NL8502998A - DATA PROCESSING SYSTEM. - Google Patents

Description

* ί 853113 / ΑΑ

Short designation: Data processing system.

The invention relates to a data processing system, in particular intended for use in the storage and retrieval (extraction) of data from a data set, such as a database.

5 As a result of the development of computers with large memory capacity and fast operation, more and more information is being stored in databases in data processing systems. However, the effectiveness of databases is limited by the ability of a user, skilled or unskilled, to store and / or search data in the database.

In general, data processing systems may be arranged to operate in two modes under the influence of an appropriate control means.

15 In a first operating mode, the data processing system is set to operate automatically. In automatic operation, the controller can directly operate the data processing system forward, according to a set of command instructions, and at least partially backward.

In a second mode of operation, the data processing system is arranged to operate manually. In manual operation, a user can operate the data processing system forward or backward with the control means in accordance with a set of command instructions.

However, in manual control, the user cannot easily execute the data processing system from a recursive command instruction.

In such situations, the user must step through each expression of the recursive control instructions or derive the data processing system from the command of the control means. For example, when a recursive command instruction specifies a thousand returns, the user in manual mode must cycle through all a thousand returns to pass through the command instruction. to go. This means that in order to go through a recursive command instruction £ 2 the user must command the control, through all its returns, and out of command at the end of the last return.

The invention provides a data processing system which is forward and backward controllable in accordance with a command instruction means, under the guidance of an instruction means, and in and out of recursive command instructions from the command instruction means.

To this end, the invention provides a data processing system 10 for data storage and data retrieval characterized by a central processing unit, a memory means, an input / output means and a control system, which are coupled under the control of a bus control unit by a system bus, the memory means first storage means 15 including a number of instructions for use in an instruction means for directing the operation of the data processing system and a second storage means with, in use, a number of instructions for use in a command instruction means, the operating system providing intermediate processing 20 for the instruction means and the command instruction means to the rest of the data processing system, the command instruction means controlling the data processing system under the direction of the instruction means, the instruction means generating and allocating pointers for each of the instructions in the command instructions the pointers are representative of the location of the previous and subsequent instructions relative to an actual instruction, the pointers comprising a first pointer representative of the location of a next instruction nested in the current instruction, a second pointer , which is representative of the location of a next instruction that is at the same nest level and within a nest of instructions as of the current instruction, a third pointer, which is representative of the location of a previous instruction, which nest the current instruction and a fourth pointer, representative of the location of a previous instruction, nesting at the same nest level and within an instruction nest as of the current one; 3 is instruction, the system being manually controllable by a manual control means and / or automatic controllable by an automatic control means.

The invention also provides a method for controlling a data processing system in relation to data storage and data retrieval characterized by accepting a number of command instructions for a command instruction means from an input / output unit and storing it in a second storage means led by an instruction means with a number of instructions, which are stored in a first storage means, via a system bus under the control of a bus controller and interconnected by means of an operating system, generating and assigning 15 pointers to each instruction of the command instruction means, wherein the pointers are representative of the location of previous and subsequent instructions relative to an actual instruction, the pointers comprising a first pointer, representative of the location of a next instruction, which is in the command instruction is nested, a second pointer representative of the location of a next instruction that is at the same nest level and within the same nest instructions as of the current instruction, a third pointer, which is representative of the location of a previous instruction, which nest the current instruction, and a fourth pointer, which is representative of the location of a previous instruction, which is at the same nesting level as the current instruction and within the same nesting instructions as the current instruction, and storing the pointers in a row, the method using a manual controller is manually controllable and / or is automatically controllable by means of an automatic control means for following a desired processing direction.

The invention is elucidated on the basis of the drawing. In the drawing shows: j u * · 4

Figure 1 shows a diagram of an apparatus containing the data processing system according to the invention;

Figure 2 is a table for textual command instructions;

Figure 3 shows a table of pointers corresponding to the table of figure 2;

Figure 4 shows a flow chart for manual control for the data processing system according to the invention; and

Figure 5 is a flow chart for automatic control for the data processing system according to the invention.

Figure 1 shows a device 8 comprising the data processing system according to the invention and which is suitable for carrying out the method according to the invention.

The device 8 comprises a central processing unit (CPU) 9a, which is electrically in communication with a system bus 9b. The bus 9b also provides electrical communication between a memory means 9c, an input / output (1/0) means 9d, a bus control unit 9e and a control system 9f.

The memory means 9c comprises a first storage means and a second storage means, each of which has stored therein a number of instructions temporarily or permanently. The instructions in the first storage means and the second storage means are for use in an instruction means and a command instruction means of the data processing system according to the invention, respectively. The command instruction means is provided for controlling the data processing system under the direction of the instruction means. The nature of the command instruction means and its control over the data processing system can be changed by the user of the data processing system by changing the instructions in the second storage means.

The instructions in the first storage means are instructions corresponding to commands used to provide a manual control method (shown in Figure 4) and an automatic control method (shown in Figure 5) for the data processing system under the guidance of the instruction means.

The second storage means comprises a number of instructions% Λ 5 for use in the command instruction means, which relate to method commands, which are independent of and directed by the device and the method according to the invention.

The memory means 9c also comprises a third storage means with data to be accessed and processed therein. The data relates to data on which the method according to the invention, as explained below, can act. For example, the sets of data can relate to data in a database.

The number of command instructions in the second storage means relates to a method of equipment of the device and the method according to the invention, as desired by the user for accessing and / or processing data in the memory means 9c, such as data in the third storage medium.

The instruction means and the command instruction means are coupled to the rest of the device 8 by means of the control system 9f.

The I / O means 9d includes units to enable input and output of instructions and data into and out of the device 8. In particular, the I / O means 9d may include video display units, printers, automatic ordering systems, disc driving systems, etc. (not shown). Data and command instructions are fed by a user into the I / O means 9d and passed to the rest of the device 8.

The transport of data and instruction commands is guided and controlled in the device 8 over the bus 9b by means of the bus control unit 9e. For example, the bus control unit 9e can give exclusive use of the bus 9b to the I / O means 9d. Such exclusive use may be permitted to a disk drive system of the I / O means 9d to allow it to store and / or read data from the memory means 9c under the influence of a direct memory access control unit (DMA) ( not shown).

The control system 9f of the device 9 is also required to couple the method of the invention with the rest of the device 8. The operating system 9f additionally provides instruction and data format changes suitable to enable the instructions of the memory means 9c applicable to a variety of CPUs 9a, I / O means 9d and bus controllers 9e.

The device and method of the invention is particularly intended for use with the UNIX operating system developed by AT and T Bell Laboratories (trade name), although it can also be adapted for other operating systems.

Figure 2 shows, by way of example, a table of textual instructions 10, comprising a number of lines of text 12. The text lines 12, in use, are text instructions for use in the command instruction means and may include nested instructions which are processed in a recursive manner Should be 15. A nested statement is an instruction whose operation depends on a previous statement called the nest. The nesting statement is processed as soon as the nested statement is processed through all its returns. The nested recursive instruction is processed between each processing of the nesting recursive instructions until the nesting recursive instruction is also fully processed.

For the present example, a nested verb line 12 is a verb line 12, occurring one or more spaces 25 from the margin than a preceding verb line 12. Thus, a verb line 12 can be converted by a user of the device 8 from a nested nested verb line 12 by adding or removing one or more spaces at the beginning of the verb line 12.

The table of textual instructions 10 has been generated by a user of the data processing system according to the invention. For example, the text lines 12 are fed into the device via a video display unit of the I / O means 9d. In Figure 2, the verb lines 12 are shown on a screen 13a 35 of a video display unit and each verb line 12 has a verb line number 13b. Each verb line number 13b is a pointer to each corresponding verb line * * 7 12. The verb lines 12 are transferred from the 1/0 means 9d over the bus 9b under the control of the bus control unit 9e to the memory means 9c and may be subject to requirements of the rest of the establishment 8.

5 For the instruction table 10 in Figure 2, nested verb lines 12 are processed to the end, before nested nested verb lines 12. For example, the verb lines with numbers 3, 4, and 5 are nested in the verb line 2 and each of them is processed to the end whenever the work-10 word line 2 is being processed.

Processing of nested verb lines 12 in the data processing system according to the invention can be compared to nested DO loops in the programming language FORTRAN IV. In such a comparison, each verb line 12 can be interpreted as a DO loop. Also, each verb line 12 can be understood as a micro-instruction with definitions regarding its return. Preferably, the verb lines 12 are formed from components as set forth and described in the claims of Australian Patent Application 7965, also filed by the applicant on the priority date of the present patent application.

Figure 3 shows a table of pointers, which is conveniently referred to as a sign table ("token table") 14. The sign table 14 comprises a number of pointers indicating the relative location 25 of a current textual instruction or verb line 12 with preceding and subsequent textual instructions or verb lines 12.

The pointers are defined for each command instruction line written by the user and stored in the memory means 9c. The pointers are constituted by the instruction means and correspond to command components, connection components and parameter components of the command instructions, as explained and mentioned in the claims of the patent application filed therewith. The pointers 35 also provide a representation of the properties of the connection components and the parameter components of the command instruction.

*% 8

The pointers include a first pointer 16, which is conveniently referred to as IN pointer 16. The IN pointer 16 represents the location of a subsequent verb line 12 nested in current verb line 12. For example, in figure 2 the verb line 1 is nested in the verb line 2. In the corresponding drawing table 14 of figure 3, the verb line 1 is an IN pointer 16 equal to 2. The IN pointer 16 is present as data input in the memory means 9c and is generated by the instruction means. The 10 IN pointer 16, during use, represents to the CPU 9a a way to proceed from verb line 1 to verb line 2.

Similarly, verb line 2 is nested in the verb lines 3, 4 and 5. In the drawing table 14, which corresponds to the table 15 textual instructions 10 (figure 2), the verb line 2 has an IN pointer 16, which is equal to 3. A corresponding data input is formed by the instruction means and stored in the memory means 9c. The IN pointer represents a processing path for the CPU 9a to verb line 20 3 from verb line 2.

Thus, the IN pointer 16 leads the command instruction means from an actual verb line 12 to a nested verb line 12.

The pointers also include a second pointer 18, which is conveniently half-marked with FORWARD pointer 18. The FORWARD pointer 18 represents the location of a succeeding verb line 12, which is at the same nest level and within the same nest of verb lines 12 as the actual verb line 12. For example, verb line 3 is followed by verb line 4, which is a nested nested line 12. In the drawing table 14, the verb line 3 has a FORWARD pointer 18 equal to 4. The FORWARD pointer 18 represents the CPU 9a of a way to proceed from verb line 3 to verb line 4. Corres-35 pondering data input is formed by the instruction means and is stored in the memory means 9c. Since verb line 4 is not nested in verb line 3, there is no IN pointer 16 for verb line 3. In such cases, the

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* * 9 relevant pointer and data entry in the second storage means set to zero or any other inactive value, for example -1.

Similarly, verb line 4 is immediately followed by 5 verb line 5, which is a nested nested verb line 12. The verb line 4 has a FORWARD pointer 18 equal to 5 and an IN pointer 16 equal to zero. The FORWARD pointer 18 represents a processing path from the CPU 9a to verb line 5 from verb line 4.

The comparison of the IN pointer 16, for verb line 4, to zero, indicates that no verb line 12 is nested in verb line 4. That is, there is no IN pointer for verb line 4. A similar case exists for verb lines 5, 6 and 7 for the example of Figure 15-2.

The hands also include a third pointer 20, which is conveniently referred to as an OUT pointer 20. The OUT pointer 20 represents the location of a preceding verb line 12 nested in the current verb line 12. For example, in Figure 2, verb line 2 is nested by verb line 1. In the corresponding drawing table 14, verb line 2 has an OUT pointer 20 equal to 1.

A corresponding data entry is constituted by the instruction means and stored in the memory means 9c. The OUT 25 pointer 20 has a representation of a path to the CPU 9a to proceed from verb line 2 to verb line 1.

Likewise, the verb lines 3, 4 and 5 have OUT hands 20, equal to 2, indicating a path from each of the verb lines 3, 4 and 5 to verb line 2.

The verb lines 1 and 7 of the example of Figure 2 have no nesting verb lines and thus have OUT pointers 20 equal to an inactive value, such as zero, with corresponding data input generated in the memory means 9c.

The hands also include a fourth pointer, which is conveniently referred to as BACK pointer 22. The BACK pointer 22 represents the location of a preceding verb line 12, which is at the same nesting level and within the same nest of verb lines 12 is like the actual verb line 12.

For example, verb line 6 is preceded by the non-nesting verb line 2 and in the drawing table 14 has a BACK pointer 22 equal to 2. The BACK pointer 22 has a corresponding data input generated by the instruction means and stored in the memory means 9c. is.

The BACK pointer 22 indicates a path from verb line 6 to verb line 2 for the device 8 under the control of the command instruction means.

Similarly, verb line 7 has a BACK pointer 22 equal to 1, indicating a path from verb line 7 to verb line 1. The verb lines 1, 2 and 3 of the example of Figure 2 have no preceding non-nesting verb lines, so that their corresponding BACK pointers 22 are set to an inactive value, such as zero.

The hands 16, 18, 20 and 22 are used in a manual operation according to the invention and the hands 16, 18 and 20 are used in an automatic process according to the invention to monitor the operation of the device 8 in accordance with the command instruction means to drive under the guidance of the means of instruction.

Each of the pointers is associated with an initiation command. The IN pointer 16 is associated with an IN command, the FORWARD pointer 18 with a FORWARD command, the OUT pointer 30 20 with an OUT command, and the BACK pointer 22 with a BACK command.

The initiation commands are accessed, during use, by a user of the device 8 in the I / O means 9d, interpreted by the operating system 9f and directed by the CPU 9a and the instruction means to track the operation given is indicated by a relevant pointer 16, 18, 20 or 22 for a current verb line 12 of the command J h * 11 do-means of instruction.

For example, an IN command given in the manual operation for a verb line 2 of the table of text instructions 10 shown in Figure 2 would direct the CPU 9a via the relevant 5 IN pointer 16 (equal to 3) to verb line 3. One can imagine that the initiation commands can be given by any letter key or control functions of a keyboard of the I / O means 9d or via a bat controller or light pen or the like.

The manually operated process follows a processing sequence, shown in the flow chart of Figure 4, guided by the instruction means. The flowchart includes processing blocks with reference numerals 30 to 68. CPU 9a is held in a non-operating state in processing block 30. In the state, CPU 9a is cleared for requests from peripherals such as I / O resource 9d , to serve. When an initiation command is detected by the CPU 9a from a keyboard of the I / O means 9d, the control system 9f interprets the initiation command and presents it to the instruction means. The instruction means causes the CPU 9a to perform checks to determine whether the above commands were given.

Blocks 32 to 38 allow the CPU 9a to test for an IN command, a FORWARD command, an OUT command, and a BACK command, respectively.

The test involves comparing the given initiation command with the four initiation commands. In blocks 32, 34, 36 and 38, the given initiation command is compared with the IN command, the FORWARD command, the OUT command 30 and, respectively, and in this order the BACK command.

When the CPU 9a in block 32 determines that the given initiation command is not an IN command, control is passed to block 34. Similarly, block 34 of CPU 9a determines whether the given initiation command 35 is a FORWARD command if not, it transfers control of the data processing system to block 36, and similarly to block 38.

The test is only carried out until the given instruction command is recognized. For example, if an IN command was given, the test of block 32 would recognize the command and no further command recognition tests would be made. The recognized command is checked for validity 5 before the command is processed. As explained above, it is not correct to edit some of the commands on certain verb lines 12 in the text table 10. Blocks 40 to 46, which correspond to blocks 32 to 38, respectively, check that the relevant pointers 16, 1018, 20 or 22 of the drawing table 14 represent a valid pointer. For convenience, an invalid pointer is set to zero (or -1) and blocks 40 through 46 perform tests to determine if the recognized command is associated with a pointer equal to a positive number (or 15 negative number ) unequal zero. The recognized command may only be processed if the command is a valid command for the verb line 12 for which the instruction command has been given. That is, if there is no valid pointer for the given command on the actual verb-20 line 12, the command is not processed.

For example, an IN command given on verbal line 4 of the textual instruction table 1 of FIG. 2 will be recognized as such a command, but will not be processed, since the IN pointer 16 is made equal to zero.

When the relevant pointer is a valid pointer, the respective blocks 48 through 54 direct the instruction means to direct the CPU 9a to execute the command. Block 48 directs CPU 9a through operating system 9f to execute the IN command, and similarly blocks 50, 52 and 54 direct CPU 9a to process FORWARD, OUT and BACK commands, respectively.

When executing a command, the CPU 9a is guided by the manual process according to the invention for processing the table instructions 10, which are stored in the second storage means in accordance with the pointer 16, 18, 20 and 22 of the drawing table 14 guided command instruction means. When operation 13 of a given command is terminated by one of blocks 48 through 54, control is returned to block 30 for further awaiting initiation commands from the user of device 8.

When no command is recognized or no valid command is received, the process passes control to block 56. Block 56 is arranged to indicate that an error has occurred. For convenience, block 56 generates an error message to indicate the nature of the error. The error message is transferred to the I / O means 9d via the bus 9b under the direction of the CPU 9a and the bus control unit 9e, and can be displayed on a video display or printer if necessary. The control is then returned to block 30 to await further initialization commands.

Figure 4 also shows a sub-flow diagram, which is connected to the main flow diagram by dashed lines. The substream diagram provides control for directing the processing of the data processing system to advance n terms forward or backward from an actual verb line 12. That is, if the actual verb line 12 is a recursive verb line 12, such as, for example, a FORTRAN IV DO loop, commands can be given to direct the CPU 9a forward or backward, as the case may be, through the expressions of the recursive verb line 12. To cycle through the expressions of a recursive verb line 12, which relates to data in a data file in the third storage medium of the memory means, the CPU 9a increments or decrements a memory address pointing to memory locations in the third storage means.

In this way, the CPU 9a can forward or backward a number of records in a data file.

Such control allows a user to browse the data cords of a data file in accordance with the command command means control and subject to the manual control process.

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Commands, which are conveniently referred to as FORWARD n RECORDS and BACKWARD n RECORDS, may be given by an operator through the l / 0 means 9d to instruct the CPU 9a to cycle through the expressions of a recursive verb line 125 sniffing data records from a data file. The commands cause the CPU 9a to exit the control of block 30 and continue with the recognition tests.

Blocks 58 and 60 provide further recognition tests and will recognize a FORWARD n RECORDS and a BACKWARD 10 n RECORDS initiation command, respectively.

Blocks 62 and 64 test whether the initiation command is valid for the actual verb line 12.

Blocks 62 and 64 determine that an initiation command is invalid if it requests records that do not exist in the records approximated by the actual verb line 12 or if the actual verb line 12 is not of a recursive type.

For example, a BACK n RECORDS command, where the actual verb line 12 points to a first record of a data file in the third storage medium, will not be allowed.

When the command is valid, blocks 66 and 68 direct the CPU 9a through the operating system 9f to move the n records forward or backward through the records approximated by the actual verb line 12. When the ne record is entered, control is returned to block 30.

When no command has been recognized or validly tested, control proceeds to error block 56 and then to command input block 30, as explained above.

Under manual control, as explained above, there are six command types to accomplish six process control modes, hereinafter referred to as hexadirectional control.

The automatic process follows an operating sequence shown in the flow chart of Figure 5. The flowchart includes operating blocks 80 through 96.

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The automatic process follows a control path defined by the command instruction means and is described by pointers 16, 18, 20 and 22 of the character table 14, which are present when data is entered into the memory means 9c and are subject to the guidance of the instrument.

Once the operation of the table instructions 10 has been instructed by the operator, the CPU 9a comes under the control of the block 80 and is guided by the instruction means.

The block 30 leads the CPU 9a to work out the current verb line 12 only once.

The elaboration proceeds to a first test stage in block 82. The first stage includes testing whether there are any data records left to be examined in a file 15 of the third storage medium in which the actual verb line 12 operates. A flag is used to indicate whether there are any records left that should be considered by the actual verb line 12. The flag is conveniently referred to as end-of-date EOD flag. It is conceivable that, while data remains to be taken into account, the EOD flag is not set and when no data is left to be taken into account, the EOD flag is set.

When more data is to be taken into account by the actual verb line 12, the CPU 9a is passed through the block 80 to rework the verb line 12. The verb line 12 is worked out recursively, until the end of the data (EOD) is detected and the EOD flag is set. Block 82 then directs CPU 9a to test the validity of pointers 16, 18 and 20 to determine the further course of the process of the invention as controlled by the command instruction means.

In the present embodiment of the invention, it is desirable to construct nested verb lines 12 in a similar manner to nested DO loops in FORTRAN IV. To achieve this, the block 84 directs the CPU 9a through the operating system 9f to test the IN pointer 16, first corresponding to the actual verb line 12.

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Therefore, when a nested verb line 12 is present, it must be fully processed before the next expression of the actual verb line 12 is worked out. For example, verb line 2 of the text table 10 of Figure 5 2. In addition, a group of nested verb lines 12 is treated in the same way as a single nested verb line 12. If no valid IN pointer 16 is present, block 86 leads the instruction means to the, via the operating system 9f, directing the CPU 9a to test the FORWARD pointer 18 10 for the current verb line 12.

Similarly, the block 88 directs the CPU 9a through the operating system 9f to test the validity of the OUT pointer 20 when there are no valid IN or FORWARD pointers 16 or 18 for the current verb line 12.

As seen in the example of Figure 2, an OUT pointer 20 is required to perform processing from a nested set of verb lines 12.

Blocks 90 to 94 direct the CPU 9a to execute the command corresponding to a valid pointer 16, 18 and 20, respectively. Once the command has been completed, in accordance with the drawing table 14 under the guidance of the instruction means control of device 8 is returned to block 80.

If all of these tests in blocks 84 through 88 25 do not give a valid pointer 16, 18 or 20 for the current verb line 12, block 96 recognizes an incorrect situation and therefore warns the user by giving an error warning. Once the error warning is given, block 96 directs CPU 9a to fully work out a verb line 30 under control of block 80 and the automatic process of the invention continues. The automatic control process can be interrupted by the elaboration of an interrupt command means. The interruption can be provided by an operator of the device 8 via the I / O-35 means 9c. The interrupt command means allows the user to interrupt the automatic process and bring the operation of the data processing system into line with the manual process. The interrupt command means can also be used to switch from manual processing to automatic processing.

The pointers stored in the drawing table 14 are preferably removed from the memory means 9c by the instruction means as soon as the processing from processing to termination is completed under the control of the command instruction means.

10 Any, and one or more of the hands can be turned off or blocked on any desired verb line 12.

The blocking of the pointer on a verb line 12 may be guided by the instruction means to invalidate the pointer on that verb line 12. A command corresponding to the blocked pointer cannot be processed for that particular verb line 12.

A pointer can be turned off by negating (denying) the corresponding data entry in the memory means 9c for the relevant verb line 12 or verb lines 12. The validity tests explained above will then prove invalid for that verb line 12.

The pointer lock can be associated with a user access code to the data processing system, so that the user's ability to work with all or part of the process or to view all or part of the data in the data processing system depends on a his / her access code provides security level.

In Australian patent application 7965, simultaneously filed by applicant, entitled "Improvements in / or relating to data processing systems", a data processing system for data storage and data extraction is explained and described in the claims thereof, comprising a system bus, a bus control unit, a memory means, a control system, a central processing unit (CPU) and an input / output means, the system bus being arranged to provide electrical communication between the components 18 of the bus control unit and the control system device, the memory means being implemented with a first storage means containing a number of instructions for use in an instruction means for directing the operation of the data processing system and a second storage means containing, during use, a number of command instructions for use in a command instruction means for the control one of the operation of the data processing system, wherein the control system provides an intermediate processing between the instruction means and the command instruction means and the rest of the data processing system, the command instruction means controlling the data processing system under the direction of the instruction means, and the input / output means intended is for input of data into the device and output of data from the device, wherein the command instructions comprise command components and connection components, each of the command components and each of the connection components having one or more parameter components, the command components operating controlling the device, subject to one or more parameter components, related by one or more of the connection components, such that the structure of the command instruction is independent of the order of the parameter components and their corresponding connection components.

In Australian patent application 7965, simultaneously filed by applicant, entitled "Improvements in / or relating to data processing systems", a data processing system for data storage and data extraction is explained and discussed in the claims, comprising a system bus, a bus control unit, a memory means, a control system, a central processing unit (CPU), an input / output means, wherein the system bus is arranged to provide electrical communication between the components of the device, subject to the bus control unit and subject to the control system, the control means being executed with a first storage containing a number of instructions for use in an instruction means for directing the * '"*. · ··' *» vp 1/19 operation of the data processing system and a second storage means containing, during use, a number of command instructions for use in a means of instruction vo or controlling the operation of the data processing system, the control system providing an interface between the instruction means and the command instruction means and the rest of the system, the command instruction means controlling the data processing system under the direction of the instruction means, and the input / output means is intended for input of data into the device and for output of data from the device, the memory means also comprises a third storage means containing a number of data storage means, wherein the data storage means means raw data storage means, first data definition storage means and second data storage means. definition storage means.

The entire description of this other concurrently filed patent application is to be construed as being incorporated herein. Changes obvious to a person skilled in the art are considered to be within the scope of the invention. For example, the drawing table 20 14 could be dynamically rather than statically generated, so that the device 8 determines the relevant pointers as the process continues without stocking all the pointers with respect to the stock of command instructions issued by the user. generated and present in the second storage medium.

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Claims (19)

Data processing system for data storage and data retrieval characterized by a central processing unit, a memory means, an input / output means and a control system, which are coupled under the control of a bus control unit by a system bus, the memory means a first storage means having a number of instructions for use in an instruction means for directing the operation of the data processing system and a second storage means with, in use, a number of instructions for use in a command instruction means, the operating system providing intermediate processing for the instruction means and the command instruction means to the rest of the data processing system, wherein the command instruction means controls the data processing system under the direction of the instruction means, generates and assigns the instruction means pointers for each of the instructions in the command instruction means, the pointers are representative for the location of the preceding and following instructions relative to an actual instruction, the pointers comprising a first pointer representative of the location of a next instruction nested in the current instruction, a second pointer representative of the location of a next instruction which is at the same nest level and within a nest of instructions as of the current instruction, a third pointer, which is representative of the location of a previous instruction, which nest the current instruction and a fourth pointer, which is representative of the location of a previous instruction, which is at the same nest level and within an instruction nest as of the current instruction, the system being manually controllable by hand control means and / or automatic controllable by means of an automatic control means. Data processing system according to claim 1, characterized in that the instruction means comprises a means for allowing the control of the control of the operation of the data processing system under the control of the command instruction means, such that by the command instruction means a current instruction entered data recorders can be tapped forwards or backwards. Data processing system according to claim 1 or 2, characterized in that it can be manually controlled by means of the manual control means 5 in accordance with the command instruction means and is subject to one or more pointers. Data processing system according to claim 1 or 2, characterized in that it is automatically controllable by means of the automatic control means in accordance with the command instruction means and is subject to one or more of the first, second and third pointers. Data processing system according to any one of the preceding claims, characterized in that the memory means comprises a third storage means, which can contain data to be accessed (entered) and to be processed. 6. Data processing system according to any one of the preceding claims, characterized in that the command instruction means comprises textual command instructions stored in the second storage means and generated by a user of the data processing system via the input / output means. A data processing system according to any one of the preceding claims, characterized in that the command instruction means 25 comprises implied textual command instructions stored in the second storage means and generated in response to instructions accessed in the data processing system by a user through the input / output means with respect to inquiries generated by the instruction means. 8. A data processing system according to claim 6, characterized in that the textual command instructions in the second storage means allow manual control by means of the hand control means and / or automatic control by means of the automatic control means of the data processing system to provide a desired line. of processing for accessing and processing data from the memory means. "V 9. A data processing system according to claim 7, characterized in that the implied textual command instructions allow manual control by means of the manual control or automatic control by means of the automatic control means of the data processing system to follow a desired processing direction for accessing and processing. of data in the memory means. 10. A data processing system according to any one of claims 5, 6 or 8, characterized in that the command instructions in the second storage means have a physical location on a display of the input / output means, so that a textual instruction following the actual textual instruction nested in the actual textual instruction, offset from the actual textual instruction and represented by the first pointer, a textual instruction following the actual textual instruction and at the same nest level and within a nest of textual instructions as of the actual textual instruction is located immediately below the actual textual instruction and is represented by the second pointer, a textual instruction which precedes the actual textual instruction and which the actual textual instruction nest is positioned in such a way that the up-to-date textual instruction appears to have been generated from this and suggested is counted by the third pointer and a textual instruction, which precedes the current textual instruction and which is at the same nest level and within a nest of textual instructions as of the current textual instruction, is located immediately above the actual textual instructions and is presented by 30 the fourth hand. 11. A data processing system according to any one of the preceding claims, characterized by a means for allowing interrupting the operation of the system for switching the control from the manual control means to the automatic control means. 12. A data processing system as claimed in any one of the preceding claims, characterized by a means for allowing interrupting the operation of the system for switching control from the automatic control system to the manual control means. 13. Method for controlling a data processing system 5 in relation to data storage and data retrieval characterized by accepting a number of command instructions for a command instruction means from an input / output unit and storage thereof in a second storage means under the direction of an instruction means having a plurality of instructions stored in a first storage means, via a system bus under the control of a bus controller and coupled through an operating system, generating and assigning pointers to each instruction of the command instruction means, the pointers representative of the location of previous and subsequent instructions relative to an actual instruction, the pointers comprising a first pointer representative of the location of a subsequent instruction nested in the command instruction, a second pointer, which is representative of the location 20 of a next instr uction which is at the same nest level and within the same nest instructions as of the current instruction, a third pointer representative of the location of a previous instruction, which nest the current instruction, and a fourth pointer representative of the location of a previous instruction, which is at the same nesting level as the current instruction and within the same nesting instructions as the current instruction, and storing the hands in a row, the method being manually controllable by means of a manual controller and / or is automatically controllable by means of an automatic control means for following a desired processing direction. Method according to claim 13, characterized by manual control by means of the manual control means according to the command instruction means and subjected to one or more of the pointers. 15. Method according to claim 13, characterized by the automatic control by means of the automatic control means in accordance with the command instruction means and subjected to one or more of the first, second and third pointers. 16. A method according to any one of the preceding claims, characterized by storing data in a third storage means, wherein the data can be accessed and processed by means of the command instruction means under the direction of the instruction means. Method according to any one of claims 13 to 16, characterized in that a user executes a number of textual command instructions via the input / output means in the second storage means to direct the control of the instruction means. Method according to any one of claims 13 to 16, characterized in that a user creates a number of implied textual command instructions in the second storage means via the input / output means, selected from a number of implied textual commands given by the instruction means. instructions. 19. Method according to claim 16 or 17, characterized in that a user enters textual command instructions in the input / output means, wherein the textual command instructions are physically located on a display means of the input / output means such that a textual instruction, which follows the actual textual instruction and which is nested in the actual textual instruction generated from the actual textual instruction and is represented by the first pointer, a textual instruction that follows the actual textual instruction, which is at the same nest level and within the same nest of textual instructions is as of the actual textual instruction, is located immediately below the actual textual instruction and is represented by the second pointer, a textual instruction which precedes the actual textual instruction and which sets the current textual instruction nest becomes that the current text • - * ·. fa, ♦ · * »it appears that the actual instruction is generated and is represented by the third hand, and a textual instruction, which precedes the actual textual instruction and which is at the same nest level and within the same nest of 5 textual instructions as of the current textual instruction is located immediately above the current textual instruction and is represented by the fourth pointer. 4 A r »'V 4.-' ·