of these intermediate address registers, and in which, furthermore, of two registers that are intended to receive one character each of the two data words to be linked, the first register with its input to the output of the memory and its output to the input of the second register and each output of the two registers can be connected to the input of the memory or the input of a linking network that can be connected to the input of the memory.



  The object of the invention is an advantageous development of the subject of the main patent, which makes it possible to edit data words stored in the data processing system in a particularly simple manner, d. i.e., prepare for printing.

   This is achieved according to the invention in a data processing system according to the present addendum patent in that an editing device contained in the linking network controls the linking of the two words that can be extracted character by character in such a way that either the character stored in the first register a so-called format control word or, if spaces or certain control characters occur in the format control word, the character stored in the second register of a data word to be prepared for printing is transferred back to the memory.



  The invention is described in more detail below with the aid of an exemplary embodiment.



  In the accompanying drawings: Fig.l shows the block diagram of the data processing system according to the main patent, Fig. 2a-2e the editing device, Fig.3-7 the basic logic circuits used in the circuits, Fig. 8 the device for generating the characters during editing and Figure 9 illustrates the manner in which Figures 2a-2e are to be arranged.



  In Fig. 1 a block diagram of the data processing system is shown according to the main patent. It is briefly described below as the present invention uses the controls contained therein. In the data processing system shown in Fig. 1, the digits are transmitted and processed in series and the bits in parallel. A magnet core memory 11 contains all the characters to be used in the internal operation of the machine. Each character contains eight bits (1 or 0) in different arrangements, which each make up the meaning of the character.

   In the arrangement shown in FIG. 1, a symbol is contained in each vertical section 11a, which contains eight magnetic core planes.



  When each vertical core section is set to display a particular character, the character can be extracted on line 13 or entered on line 15 by selecting a desired coordinate position. This coordinate position is selected in accordance with an X matrix and a Y matrix, which decrypt a specified number in the address register 21, so that you get the desired coordinates with which you denote by this number Receives characters in memory.



  When the character selection is carried out by the X matrix and the Y matrix, the magnetic cores which contain the individual bits of a character are reset to 0. As a result, each character is transferred into a circular buffer register 23 as the combination of bits which were previously contained in the cores of said column.



  The character then standing in the circulating buffer register 23 is transferred to a circulating register 25 and through the line 15 also to the same position in the memory 11, or it is transferred directly from the circulating buffer register 23 in the memory 11 at the memory location from which it originated , repositioned, or used in a logic operation, and the results are saved in the location from which the character originated. In contrast to the foregoing, operation characters are stored in an operation register 27.



  In the operation of the present machine, the address of the next instruction is contained in an instruction register 29. The address, which is represented by a number, designates the first digit of a command word contained in the memory 11 in a group of memory locations, the command word memory locations. The command word consists of the operation code and the addresses for the data words to be linked.



  The operation code that determines the operation of the machine is a one-character designation such as E (for editing), A (for adding), etc. The A address and B address can contain up to three digits each. They prescribe the first digit of the two operands that are to be used in the processing process identified by the operation code.

   Other operation codes can be used after the A and B address if the operations identified by them are to be carried out with groups of characters that start with the first address of <I> A </I> and <I> B < / I> follow the designated character groups.



  The commands can be of any length. Similarly, the operands or data on which an operation is to be performed do not have a fixed length. To designate the beginning of an instruction or the end of an operand, the relevant digit is provided with an additional marker. This so-called word mark is listed in an additional, the eighth core level.



  During the operation, the command word is transferred character by character from the memory 11 into the circulating buffer register 23. The first character, the operation code, is stored in the operation register 27. The following characters are the addresses for the A and B registers 33 and 31. The command register 29 is added by an address converter 35 to the number one or another digit stored in the address register, switched to the next address, which is then used as an address is returned to the command counter for the next J3efehis digit.



  After the complete command addresses have been entered in the main memory address registers <I> A </I> and <I> B, </I> abbreviated <I> A </I> MAR and <I> B </I> MAR the operation continues according to the operation character stored in operation register 27. The operation register 27 is connected to a translator 37, which converts a special operation symbol into a form recognizable by a circulation control 39.



  The circulation control 39 is the control mechanism for the machine and transmits all necessary signals to all parts of the device so that a suitable operation is secured for the operation code then stored in the operation register 27.



  <I> A- </I> and B cycles in which data are transferred from memory 11 to registers 23 and 25 emanate from circulation control 39. During an A cycle, a character is transferred from memory 11 at the memory location prescribed by <I> A </I> MAR 33 into B register 23, during the removal part of the cycle and into the same digit position in memory 11 returned during the input portion of the A cycle at the same time as it is being stored in register 25.

   During a B cycle, a character is taken from memory 11 and stored in register 23 in accordance with the address prescribed by <I> B </I> MAR 31. During the input part of the B cycle, this character can be returned to memory in the same memory location, or a different character can be inserted in that memory location.



  In general, there are therefore two rounds of operations <I> A </I> and <I> B </I> with two reverse circulation registers <I> A </I> and <I> B, </I> 25 and 23, which in these circulations take on characters that were designated by the <I> A </I> and <I> B </I> MAR 33 and 31. Every time an A or B circulation is used, the address in the A and B registers is changed by one and designates the next following digit storage location in memory 11 from which to be taken in the next used circulation.

   It can therefore be seen that in a common case, the results of an operation with operands stored in an A and B storage location can be found in the B storage location.



  When editing, the control word format is stored in the immediately consecutive memory locations which are identified in more detail by the first digit address stored in the <I> B </I> MAR. The data to be edited are similarly stored in a storage location identified by the address of the first digit stored in the <I> A </I> MAR. If an editing operation code is used, the digits are transferred from each storage location to the A register 25 and B register 23.



  In the removal part of the B cycle, after the number designated by the <I> B </I> MAR has been transferred to the B register 23, an editing circuit 41 then looks for the character in the B register 23. During the input part of the B cycle, the character stored in the A register 25 is returned by an AND circuit 43 which is controlled by an inhibit gate 45, which in turn is controlled by the editing circuitry 41.

    



  The inhibit gate 45 can also generate a special character during this time, which is different from the character stored in the A or B register, which is used at the address identified by the <I> B </I> MAR 31 should. If neither the character in the A register nor a special character is used, the character in the B register is fed back by the AND circuit 47 to the same digit position in the memory 11 from which it originates.



  If the character stored in the A register 25 is used in the place of the character stored in the B register 23, an A circuit and a B circuit are generated for the extraction of the next character, which are located at the one in <I> A </I> MAR 33 and <I> B </I> MAR 31 is located. If the character stored in the B register 23 is used, the character designated by the B address in the <I> B </I> MAR 31 is used and another B cycle is carried out.

   In a similar manner, a further B cycle results from a special character generated by the inhibit gate 45 in cooperation with the editing circuit 41.



  If a control word is at the B addresses identified by <I> B </I> MAR 31, then each control word digit controls the digit that is entered during the B cycle and the resulting digit to that of the <I > B </I> MAR 31 prescribed addresses is composed of characters from the A storage location, into which characters of the control word and any special characters are interspersed.



  When a complete merge operation has taken place, the editing device 41 determines whether another instruction cycle is in progress, or whether the merged data information now stored in the locations of the earlier control word is once again extracted through the B register 23 with a further editing process by the editing device 41.



  Before a detailed description of the editing device, the basic circuits used are explained in more detail.



       Fig. 3 shows an AND circuit in which a PNP transistor 59 is used. A series of diodes 61 connect the inputs to the base of the transistor. When all diodes are biased with a voltage -T, the PNP transistor provides a voltage + U. When any diode 61 is biased with a voltage + T, the output falls to -U. Fig. 3b shows the schematic representation of the circuit.



  In Fig. 4a an AND circuit with an NPN transistor is shown in which all diodes must be biased to a voltage + U so that an output voltage -T is generated. Each voltage -U on any diode 65 provides an output + T. Fig. 4b shows the schematic representation of the circuit.



  In Fig. 5a an OR circuit with NPN transistors provides an output voltage -T for any input voltage + U. Fig.5b gives the schematic representation of the circuit.



       6a is a circuit for a P block which converts a voltage + U into an output voltage <I> -T </I> and an input voltage -U into an output voltage + T. Fig.6b is the schematic representation of the circuit.



  The encryption of the data and command words are only shown for some characters:
EMI0003.0079
  
    Character <SEP> machine code
<tb> <I> C <SEP> B <SEP> A <SEP> 8 <SEP> 4 <SEP> 2 <SEP> 1 </I>
<tb> space <SEP> X
<tb> X <SEP> X <SEP> X <SEP> X <SEP> X
<tb> & <SEP> X <SEP> X <SEP> X
<tb> $ <SEP> X <SEP> X <SEP> X <SEP> X <SEP> X
<tb> X <SEP> X <SEP> X
<tb> - <SEP> X
<tb> X <SEP> X <SEP> X <SEP> X <SEP> X
<tb> A <SEP> X <SEP> X <SEP> X
<tb> B <SEP> X <SEP> X <SEP> X
<tb> C <SEP> X <SEP> X <SEP> X <SEP> X <SEP> X
<tb> K <SEP> X <SEP> X <SEP> X
<tb> L <SEP> X <SEP> X <SEP> X
<tb> S <SEP> X <SEP> X <SEP> X
<tb> T <SEP> X <SEP> X <SEP> X
<tb> 0 <SEP> X <SEP> X <SEP> X.
<tb> 1 <SEP> X
<tb> 2 <SEP> X
<tb> 3 <SEP> X <SEP> X <SEP> X
<tb> 4 <SEP> X
<tb> 5 <SEP> X <SEP> X <SEP> X
<tb> 6 <SEP> X <SEP> X <SEP> X
<tb> 7 <SEP> X <SEP> X <SEP> X
<tb> 8

  <SEP> X
<tb> 9 <SEP> X <SEP> X <SEP> X The command for an editing operation can have the following appearance:
EMI0004.0002
  
    Command word <SEP> E <SEP> 7 <SEP> 8 <SEP> 9 <SEP> 3 <SEP> 0 <SEP> 0
<tb> Main memory address <SEP> 001 <SEP> 002 <SEP> 003 <SEP> 004 <SEP> 005 <SEP> 006 <SEP> 007 E is the operation code that indicates an editing operation, while the digits 789 are the address of the first Identify the digit of the data word to be worked with and name 300 the first digit of the format control word that is to be used in connection with the present editing operation.

   These digits had been entered into the <I> A </I> MAR and the <I> B </I> MAR through a series of command cycles that occurred after the operation that preceded the current operation.



  The data word at address 789 and Aden following storage locations should look like this:
EMI0004.0011
  
    Data word <SEP> 0 <SEP> 0 <SEP> 2 <SEP> 5 <SEP> 7 <SEP> 4 <SEP> 2 <SEP> 6
<tb> Main memory address <SEP> 782 <SEP> 783 <SEP> 784 <SEP> 785 <SEP> 786 <SEP> 787 <SEP> 788 <SEP> 789 and the control word at address 300 and lower as follows:

       
EMI0004.0016
  
    Control word <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP> b <SEP> b <SEP> 0 </I>
<tb> Main memory address <SEP> 284 <SEP> 285 <SEP> 286 <SEP> 287 <SEP> 288 <SEP> 289 <SEP> 290 <SEP> 291
<tb> Control word <SEP> <I> b <SEP> b <SEP> & <SEP> C <SEP> R <SEP> & </I>
<tb> Main memory address <SEP> 292 <SEP> 293 <SEP> 294 <SEP> 295 <SEP> 296 <SEP> 297 <SEP> 298 <SEP> 299 <SEP> 300 If the operation code in register 27 and the addresses of the Data word and in the A and B address registers,

   the machine is ready to perform an editing operation. During the A cycle, the digit stored in the memory location specified in <I> A </I> MAR 33 is taken from the main memory, passed through the B register, stored back in its starting position in memory 11 and transferred to the A register.

   During the B cycle, the digit stored in the memory location designated by the MAR 31 is taken from the memory 11 and entered into the B register. The B register contains a control word character which can be returned to the B address in the main memory or the character can be accommodated in the A register at this address.



  The table below shows the operations performed in the example chosen.
EMI0004.0039
  
    Uml. <SEP> <I> MAR <SEP> REG <SEP> SP. </I> <SEP> B field
<tb> <I> 1 <SEP> A <SEP> B <SEP> B <SEP> A </I> <SEP> at the <SEP> end <SEP> of the <SEP> cycle
<tb> 1 <SEP> A <SEP> 008 <SEP> 0788 <SEP> 0300 <SEP> 6 <SEP> 6 <SEP> 6 <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>. <SEP> b <SEP> b <SEP> & <SEP> C <SEP> R <SEP> & </I>
<tb> 2 <SEP> B <SEP> 008 <SEP> 0788 <SEP> 0299 <SEP> 6 <SEP> * <SEP> do.
<tb> 3 <SEP> B <SEP> 008 <SEP> 0788 <SEP> 0298 <SEP> '"<SEP> 6 <SEP> * <SEP> do.
<tb> <I> 4 <SEP> B </I> <SEP> 008 <SEP> 0788 <SEP> 0297 <SEP> & <SEP> 6 <SEP> Blank <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>.

   <SEP> b <SEP> b <SEP> & <SEP> C <SEP> R <SEP> b </I>
<tb> 5 <SEP> B <SEP> 008 <SEP> 0788 <SEP> 0296 <SEP> R <SEP> 6 <SEP> Blank <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>. <SEP> b <SEP> b <SEP> & <SEP> C <SEP> b <SEP> b </I>
<tb> 6 <SEP> B <SEP> 008 <SEP> 0788 <SEP> 0295 <SEP> C <SEP> 6 <SEP> Blank <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>. <SEP> b <SEP> b <SEP> & <SEP> b <SEP> b <SEP> b </I>
<tb> 7 <SEP> B <SEP> 008 <SEP> 0788 <SEP> 0294 <SEP> & <SEP> 6 <SEP> Blank <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>. <SEP> b <SEP> b <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 8 <SEP> B <SEP> 008 <SEP> 0788 <SEP> 0293 <SEP> <I> b </I> <SEP> 6 <SEP> 6 <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>.

   <SEP> b <SEP> 6 <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 9 <SEP> A <SEP> 008 <SEP> 0787 <SEP> 0293 <SEP> 2 <SEP> 2 <SEP> 2 <SEP> do.
<tb> 10 <SEP> <I> B </I> <SEP> 008 <SEP> 0787 <SEP> 0292 <SEP> <I> b <SEP> 2 <SEP> 2 <SEP> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> 0 <SEP>. <SEP> 2 <SEP> 6 <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 11 <SEP> A <SEP> 008 <SEP> 0786 <SEP> 0292 <SEP> 4 <SEP> 4 <SEP> 4 <SEP> do.
<tb> 12 <SEP> B <SEP> 008 <SEP> 0786 <SEP> 0291 <SEP> 4 <SEP> do.
<tb> 13 <SEP> <I> B </I> <SEP> 008 <SEP> 0786 <SEP> 0290 <SEP> 0 <SEP> 4 <SEP> 4 <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> b <SEP> _4 <SEP>.

   <SEP> 2 <SEP> 6 <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 14 <SEP> A <SEP> 008 <SEP> 0785 <SEP> 0290 <SEP> 7 <SEP> 7 <SEP> 7 <SEP> do.
<tb> 15 <SEP> <I> B </I> <SEP> 008 <SEP> 0785 <SEP> 0289 <SEP> <I> b <SEP> 7 <SEP> 7 <SEP> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> b <SEP> 7 <SEP> _4 <SEP>. <SEP> 2 <SEP> 6 <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 16 <SEP> A <SEP> 008 <SEP> 0784 <SEP> 0289 <SEP> 5 <SEP> 5 <SEP> 5 <SEP> do.
<tb> 17 <SEP> B <SEP> 008 <SEP> 0784 <SEP> 0288 <SEP> <I> b </I> <SEP> 5 <SEP> 5 <SEP> <I> $ <SEP> b <SEP> b <SEP> b <SEP>, <SEP> 5 <SEP> 7 <SEP> 4 <SEP>. <SEP> 2 <SEP> b <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 18 <SEP> A <SEP> 008 <SEP> 0783 <SEP> 0288 <SEP> 2 <SEP> 2 <SEP> 2 <SEP> do.
<tb> 19 <SEP> B <SEP> 008 <SEP> 0783 <SEP> 0287 <SEP> 2 <SEP> do.

         
EMI0005.0001
  
    Uml. <SEP> <I> MAR <SEP> REG <SEP> SP. </I> <SEP> B field
<tb> <I> I <SEP> A <SEP> B <SEP> B <SEP> A </I> <SEP> at the <SEP> end <SEP> of the <SEP> cycle
<tb> 20 <SEP> B <SEP> 008 <SEP> 0783 <SEP> 0286 <SEP> <I> b <SEP> 2 <SEP> 2 <SEP> $ <SEP> b <SEP> b <SEP> 2 <SEP>, <SEP> 5 <SEP> 7 <SEP> _4 <SEP>. <SEP> 2 <SEP> 6 <SEP> b <SEP> b <SEP> b <SEP> b </I>
<tb> 21 <SEP> A <SEP> 008 <SEP> 0782 <SEP> 0286 <SEP> 0 <SEP> 0 <SEP> 0 <SEP> do.
<tb> 22 <SEP> B <SEP> 008 <SEP> 0782 <SEP> 0285 <SEP> <I> b </I> <SEP> 0 <SEP> 0 <SEP> <I> $ <SEP> b <SEP> 0 <SEP> 2 <SEP>, <SEP> 5 </I> <SEP> 7 <SEP> 4 <SEP>.

   <SEP> 2 <SEP> 6 <SEP> b <SEP> <I> b <SEP> b <SEP> b </I>
<tb> 23 <SEP> A <SEP> 008 <SEP> 0781 <SEP> 0285 <SEP> _0 <SEP> _0 <SEP> 0 <SEP> do.
<tb> <I> 24 <SEP> B </I> <SEP> 008 <SEP> 0781 <SEP> 0284 <SEP> b <SEP> 0 <SEP> 0 <SEP> $ <SEP> 0 <SEP> 0 <SEP> 2 <SEP>, <SEP> 5 <SEP> 7 <SEP> _4 <SEP>. <SEP> 2 <SEP> 6 <SEP> b <SEP> <I> b <SEP> b <SEP> b </I>
<tb> 25 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0284 <SEP> _ $ <SEP> 0 <SEP> $ <SEP> do.
<tb> 26 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0285 <SEP> $ <SEP> 0 <SEP> $ <SEP> do.
<tb> <I> 27 <SEP> B </I> <SEP> 008 <SEP> 0781 <SEP> 0286 <SEP> 0 <SEP> 0 <SEP> Blank <SEP> <I> $ <SEP> b <SEP> 0 <SEP> 2 <SEP>, </I> <SEP> 5 <SEP> 7 <SEP> _4 <SEP>.

   <SEP> 2 <SEP> 6 <SEP> <I> b <SEP> b <SEP> b <SEP> b <SEP> * <SEP> '\ </I>
<tb> 28 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0287 <SEP> 0 <SEP> 0 <SEP> Blank <SEP> <I> $ <SEP> b <SEP> b <SEP> 2 <SEP>, </I> <SEP> 5 <SEP> 7 <SEP> 4 <SEP>. <SEP> 2 <SEP> 6 <SEP> b <SEP> <I> b <SEP> b <SEP> b <SEP> * </I>
<tb> 29 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0288 <SEP> 2 <SEP> 0 <SEP> 2 <SEP> do.
<tb> 30 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0289 <SEP> _0 <SEP> do.
<tb> 31 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0290 <SEP> 5 <SEP> 0 <SEP> 5
<tb> 32 <SEP> B <SEP> 008 <SEP> 0781 <SEP> 0291 <SEP> 7 <SEP> 0 <SEP> 7
<tb> 33 <SEP> B <SEP> 008 <SEP> 078 <B> 1 </B> <SEP> 0291 <SEP> 4 <SEP> 0 <SEP> 4 <SEP> <I> $ <SEP> b <SEP> b <SEP> 2 <SEP>, </I> <SEP> 5 <SEP> 7 <SEP> 4 <SEP>. <SEP> 2 <SEP> 6 <SEP> b <SEP> <I> b <SEP> b <SEP> b </I> The various columns have the following meanings: 1.

   Number of steps since the start of the initial instruction cycle 2. Type of cycle 3. Address register a) I register with the address of the instruction that is to be executed next after the editing operation, b) A register with the address of the next digit of the data word to be taken from the memory, c) B register with the address of the next digit of the control word 4. Contents of the registers <I> A </I> and <I> B </I> 5. The in the Main memory characters returned 6. The B field at the end of the cycle.



  The number of asterisks on the right-hand side of the control word indicates the type of sum when posting, whether it is a sum (one asterisk), a subtotal (two asterisks) or a main sum (three asterisks).



  In the present case, it is therefore a subtotal. It is of course possible that no stars are required at all, in which case the CR sign would be used.



  At step # 1, an A wrap begins and transfers the digit (a 6) stored in location 789 in the A main memory address register to the B register. It is passed to the A register and is transferred back into main memory at the same location 789 at the same time.

   In the next cycle, which is a B cycle, the digit (an asterisk) stored at 300, represented by the <I> B </I> MAR, is transferred to the B register, and since this is a punctuation Character to be used in the word is, it is transferred back to its storage location at the B address and another B wrap is made to get the next control character. The 6 that was in the A register remains as it is.

   In the next cycle, which is a B cycle, the number on the B MAR display 299 is excluded. Since this is also a star, it is processed in the same way as the star in step 2 so that the two stars appear in the edited word. In switching step no. 4, the number at address 298, as indicated by <I> B </I> MAR, is an AND sign and is stored in the B register.

    The ampersand is not returned to main memory like the asterisks, but it is ignored and its position in main memory is left blank, so between the * and then. next character will be given a space.



  The CR shown in the control word acts as a sign specification. The sign of the data word is plus, as indicated by the lack of a B bit above the ones digit. The CR symbol is therefore not required and is replaced by spaces. However, if the sign of the unit's digit of the data word shown as 789 were to have a minus sign, then the CR sign would be generated again.



  In this case it can be seen in switching steps no. 5 and 6 that successive B cycles are made, and that R and C are brought out of digit positions 297 and 296 and replaced by spaces that are returned to the main memory, so that the partially edited control word for step no. 6 contains an AND sign, three spaces and two asterisks to the right of the ampersand. In switching step no. 7, the number at 295 (an ampersand) is replaced by a space in the edited part of the control word.

   In switching step no. 8, the next B digit (a space) is brought out and the character in the A register is transmitted. Since a 6 has remained in the A register, a 6 replaces the space at storage location 294. In switching step no. 9, an A cycle is carried out, and a number at storage location 788, as in <I> A </I> MAR specified (one two), is shifted to the A register and also returned to the same location in the data word. A B wrap is then made and the digit stored in memory location 293 (a space) is brought out.

   This causes the number 2 in the A register to be transferred to location 293. On the next two A and B rounds, the digit 4 of the data word is brought out into the A register, and the punctuation mark decimal point is brought out and placed in the B register. In the present case, however, the punctuation mark takes precedence over the digit from the data field and is returned to the same location in main memory.



  In switching step no. 13, the data character 4 replaces the zero in the control word. The zero is written in the control word to indicate that a zero suppression operation is desired. An interlock is created that causes zeros to be discarded on a reverse sense operation. The limit for this operation is indicated by a word mark that is automatically added to the character in this position.



  The process continues as shown, and the data word characters are used in the place of spaces in the control word, until the comma is reached in the control word, at which point it is used again. In switching step no. 20, the number 2 is used in place of the blank at address 287.

   In the following switching steps no. 22 and 24 spaces contained in the control word are replaced by zeros in the data word up to the point where a dollar sign containing a word mark is sensed. This means the end of the control word, and it is replaced, as shown in the edited word to the left of the last zero;

      the edited word is now removed from the memory area by reversing the addition process in the B register so that the dollar sign returns, but any zero that is found is replaced with a space up to the point where the first significant digit is it is enough at what time the digit is replaced. Any additional zeros are not replaced by spaces.

   This process continues until the number 4, which contains the word mark, is reached. At this point the operation is terminated.



  The operation described above is the normal editing in this machine. In addition, there are now special procedures that can be carried out on each editing device in an additional device. These are the methods of filling the protective star, the sliding dollar sign, the sign control on the left and the decimal point separation. The first two possibilities are controlled by the characters * and $, which set word markers and transfer them from the A register in the same way as the signal for suppressing zeros.



  The protective star filling process works by substituting zeros and star punctuation until a significant digit is sensed. However, it is necessary that a 0 or a space appears to the right of this control star so that the main section lock is activated and the asterisk becomes effective. The floating dollar sign option works like zero suppression until the automatically inserted word mark is sensed.

   At that point, a second forward sensing is initiated and continues until the position of a blank is sensed. At this point a $ is inserted and the editing operation is complete.



  The decimal control takes effect when a decimal point is sensed on a retrograde sensing. The further suppression of zeros is blocked so that no blanks are generated, although the zero suppression interlock is still switched on. If there is no significant character in one of the positions to the right of the decimal point that could reset the zero suppression lock before the end of the cycle in which the automatically inserted word mark is sensed, then a new sense forward is generated.

   During this sensing process, all zeros and the decimal point are converted to spaces. The editing operation ends at the column of the decimal point.



  To control the sign on the left, it is necessary to create an interlock that is set by the B bit in the units position of the A field. CR and - are either newly formed in this interlocking or replaced by blanks.



  The example above and the procedures described follow a number of rules:
EMI0007.0001
  
    Control <SEP> function
<tb> characters
<tb> Rule <SEP> 1 <SEP> a <SEP> space <SEP> <I> (b) </I> <SEP> Specifies <SEP> the <SEP> positions <SEP>, <SEP> the <SEP> from <SEP> the <SEP> character <SEP> of the <SEP> A <SEP> field <SEP>
<tb> will be <SEP>. <SEP> Causes <SEP> a <SEP> transmission <SEP> from <SEP> the <SEP> A register.
<tb> Rule <SEP> 1 <SEP> b <SEP> 0 <SEP> As <SEP> for <SEP> space, <SEP> but <SEP> marks <SEP> additionally <SEP> the <SEP> outermost < SEP> right <SEP> limit
<tb> the <SEP> zero suppression. <SEP> A, <SEP> suppression <SEP> takes place <SEP> not <SEP>, <SEP> if
<tb> this <SEP> character <SEP> with <SEP> control word <SEP> is omitted <SEP>.
<tb> Rule <SEP> 1 <SEP> c <SEP> Will.

   <SEP> to <SEP> the <SEP>; position <SEP> reproduced, <SEP> where <SEP> it <SEP> was entered <SEP>; <SEP> will
<tb> but <SEP> removed, <SEP> if <SEP> the <SEP> total sum <SEP> is zero <SEP>, <SEP> the <SEP> option <SEP> of
<tb> Decimal control <SEP> set up <SEP> is <SEP> and <SEP> the <SEP> control <SEP> zero <SEP> on <SEP> the <SEP> right
<tb> Page <SEP> of the <SEP> decimal point <SEP> appears.
<tb> Rule <SEP> 1 <SEP> d <SEP> If <SEP> is played back <SEP> at <SEP> the <SEP> position, <SEP> where <SEP> <SEP> was entered <SEP> < SEP> and <SEP> from <SEP> the
<tb> Zero suppression operation <SEP> removed.
<tb> Rule <SEP> 1 <SEP> e <SEP> CR <SEP> <SEP> remains in the <SEP> memory, <SEP> if <SEP> the <SEP> sign <SEP> of the <SEP> data < SEP> is negative <SEP>;

   <SEP> becomes <SEP> in
<tb> a <SEP> space <SEP> converted, <SEP> if <SEP> the <SEP> sign <SEP> is positive <SEP>. <SEP> Can <SEP> in
<tb> Main part <SEP> of the <SEP> control word <SEP> are used <SEP>, <SEP> without <SEP> that <SEP> it <SEP> is subject to the <SEP> sign control <SEP>.
<tb> Rule <SEP> 1 <SEP> f <SEP> - <SEP> As <SEP> for <SEP> CR.
<tb> Rule <SEP> 1 <SEP> g <SEP> & <SEP> If <SEP> forms a <SEP> empty <SEP> space, <SEP> can be used <SEP> multiple times <SEP>.
<tb> Rule <SEP> 1 <SEP> h <SEP> * <SEP> If <SEP> is reproduced, <SEP> where <SEP> it <SEP> was written <SEP>;

   <SEP> can be used <SEP> simply <SEP> or <SEP> multiple <SEP> <SEP>, <SEP> to <SEP> to display the <SEP> class <SEP> of a <SEP> sum <SEP> <SEP> or
<tb> individually <SEP> a <SEP> protective star filling <SEP> to initiate, <SEP> where <SEP> it <SEP> then <SEP> like <SEP> a <SEP> 0
<tb> works.
<tb> Rule <SEP> 1 <SEP> i <SEP> $ <SEP> If <SEP> is reproduced, <SEP> where <SEP> it <SEP> was written <SEP>, <SEP> can <SEP> den <SEP> change location <SEP>,
<tb> if <SEP> it <SEP> was entered <SEP> in the <SEP> main part <SEP> of the <SEP> control word <SEP>.
<tb> Rule <SEP> 2 <SEP> - <SEP> With <SEP> editing <SEP> <SEP> the <SEP> sensing <SEP> after <SEP> forwards <SEP> only <SEP> from <SEP > the <SEP> B <SEP> word mark <SEP>,

  stopped.
<tb> Rule <SEP> 3 <SEP> - <SEP> After <SEP> the <SEP> last <SEP> A field character <SEP> has been transmitted <SEP>, <SEP> becomes <SEP> the <SEP> in
<tb> control word <SEP> remaining <SEP> punctuation <SEP> not <SEP> reproduced, <SEP> to <SEP> their
<tb> Place <SEP>, <SEP> blank positions <SEP> are created.
<tb> Rule <SEP> 4 <SEP> - <SEP> Every <SEP> not <SEP> under <SEP> Rule <SEP> 1 <SEP> listed <SEP> characters <SEP> can <SEP> in <SEP > the <SEP> control word
<tb> entered <SEP> are <SEP> and <SEP> <SEP> is unconditionally <SEP> inserted.
<tb> Rule <SEP> 5 <SEP> - <SEP> The <SEP> symbols <SEP> CR <SEP> and <SEP> - <SEP> are replaced by <SEP> with <SEP> spaces <SEP>, < SEP> if <SEP> that
<tb> A field <SEP> is positive <SEP>.

   <SEP> If <SEP> without <SEP> consideration <SEP> on <SEP> the <SEP> sign <SEP> CR <SEP> and
<tb> - <SEP> are required <SEP>, <SEP> then <SEP> should <SEP> the <SEP> sign <SEP> in <SEP> of the <SEP> unit position <SEP> des
<tb> A field <SEP> must be forced <SEP>.
<tb> Rule <SEP> 6 <SEP> - <SEP> If <SEP> inn. <SEP> control word <SEP> a <SEP> zero <SEP> entered <SEP> <SEP> is, <SEP> <SEP> is automatically inserted <SEP> a <SEP> word mark <SEP>, <SEP> if <SEP> this <SEP> position <SEP> is sensed first <SEP>
<tb> will. <SEP> After <SEP> determination <SEP> the <SEP> B-field word marking <SEP> <SEP> becomes the <SEP> sensing
<tb> vice versa, <SEP> where <SEP> zeros <SEP> and <SEP> punctuation <SEP> changed to <SEP> spaces <SEP>
<tb> be.

   <SEP> If <SEP> a <SEP> significant <SEP> digit <SEP> is sensed <SEP>, <SEP> ends <SEP> the <SEP> suppression <SEP> of <SEP> zero <SEP> and <SEP> punctuation <SEP> and <SEP> a <SEP> unchanged <SEP> re-formation <SEP>! Begins. <SEP> Every <SEP> character, <SEP> which <SEP> is not a <SEP> punctuation mark <SEP>, <SEP> it updates <SEP> the <SEP> zero suppression <SEP> again, <SEP> to <SEP > the <SEP> next <SEP> significant <SEP> digit
<tb> is sensed <SEP>.

   <SEP> This <SEP> action <SEP> can be <SEP> repeated <SEP>, <SEP> it <SEP> ends <SEP> however,
<tb> if <SEP> the <SEP> <SEP> automatically inserted <SEP> word mark <SEP> is sensed <SEP>.
<tb> Rule <SEP> 7 <SEP> - <SEP> A field data, <SEP> which <SEP> was not <SEP> transmitted <SEP>, <SEP> before <SEP> the <SEP> B Word mark
<tb> is sensed <SEP>, <SEP> appear <SEP> not <SEP> in <SEP> the <SEP> edited <SEP> data. <SEP> The <SEP> A field <SEP> can
<tb> less, <SEP> should <SEP> but <SEP> not <SEP> contain more <SEP> positions <SEP> than <SEP> the <SEP> sum <SEP> of
<tb> spaces <SEP> and <SEP> zeros <SEP> in. <SEP> control word.

           In protective star replenishment, in retrograde sensing, after the dollar sign has been replaced in the control word, the zeros that were inserted in the forward sensing are replaced with stars so that the dollar sign appears first, then the stars and then the amount. This is therefore similar to zero suppression except that asterisk padding is used. The floating dollar sign is not used with the asterisk padding, as it would be necessary to bring the dollar sign into close proximity to the most significant digit, which is not necessary with the asterisk padding.



  The apparatus of the present invention controls the data processing system shown generally in Fig. 1 by providing for elimination of A-rounds, except when a signal is transmitted that specifically an A-round should be taken. A further control is provided in order to be able to transmit the data in the A register through the AND circuits 43, controlled by the inhibit gates.



  When the editing device controls the machine, all decisions as to whether the information is to be accommodated in the edited part of the control word are based on the B cycle. At this point in time, the data in the B register 23 are transferred back to the edited part of the control word from which they were taken, or the data in register 24 are transferred to the same address or a different character determined by the editing control inserted at this address.



  2a shows a series of AND circuits 49-57 for some of the usual digit combinations; they supply, as shown, the special digits which are shown as preparatory AND circuits 56 and 59-71 . The AND circuits 56 and 59-71 serve to: sense the digits in the B register 23, while the AND circuit 12 is used to sense a sign in the A register 25.



  In Fig. 2c, the controls that require an A cycle are shown on line 52, which is actuated by a circuit 73 to inverter 75 (Fig. 2b), which in turn is connected to the editing line from the operation decryption register, line 77 , connected is.

   As a result, during an editing operation, the A circulation line, which is normally connected to the circulation control and generates A circulation alternately with B circulation, is rendered ineffective, and the machine makes B rotations one after the other until a circuit 34, Fig. 2e, which is ver with an OR circuit Fig. 2b connected, any dollar signs, zeros or space displays on lines 86, 54 or 28 couples. In other words, this prevents the machine in its normal operation and only provides normal operation when the control is positive.

      AND gates 94 and 96 are controlled by means to be described below. They allow data stored in the A register 25 to be transmitted through the AND circuits and, controlled by the inhibit gate, to be transmitted back to the memory location at the B address.



  In FIG. 2e, line 151 is the editing line for regeneration. This line is connected to a circuit to be described below, in which a signal placed in the line indicates that the machine should generate a check bit C.



  The first stars, which designate the classes of the sums, must be inserted in the edited part of the B control word. The circuit shown in FIG. 2 has no way of sensing this information, which is brought out of the control word during a B cycle, so that it is automatically returned to the place from which it originated and a further B cycle is carried out .

   If there is a sign bit in the ones position of the data word, the AND circuit 12 recognizes that the fact @ e that the minus means; and the inverter 14 is not prepared. The line 24, FIG. 2e, to the AND circuit 149 is not prepared, the regeneration print edition does not take effect, the C and R characters are not changed and are again accommodated in the edited part of the control word.



  In the various steps that take place, the first significant step is the one where, at step no. 8, the space in the control word is sensed by the AND circuit 56, FIG. 2a. This signal is transmitted through the OR circuit 58, FIG. 2b, to the AND circuits 94 and 96 and prepares a branch therefrom. At the same time, as shown, the signal is passed through AND circuit 87 to the other branch of AND circuits 94 and 96 with a timing pulse.

   The outputs of AND gates 94 and 96 drive the inhibit gate 45, FIG. 1, and open gate 43, causing the character then in the A register, which is the 6 shown in step # 6, to be displayed at The edited part of the control word can be accommodated in the main memory position 294. On the line 28, the signal was recognized as a blank, in other words, as an insignificant digit at the point of the zero line 54, as mentioned earlier.

   Furthermore, the signal on line 28 goes through OR circuit 89 to the body lock, which consists of AND circuit 88 and P circuit 90, and which is set and indicates that the device is now in the body of the control word. When the main body locks 88 and 90 are turned on, the monostable multivibrator 93, which is capacitively connected to the input line, is energized and blocks the AND circuit 96, which is normally set to ON, in order to prevent any sign bit contained in the number in the A register is printed with the number 6.

   The AND circuit 96 controls the zone part and the AND circuit 94 controls the digit part. The sign is saved as a zone bit, which, together with the number 6, forms an alphabetic character. To prevent this new character from being printed, it is necessary to disable the zone transfer.

   The monostable multivibrator 93 is only switched on as long as it is necessary for the transfer from the A register, and then it prepares the AND circuit 96 so that any alphabetic characters that appear thereafter are newly formed and can be put into main memory.

   The main part, which is characterized by the fact that it activates the main part lock, is the part of the control word that is intended to work with the data word, in contrast to the part of the control word that is used to determine the signs, sums and spaces.



  In cycles 10 and 11, the new data from data word number 4 is brought into the A register, and in cycle 12, which is a B cycle, the period is passed on to the B register. In the editing control there is no circuit that recognizes a period at this time, so that the period is newly formed and returned to the memory at storage location 292 in accordance with the rules established in the operation of the system.

   At step # 13 a zero is placed in the B register and sensed by circuit 56, FIG. 2a, and through lines 54 to OR circuit 89 and through AND circuit 32 to the B circuit 34 transmitted so that an A circulation is generated that brings down the 4 standing in the A register.

   At the same time, the signal through the OR circuit 56 is connected to the AND circuit 60, one of its branches with the output of the AND circuit 87 and the other branch is connected to the output of the inverter 62, which is the Fact indicates that a zero elimination latch 72 has not been set.

   The AND circuit 60 conducts a signal to the interlock consisting of the AND circuit 64 and the circuit 66, and the latter sends a signal to the AND circuit 68 so that at the beginning of the next cycle the zero elimination Latch 72 and 70 is set. At the same time, the output of the AND circuit 60 is coupled to a line 62, which means that the word mark is set, which is the special bit which, together with a character, indicates a special case.

   In the present special case, the word mark indicates the point at which the zero suppression is to be ended in the event of a backward sensing.



  It should be noted here that the word mark can be set and the zero suppression lock can be activated using an asterisk, which is placed in the main part of the control word, or a dollar sign or a zero. Each of these indicates that a different operation should be performed. The star line from the detection circuit 97, Fig. 2d, is ver via the line 95 with the OR circuit 89 connected.



  In switching step no. 19, the comma is placed in the B register, there is no device for recognizing a comma in the edition circuit while the main part lock is switched on, so the comma is returned to the B storage location 288. The comma Detection circuit 59, FIG. 2a, serves a purpose to be described below.



  In switching step 23 the data character zero contained a word mark. The A-field word mark means that this is the end of the data word to be edited. At this time, the A word mark sensed from the A register is connected to a line 101 and to an AND circuit 84.

   The character from the data word provided with a word mark is retained in the A register until a control word digit to be accommodated in the B register appears either as a space, as a zero, as a dollar sign or as an asterisk, and then the OR circuit 89 prepares the other branch of the AND circuit 84 before.

   The output of circuit 84 causes capacitor 85 to charge so that at the end of the sensing of the zero or space character, a monostable multivibrator acts as a trigger and resets main body locks 88 and 90.

   It should be noted that the character that determined that the main part lock was switched off, of course, also acted as a trigger on gates 94 and 96, which ensures that the character in the A register is transferred to the edited part of the control word, before the main body lock is switched off. This is achieved by allowing the monostable multivibrator 86 to operate when the AND circuit 84 is switched off.



  If the body lock goes out, the detection of the dollar sign does not affect the A field because gates 94 and 96 are no longer prepared by the body lock. In cases where the control word is much longer than the data word, unnecessary punctuation, such as commas, is omitted by the following method.

   The AND circuit 150 is connected to edit, not body, not backward sensing, and the detection of an A wordmark that appeared on line 152 so that if a comma appears after the body lock is turned off, the regeneration line appears , Druck, Edieren, No. 151 had the effect that blanks were inserted instead of the special digit of the control word that was then sensed. This prevents the edited word from having commas beyond the left border of the data field.



  Simultaneously with the sensing of the dollar sign, the B-field word mark was sensed and actuated line 112, Figure 2e. At the same time, the B-recirculation line has a high voltage level and the output from inverter 108 indicates that there is no command-execution change from the output of AND circuit 138 and the lines connected to it.

   This last circuit indicates that the zero elimination latch or some other feature has been set, and we must again address the MAR and return the last control word character to the B register. The output on line 110 from AND gate 104 goes to wrapper control and commands the machine to re-address to the memory location at B address 284 and bring the dollar sign back into the B register.

    The word mark contained in the dollar sign was removed by the AND circuit 142 (FIG. 2e), which senses the B word mark on line 112 and the B circulation on line 103. The editing is carried out in such a way that a signal is sent from: the AND circuit 142 to the inverter 140 and to the inhibit circuit, and the word mark is removed.



  The sensing then continues backward and each successive B address is incremented by 1 so that the next character is taken from memory and through the B register. At step # 27, the sensing circuit 56 senses a zero in the B register. This comes into the OR circuit 105 and is sent via the line 178 to the AND circuit 114, FIG. 2e.

   Since we are on a zero elimination operation, we found a zero, there is a back sensing, line 158, and the decimal lock has not set, line 162, then a space is recreated and stored in memory on Place the 0 housed.

   When the circuit was reversed, AND circuit 170 recognized signals on lines 107, 109 and the signal-edit-execute which sets delay latch 172, 174 for return sensing which continues, and provides signals indicating that something is going on besides the forward sensing that was first initiated. Line 109 is the reverse sensing interlock signal from the orbit control while the signal on line 107 is the timing signal.



  The commas or zeros that appear when the partially edited control word is sensed again are sensed by circuit 114 and spaces are inserted until the significant digit is reached as identified by line 111, which is passed through the OR circuit 180 causes the signal to be removed from AND circuit 72 and a zero suppression latch 70, 72 is switched off. This zero suppression latch was set in the cycle following that in which the zero was found in the control word during the forward sense.

   The following cycle dealt with the setting on the basis of the timing pulse on line 113 and the AND circuit 68 so that any conflict between the setting word mark and the zero suppression circuits is avoided.



  The machine runs through successive B revolutions until the word mark is sensed in switching step no. 33 on the line 112 of the AND circuit 142 together with the execution E on the line 74 and the B circulation line 103 for the butt decimal lock, the is connected to the inverter 124. Inverter 124 is not actuated so there is a signal on line 162 and a signal is on line 108 which is not the dollar lock.

    The AND circuit 138 sends an output to 123 to the circulation control and gives this the character to initiate a new instruction circulation, to remove the next instruction and to continue with the program. At this point in time, the word mark is released via the inverter 140.



  If an asterisk had been placed in the main part of the control word in any place other than the first blank position, the following conditions would have occurred. The circuit 97, Fig.2d, senses the various data for a star when the main subline of the AND circuit 88 has a high voltage level and sets the star lock, which consists of the AND circuit 125 and the sequence circuit 127 be.

   Guard star padding is similar to zero suppression in that the zero suppression interlock is set in a similar manner and causes the machine to re-address and reverse sense the digits in the partially edited control word, and use AND circuit 129 to delay interlock for reverse sensing on 176 and sense the zero suppression latch on line 133 to generate a signal star pad,

   wel ches will be described in the following in connection with FIG. At the same time, AND circuit 114 senses punctuation and zeros and provides a signal on line 151. In accordance with the circuit to be described, the asterisk padding generates the characters that are necessary to display an asterisk only if a signal is present on the new formation editing line 151 so that stars are inserted in place of spaces, that are left for the zeros that are in the partially edited word in the B location.

   The star padding works in the same way as the zero suppression by using the single zero, in such a way that when the significant digit occurs on line 115 the output of the OR circuit 180 drops and the AND circuit 72 of the zero suppression interlock is switched off and no more star filling takes place. The circuit 91 recognizes the dollar sign and sets the latch 102 and 100 through the circuit 98 a. Inverter 104 indicates on line 108 and AND gate 138 that a dollar lock has been set and no command / execution change occurs.

   With the AND circuit 104, the editing line 16, the B-circulation line 20 and the B-word mark line 112 are connected with no I / E change from a signal from the inverter 108, with which a readdressing is caused on the line 110 after the partially edited word has been sensed, and we reach the word mark inserted by the $ symbol, which probably appeared in the original control word at address 291.

   On the second forward sense, when the first space is sensed through line 139, AND gate 142 generates a signal on 123 indicating the toggle command-execution, and the device cycles of commands.

   At the same time, the right word mark lock is determined by the AND circuit 141, this acts through the P circuit 143 and the AND circuit 145 and causes the necessary bits to be recorded at the inhibit switches so that the dollar sign is stored in the memory the place of the blank is given. This has the same meaning as the protective star insertion operation, and the dollar sign is inserted in the first space position detected.



  With the decimal point elimination, zeros to the right of the decimal point are removed if there are no significant digits in the decimal part of the data word; the symbol for zero suppression is in the position of the least significant digit of the data word, i.e. two positions to the right of the decimal point.

   If, during backward sensing, the decimal point is sensed by an AND circuit 116 and provides an output from there, the AND circuit 118, which senses that a backward sensing delay is currently taking place, sends a signal to lock the decimal out of the AND circuits 120 and 122 which work to remind us that we have sensed a decimal point. The lock is reset by resetting the zero suppression lock 70, 72, which - as will be remembered - results from the occurrence of a significant digit.

   Then a significant digit appears before the last decimal place in the partially edited word, the decimal lock is turned off, and we finish the operation. The AND circuit 114, which senses zeros for elimination purposes, has a line 162 which indicates that no decimal lock is set, if the lock is set then the zero sense is not recreated as a blank, but is converted into the Word inserted until the time we determine that zeros are not necessary. This happens even though the zero suppression lock is still on, see line 160 from the lock itself.

   If the decimal lock is reset, then. If the line 160 indicates that no decimal locking is switched on, the AND circuit 138, FIG. 2e, conducts and indicates on line 123 that a change instruction execution is to take place, and the process is terminated.

   If no E-change and the decimal locking are set, the re-addressing line 110 is prepared by the AND circuit 104 in accordance with the lines indicated thereon. The B word mark 112 indicates the fact that when passing through the B register, a word mark was sensed, indicating that we must turn around and walk backwards if the other conditions are met.

   With the new addressing, the decimal locking is switched off by the signal from the AND circuit 128 by the inverter 126 at time T00-T30. The signal for word mark right comes from a lock in the circulation control, which was set by the word mark just sensed.

   When forward sensing again with the backward sensing delay lock still on, AND gate 114 continues to sense zero and punctuation and cause spaces to be inserted for each zero and the field to remain blank. The decimal display on line 116 for the second sensing is connected in FIG. 2d to FIG. 2a in the OR circuit 105, which couples the information to the AND circuit 114 so that the decimal point is replaced by a space, as in FIG happened to the zeros.

   After the decimal point has been sensed during the backward sensing, the AND circuit 132, which senses the decimal point, is still switched on, and the word mark input, which indicated that we have been at a reverse sensing and have set a locking circuit in the Wrap-around control, when we received a word mark indicator in backward sensing indicated by line 135, generates a signal on line 123 indicating an I / E change and terminating the operation.



  In some applications it is desirable to indicate the credit symbol CR for a negative value, to the left of the edited word. This is done by the latch circuit 144, 147, Fig. 2d, which is connected by the line 146 to the output of the AND circuit 12, Fig. 2a, which stores the sign of the units position of the data word and it for the test by the Has CR circuits ready,

      when these symbols are sensed to the left of the control word.



  In FIG. 8, the line 131 for star filling and the line 201 for the floating dollar sign are routed to the AND circuits 205-207. If there is a signal on the editing line 151, the correct signal is generated and the results are stored in the memory 11. Line 203 represents the C-bit line and generates one or no C-bit for the star or dollar sign and also provides a space - a C-bit if there is no signal on lines 131 or 201.

 

Claims (1)

PATENT CLAIM Data processing system according to the patent claim of the main patent, characterized in that an edition device (41) contained in the linking network (41, 43, 45, 47, 49) links the two, two registers (23, 25) character-wise removable words controls in such a way that in each case either the character of a so-called format control word stored in the first register (23) or, if spaces or certain control characters occur in the format control word, which is stored in the second register (25) stored characters of a data word to be prepared for printing is transferred back to the memory (11). SUBClaims 1. Data processing system according to the patent claim, characterized in that when a certain control character occurs in the control word format, the character transferred from the data word to this point is marked so that the word formed in the memory at the original location of the format control word is again in reverse order is read out, and that all zeros and punctuation marks up to the first non-zero digit, but at most up to the marked character, are replaced by spaces. 2. Data processing system according to the patent claim, characterized in that when a certain character occurs in the format control word, the character taken over from the data word is marked so that the word formed in the memory at the original location of the format control word is reversed again is read out, and that all zeros and punctuation marks up to the first digit other than zero, but at most up to the marked character, are replaced by protective symbols. 3. Data processing system according to dependent claim 1, characterized in that a currency symbol is used in the spaces next to the first non-zero digit or next to the marked character. 4th Data processing system according to claim, characterized in that a minus or CR character occurring in the format control word is only accepted if the data word is marked as negative. 5. Data processing system according to dependent claim 1, characterized in that zeros and inter punctuation marks up to the decimal point (separator between units and tenths) are replaced by spaces. 6th Data processing system according to dependent claim 5, characterized in that in a third readout carried out in the original direction, all remaining zeros and the decimal point are replaced by spaces if the word formed does not contain any digits other than zero.