JPH07129393A - Method and device for preparing program and method and device for preparing printing image data - Google Patents

Abstract

PURPOSE:To prepare an errorless printing image having sure printing positions, printing contents, etc., by including sequence number processing for allocating continuous numbers in each prescribed data unit in specified edition processing. CONSTITUTION:When transaction data (A) are outputted as they are, the data (A) are printed out (B) without allocating sequence numbers to the data (A). When 'sequence number processing' by specified edition processing in a main program is applied to the data (A), data with sequence numbers are outputted (C). Thereby even when sequence numbers are not recorded in the original transaction data, sequence numbers corresponding to respective sheets of output paper are printed out on the output paper in accordance with specified edition. In the case of printing out plural documents on a sheet of output paper by multi-layout, a sequence number is printed out in each document. Consequently the data number of printing image data can be judged only by checking the printed paper.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for creating print image data by inputting a data string to be printed on an output sheet such as a form into a printer and editing it in a format that can be output on the output sheet. Regarding

[0002]

2. Description of the Related Art Conventionally, when a predetermined data is printed on an output paper such as a pre-printed product or a blank paper having a predetermined form to prepare an invoice or a monthly report, first, a customer list, sales amount, etc. The data to be printed on the output paper is extracted from the master file, which is a separate data file for each, and is combined into a record that is a unit of data (corresponding to the data described on one invoice), and the specified number of records Just collect and create a file commonly known as a transaction file. Next, for each data of the record written in this transaction file, determine the print position according to the format to be printed on the output paper, add line feeds, blanks, etc. according to the printer to be used, and print image data ( A PIT (also called a print image tape), which is called a PID because a magnetic tape is usually used as a recording medium, is created. Then, it is general to set the PID and the output paper to be output in the printer to perform the printing process.

For example, a case will be described as an example in which a bill is created on an output sheet of a predetermined form. FIG. 34 is a diagram showing the processing steps in the case of creating an invoice on the output paper of a predetermined form. In FIG. 34, first, predetermined data is extracted for each customer from the customer database in which the address, name, etc. of the customer to whom the invoice is to be sent are recorded, and the transaction database in which the transaction details and the billing amount are recorded. Then, a transaction file is created by collecting the records into records and collecting records corresponding to all predetermined customers (STEP 1).

Next, the print position of each data forming the record is determined according to the output paper to be printed, and a PID is created in accordance with the print output image including a line feed code, a blank code, etc. (STEP 2). And PI
When an output sheet for outputting D is set in the printer and printer output processing is performed, a bill in which predetermined data is printed at a predetermined position can be created (STEP 3).

The PID creating process will be described below. Fig. 35
FIG. 4 is a diagram showing one record written in a transaction file. As shown in FIG. 35, it is assumed to be composed of three fields. Here, one record is composed of data printed on one output sheet. Further, a field indicates an area in which data is written, and one data is written in one field. Then, records of the configuration shown in FIG. 35 are written in the transaction file for the number of output processing cases. The order of the fields forming the record may be arranged independently of the form of the output paper.

Further, FIG. 36 is a diagram showing specifications relating to a printing position and the like when printing is performed on an output sheet. These transaction data are supposed to be printed on the output paper of a predetermined form as shown in FIG. That is, the data “name” recorded in the field 1 is the 11th in the 5th line.
The data "address" printed in the second to tenth digits and recorded in the field 2 is printed in the first to tenth digits in the second line, and the data "billing amount" recorded in the field 3 is the fifth.
It should be printed in columns 31-35 of the line. Note that the output paper portion is omitted in FIG. The number of digits is a value in the case where 1-byte data such as alphanumeric characters is expressed. Therefore, in 2-byte data such as Japanese, one character is expressed by 2 digits.

In such a case, it is clear that simply setting the transaction data and the output paper on the printer will not print the respective data at the correct positions where they should be printed, and each data should be printed on the output paper. In order to print correctly at the position, it is necessary to change the format of the transaction data record to the data format shown in FIG. FIG. 37 is an example of PID. FIG. 37
According to the data format shown in, the printer reads one record, first page breaks, and then takes in the next output sheet. The first line is a line feed, the second line is the first 10 digits, and the 11th digit is blank. Print the contents of the field 2 "address" in the 40th to 40th columns and start a line feed. Then, after the 3rd and 4th lines are fed back, the 5th line is blanked in the first 10 columns. Print the contents of field 1 "Name" in the 20th digit, leave the following 10 digits blank, and
The contents of field 3 "billing amount" are printed at the 1st to 35th digits and a line feed is performed. This series of data strings is lined up for the number of output processing cases. The Kanji IN code in FIG. 37 is a code indicating that the following data is data of one character and two bytes, and the Kanji OUT code is a code indicating the end of data of one character and two bytes.

As described above, the transaction data as shown in FIG. 35 is converted into the data shown in FIG.
The PID creation process changes the format to that shown in 7 so that the printer can interpret it and print each data at the position where it should be printed.
Is created.

[0009]

However, in the conventional PID creating process, a program in a programming language such as C language or COBOL is created each time in consideration of the print format of the output product and the specifications of each printer to be used. However, this program development was extremely time-consuming and costly. In addition, since these created PID creation programs could only be used uniquely within each model, it is virtually impossible to operate on a different model or a lower model even if the number of processes is small. It was

Further, in the printout work, when a defect occurs during the post-processing, it is customary to search from the sequence number assigned to each form and print again. is there. In the case where the sequence number is output in such a case, and when the sequence number is included in the transaction data, the position to output the sequence number is determined by a normal program. On the other hand, if it is not included in the transaction data,
In order to output the serial number, a counter process must be provided on the program, and the program must be created to output the value of the integrated result to the designated position.

Further, a plurality of logical pages are provided on one page such as a pre-printed matter or a blank sheet, and a unique number is sequentially printed on each logical page to manage the number of sheets and process control. May be used. In this case, in order to print a unique number for each logical page in programming, the number must be counted in logical page units,
It is necessary to create a PID conversion program so that it is printed at a predetermined position and with a predetermined size. Therefore, a very troublesome work of newly adding only this extremely complicated part to a normal program is required.

Further, in the contract processing, the transaction data presented by the customer may not have a code having a data attribute according to the specifications stored therein, but may have defective data. If the above PID conversion processing is performed on such transaction data, defective data exists in the PID, and a print output error occurs due to a defective code. Therefore, it takes a lot of time to find the defective part of the cord, and the output efficiency is lowered.

The present invention is intended to solve the above-mentioned problems, and it is possible to perform editing including sequence number processing when it is desired to output a sequence number that is not included in transaction data, without performing the complicated work of creating a program. It is an object of the present invention to provide a method and an apparatus that enable anyone to easily create a print image with a reliable print position, print content, etc. on an output paper without any error.

[0014]

The above object can be achieved by the present invention described below. That is, (Claim 1) For a printer that prints out transaction data on a print sheet based on a specified edit process for specifying a character pattern and a print position in a screen interactive method, and transaction data based on information obtained by the specified edit process. A program creation method for automatically generating a print image data conversion program for automatically generating a print image data conversion program for converting to print image data, wherein the designated editing process is a sequential number for each predetermined data unit. A method for creating a program, which includes a sequence number process for adding (Claim 2) A print image data conversion process for converting the transaction data into print image data by the print image data conversion program generated by the print image data conversion program automatic generation process according to claim 1. And how to create print image data. (Claim 3) A character image of transaction data, a designated edit process for designating a print position in a screen interactive mode, and a print image for a printer for printing out transaction data on output paper based on the information obtained by the designated edit process. A print image data creating method including a print image data converting process for converting into data, wherein the designated editing process includes a sequence number process for giving a continuous number to each predetermined data unit. Image data creation method. (Claim 4) Based on the transaction data, other characters to be output on the output paper, a character pattern such as a mark, and a print position and a designated editing means designated by the screen interactive method, and information obtained by the designated editing means. A program creation device having a print image data conversion program automatic generation means for automatically generating a print image data conversion program for converting to print image data for a printer for printing on output paper, wherein the designated editing means is A program creating apparatus comprising sequence number giving means for giving consecutive numbers to each predetermined data unit. (Claim 5) Print image data converting means for converting the transaction data into print image data by the print image data converting program generated by the program creating apparatus according to claim 4. Creation device. (Claim 6) A character image and a print position of the transaction data are designated and designated by a screen interactive method, and a printer for printing the transaction data on an output sheet based on the information obtained by the designated and edited means. A print image data creating apparatus comprising print image data converting means for converting into image data, wherein the designated editing means includes a sequence number giving means for giving consecutive numbers for each predetermined data unit. Print image data creating device.

[0015]

Since the transaction data is converted into the print image data based on the transaction data, the character pattern, and the print position designated by the screen interactive method, it is not necessary to manually create a program for each different transaction data. Further, since the program for converting the transaction data into the print image data is automatically generated, it is possible to perform time-consuming data conversion by a device different from the device for automatically generating the check program. Further, since a continuous number is given to each predetermined data unit, the number of print image data can be known only by looking at the printed output paper.

[0016]

The present invention will be described below based on the preferred embodiments. FIG. 1 is a diagram showing an example of a system configuration for implementing a PID creating method and apparatus according to the present invention. In FIG. 1, reference numeral 1 is a control device including an arithmetic processing unit such as a microprocessor and peripheral circuits, that is, a main body such as a personal computer or an engineering workstation, 2 is an input device such as a keyboard or mouse, and 3 is a color CRT display device. Such as a display device, 4 a floppy disk storage device (referred to as an FD device), 5 a magnetic tape storage device (referred to as an MT device), 6 a storage device capable of storing a large amount of data such as a hard disk, and 7 a printer. , 8 are networks, and a local area network (called LAN) such as Ethernet can be used.

FIG. 2 is a diagram illustrating a record of transaction data, FIG. 3 is a diagram illustrating a print layout, and FIG. 4 is a diagram illustrating data of one cycle of PID. Next, an outline of the PID creating method and apparatus of the present invention will be described by taking the case of creating the PID of FIG. 4 from the transaction data of FIG. 2 in the print layout of FIG. 3 as an example.

FIG. 5 is a flow chart showing the overall processing executed by the control device 1. When the start-up process of the main program after power-on is completed, the control device 1 displays the main menu on the display device 3 ( S1). There are 3 main menus: "specified editing process", "business process", and "end".
It is a menu. Here, the designated edit processing menu is a menu for performing edit processing such as management information related to printout work, input of specifications of the transaction data MT, creation of a new external character, printout position, and the like. That is, the specifications of the data exemplified in FIGS. 2 and 3 are input to enter the PI.
This is a menu for creating a data file required for automatic generation of a D conversion program. Then, the business processing menu checks transaction data and automatically generates a code conversion program, and the PI as illustrated in FIG. 4 is based on the specifications defined in the designated editing processing menu.
This is a menu mainly for creating D. The end menu is a menu for ending the main program.

With the main menu displayed,
When one of the main menus is selected by placing a pointing point on the menu and pressing a key on the keyboard, a button of a mouse or the like (S2), the selected subprogram is launched (S3 to S5). As an example, when the business process menu is selected (S2), the business process starts (S2).
4), the sub menu is displayed on the display device 3. The submenus are three menus of "PID formation", "backup / registration", and "business ID (identity) confirmation".

As described above, the PID formation menu is a menu for creating a PID by generating a check and code conversion program and a PID conversion program based on the data file created by the designated edit processing menu. The backup / registration menu is the PI of the present invention.
D When the MT device 4 is used to download various data files that are used or created by the creating method and device to the MT, or when the data downloaded to the MT is taken into the hard disk storage device 6. It is a menu used for. The business ID confirmation menu is a menu used when confirming whether or not a corresponding ID exists. When one of these menus is selected (S7), the subprogram of that menu is launched (S8-S1).
0) Processing is performed. Next, the details of the PID creation method and apparatus of the present invention described above will be described in "designated editing process"
D formation ”and“ backup / registration ”will be described in this order.

(Designated Editing Process) FIG. 6 is a flowchart showing the designated editing process in the designated editing process (S3) of FIG. First, the operator inputs the business ID (S2
1). Then, the system determines whether or not the corresponding ID is registered (S22). Here, the system includes the hardware configuration of the system illustrated in FIG. 1 and FIG.
The software configuration of the system illustrated in (1) and peripheral related systems (not shown) are included. FIG. 6 is a flow chart showing a designated editing process when the corresponding ID is not registered. The case where the ID is registered will be described later with reference to FIG.

If the corresponding ID is not registered in FIG. 6, management information is input (S23). FIG. 8 is a diagram showing a management information input screen displayed on the display device 3. In FIG. 8, the “registration date” is the date when the PID was created in the consignment processing business. The "order number" is for displaying the preprint data of the form block making CAD on the screen based on this number. "Business ID" is
It is a number that manages the system data file. The "creator" is the person who created the PID in the system. If there is "pre-print data", the ruled lines (characters) are drawn on the X window based on the data of the form work sheet CAD. If not, the screen of the pre-print section is not displayed and the screen is displayed. Displays the spacing chart. However, in either case, the form size and the number of pitches per inch are input. "Printer model" sets the printer model corresponding to the PID created by the system. Further, when the creator, the registrant, etc. are changed, the change history is added. The above management information data is input by the operator from the keyboard, mouse, etc. while looking at the screen of FIG.

When the management information is input (S23) in FIG. 6, transaction data MT specifications are input (S24). FIG. 9 is a diagram showing an input screen for the transaction data MT specifications displayed on the display device 3. In FIG. 9, "label designation" is performed by selecting NL or SL. NL means non-label,
SL means a standard label. Select "single" or "multi" for "volume configuration". Single means that MT has one volume, and multi means that MT has multiple volumes. Therefore, if you select multi, enter the "number of turns".

"1 byte code" means ASCII, EBC
Select either DIC or nothing. ASCII, EBC
DIC means that the character codes specified by 1 byte are ASCII code and EBCDIC code, respectively. No means that there is no 1-byte code character. "2-byte code" is JEF, IBM, J
Select one of IPS-E, JIPS-J, shift JIS, and nothing. These mean that the code of the character specified by 2 bytes is each code.
For “external character code”, select “yes” or “no” depending on the presence or absence of the external character code. If there is an external character code, create an external character code correspondence table with an editor. FIG. 10 is an input screen of the editor displayed on the display device 3. The above-mentioned transaction data MT specification data is input by the operator from the keyboard, mouse or the like while looking at the screens of FIGS.

In FIG. 6, transaction data MT
After the specification input (S24) is completed, the presence / absence of the external character font is next determined (S25). If the external character font is present, a new external character font is created (S26) and then the record field data specification input (S27) is performed. If there is no external character font, the process directly proceeds to S27. FIG. 11 is a view showing an input screen for new external character font creation (S26) displayed on the display 3. In FIG. 11, the filled portion in the large frame represents the shape of the external character font, and the shape can be input from the keyboard, mouse or the like while looking at the screen of FIG. Further, it is possible to search and use a desired external character font from existing font data, external character data of CAD for creating a form block, or to modify it to obtain a desired external character font.

In FIG. 6, a new external character font is created (S2
When 6) is completed, the data specification of the record field illustrated in FIG. 2 is input (S27). FIG. 12 is a diagram showing an input screen for the data specifications of the record fields displayed on the display device 3. In FIG. 12, the “column position start point” is numerical data indicating the byte position of the record of the transaction data at which the start position of each field is, and the “attribute” is the attribute of the data. ANK (alphanumeric katakana), "P" is a type of numerical data, such as packed / unpacked type (number, input with P surrounded by square in Fig. 12), with signature (plus or minus in case of number), etc. Select one. In FIG. 12, 9 indicates that the field data is a numeral, N indicates a Japanese character (2-byte character), and X indicates that it is composed of an alphabet and a numeral. "Number of digits" indicates how many numbers, alphabets and Japanese characters are present in the field. The “field name” is the name of the field, and can be substituted for the variable name of the check program and the variable name of the PID conversion program. Although not shown in FIG. 12, a “comment” explaining each field can be added. This comment is for debugging when using the generated program for other purposes,
Make maintenance easier.

The above record field specification data is input by the operator from the keyboard, mouse or the like while looking at the screen of FIG. When "Save" in FIG. 12 is selected when the input is completed, the input record field specification data is saved in the transaction data MT specification file.

When the data specification of the record field (S27) is completed in FIG. 6, the spacing chart is displayed (S28). FIG. 13 is a diagram showing a display screen of the spacing chart displayed on the display device 3. In FIG. 13, when there is the data of the form copy making CAD, a predetermined spacing chart is displayed on the screen according to the chart classification in the data. When there is no CAD data for creating a form copy, a predetermined spacing chart given as a default is displayed on the screen. Changes are made if the defaults are determined to be inappropriate. If there is data for the form copy preparation CAD, a predetermined spacing chart is displayed on the screen, and then the ruled line frame created by the form copy preparation CAD is displayed. FIG. 14 is a diagram showing a display screen of the ruled line frame displayed on the display device 3. Further, a judgment is made as to whether or not to display the pre-printed portion characters created by the form copy making CAD. When Y is input on the display screen of FIG. 13 or 14, characters are displayed, and when N is input, characters are not displayed.

When the display of the spacing chart (S28) is completed in FIG. 6, the printout specification is next input (S29). FIG. 15 is a view showing a printout specification input screen displayed on the display device 3. Figure 15
In the upper left, the spacing chart, ruled line frame, and pre-printed portion characters are displayed in the upper left. Also in the center,
The field layout is displayed. On the right side and the lower side, a plurality of menus of operations performed on the printout specification input screen are displayed.

The above menu will be described. "letter"
Is displayed when the field layout is not displayed in the window of the display screen and is erased when the field layout is displayed in the window of the display screen by placing the mouse pointing point on this and pressing the mouse button (called hit or select) . “Paste” hits the field number to select the designated character string based on the printout specifications, determines the coordinate position, and after editing processing, hits this to determine the paste position. "Change number of points" is a menu to be specified when changing the size of pasted characters. For single-byte characters, the default is 10 cpi (character per inc
h) In the case of 2-byte characters, the default is set to 9 points (points), and when pasting at other points, hit this and select a prescribed character size.

"Hyphen edit" hits this menu when it is necessary to add "-" when outputting a zip code or sequence number. For example, 9999-99, X-99
999999 etc. For example, "△ -sama" hits this menu when a space "" is added between the name and the name, the name and the name, and the name and the name. "1B → 2B" hits this menu when converting a character set with a 1-byte code into a 2-byte code and outputting it. “Calculation” hits this menu to specify the calculation formula and the number of digits when calculating the total etc of the usage amount. "Left Alignment" selects this menu and sets the number of characters per line when you want to break the address and message text. "Flag determination" includes a flag in the transaction data, and it is determined by the flag value, and when it is desired to output different contents to the same position, this menu is hit. Create a correspondence table between flag values and field numbers or message texts.

The "fixed character string" has no data in the transaction data, but when printing out as fixed information, this menu is selected and the required character string is registered.
For example, 〒, Mr., message text, etc. "End" saves information about the contents of the printout specification when it is completed. “Pick” is for the character string once decided, and when you want to change it, select this menu and correct it. For "Cursor designation", select this menu if you want to enter the paste position using coordinate values. "Change line spacing" is selected when you want to change the number of pitches (line spacing) per inch of the displayed spacing chart. "Enlarge" selects this menu and specifies the area when enlarging the screen display of each window. "standard"
When you want to return the screen display of each window from the enlarged display to the standard display state, select this menu. "clear"
Select this menu if you want to clear (delete at all) the character string specified by the pick.

For "imposition", this menu is selected when performing multi-imposition processing (copy & paste) at the time when the printout specifications have been input for one form. After designating the copy area, the sequence is designated to determine the read record position information. "Encryption" hits this menu when you want to apply encryption processing to the character string whose paste position has been determined. “Sequence No.” selects a sequence number pattern and pastes it. Next is EXI
T? When "no" is selected in (S30), the process returns to the job ID input (S21). If yes is selected, the screen returns to the main menu display (S1) of the main program shown in FIG.

FIG. 7 is a flow chart showing the processing steps when there is a corresponding business ID in the determination (S22) of whether the business ID of FIG. 6 is registered. In this case, the designated editing process should have been completed for the time being, so the main purpose is to correct the specification or to designate the unedited portion. 7 and 6 differ in this respect,
Items without work can be skipped and skipped, and necessary work items can be selected directly, and the work can be performed immediately.
In FIG. 7, the business ID input (S21) and the presence / absence determination (S21) of the business ID are the same as those in FIG. 6, but the determination result is that the corresponding business ID exists in the system. Therefore, the specification content correction menu is displayed on the display device 3 (S31). This menu is "Management Information", "Transaction Data M
There are five types, "T specification", "new character font creation", "record field specification", and "printout specification".

When "management information" is selected while the specification content correction menu is displayed on the display device 3 (S32),
The operation can be started from the management information input (S23) in FIG. 6 (S33). "Transaction data M
When "T specification" is selected (S32), the operation can be started from the transaction data MT specification input (S24) in FIG. 6 (S34). When "New character font new creation" is selected (S32), the operation can be started from new character font new creation (S26) in FIG. 6 (S35). When "Record field specification" is selected (S32), the work can be started from the data specification input of the record field specification (S27) in FIG. 6 (S36). When "printout specification" is selected (S32), printout specification input (S
The work can be started from 29) (S37). EXIT? When no is selected in (S38), the process returns to the task ID input (S21). If yes is selected, the screen returns to the main menu display (S1) of the main program shown in FIG. This is the end of the description of the designated editing process shown in FIGS. Next, PID formation will be described.

(PID formation) FIG. 16 is a flow chart showing a conversion processing method in PID formation (S8) which is a submenu of the work processing (S4) in FIG. First, the operator inputs a work ID (S41). Then the ID
Management file corresponding to, transaction data MT
The system determines whether or not there is a specification file, a record field specification file, a fixed information file, a page information file, a printout specification file, etc. (S42). Here, the management file is created by the management information input (S23) of FIG. 6, and the transaction data MT specification file is the transaction data MT of FIG.
It is created by the specification input (S24), the record field specification file is created by the record field data specification input (S27) of FIG. 6, and the fixed information file, the page information file and the printout specification file are the printout specification input of FIG. This is the file created in (S29).

The file will be described here. For example, FIG. 19 is a diagram showing the contents of a record field specification file. Information as shown in FIG. 18 is stored as shown in FIG. FIG. 18 corresponds to the transaction data of FIG. In Figure 19, .start.: He
Record the total number of fields in number between ader and .end.: header, and .start.: header to .end.: body below it.
The information entered during each is recorded. label is a field name, which corresponds to a variable name in generating a program. comment is just a comment for the field, and input items are provided so that the contents of the field can be easily clarified when correcting. Kind indicates an attribute related to field data, and this attribute item serves as a criterion for determining whether the data code in the field is correct. start records the number of bytes at the start position of the field in each record, and depends on the number of bytes to start checking at the code check. length indicates the data length of each field. As with start, this also depends on the data length to be checked at code check.

FIG. 20 shows an example of a fixed information file, which is generated when the menu "fixed character" is selected and executed in the printout specification input (S30) of FIG. The fixed information file in Fig. 20 is .start.: Head.
The number of all fields is recorded in number between er and .end.: header, and the information entered respectively between .start.: body and .end.: body below that is recorded. constant indicates a character string set as fixed information. The character code set here is recorded with the character code supported by the printer. Therefore, when the character code used in the control device 1 and the character code supported by the printer are different, code conversion is performed. kind shows the attribute of the character string set by constant, and label becomes the variable name when generating a program. Kind and label are automatically generated from the contents set with constant, so ANK from a menu
It may be divided into two, Japanese and Japanese.
It may be generated by judging from the character code set in nt. Since the variable name must be unique for label, it is generated by combining the number of cases registered with constant with a sequential number.

FIG. 21 is an example of a page information file, and FIG. 22 is a print layout information file. This file is generated when the menu "imposition" is selected and executed in the printout specification input (S30) of FIG. 21 and 22 correspond to the print layout of FIG. FIG. 23 is a diagram showing the relationship between the actual imposition and the logical numbers set by the files of FIGS. 21 and 22. In Fig. 21, the total number is recorded in logical between .start.: Header and .end.: Header, and the information entered between .start.: Body and .end.: Body below that is Will be recorded. The identifier indicates the file name of one piece of print layout information that constitutes a logical page. unit represents the unit of the coordinate system that sets the output position, and the column, inch, and
It has a unit system of dots. x and y indicate absolute coordinates based on the unit of unit. init indicates the initial value of the logical number. step indicates the step length when moving from the current value of the logical number to the next page.

In FIG. 22, .start.: Header to .en
The total number of layouts is recorded in number up to d.:header, and the information set respectively below .start.: body to .end.: body is recorded. Now, since the number of impositions is 2, two files of print layout information of frame1 and frame2 are created. Since frame1 and frame2 are similar, only frame1 is shown here. x and y are numerical values based on the unit of unit and record the relative coordinates within each logical page. For length, record the character string length at the time of output with the number of digits. In case of line break editing, the number of characters per line is set here. The kind indicates the existence location of the original data necessary for output. Whether the original data is a transaction data file, a fixed information file, or another file is identified by this value when the PID is generated. I know where to read the data from. If it is a logical number, it is not related to these files, so it is identified by this. label is the label for the data selected when designing the printout, and it has the same contents as the label determined in the record field specification file and the fixed information file specified earlier. For logical numbers, these data do not have to exist, so "* logical *"
The item name is stored. size indicates the character size set at the time of output.

Now that the description of the file has been completed, FIG.
Returning to S41, the description of PID formation is continued. If these files do not exist, an error message is displayed on the screen of the display device 3 (S43). The file name or the like that does not exist as an error message. On the error message screen, a display for selecting whether or not to continue the PID formation is displayed. When selecting to continue, EXIT?
Since no is selected in (S54), task I
Return to D input (S41). If you select No, EXIT
? Since "yes" has been selected in (S54), the process returns to the main menu display (S1) of the main program in FIG.

If these files exist, the transaction data is read (S44). This is the "label" in the transaction data MT specification file,
Reading is performed with reference to the items "volume", "record length", "recording density", and "block length". In the case of multi-volume, the files are linked together to create a work file for checking and code conversion processing. Also, the device name for creating the PID and the printer name for outputting are selected and input. The following processing contents differ depending on this selection.

Next, a check and code conversion program is automatically generated (S45). This automatic generation is performed by using the code generator to generate a program code from the transaction data MT specification file and the record field specification file. The program generated at this time is a source program such as C language or COBOL, and when the program is executed,
Load modules can be created by compiling and linking depending on the processing device, and any device can be selected. If the data code of transaction data does not require code conversion, only the check program is automatically generated. After the check and conversion program is generated, it is determined whether the control device 1 uses the previously selected PID creation device name or PID creation is performed using another model. When outputting with another model, it is possible to transfer the check and conversion source program via a network or to output to a recording device such as an FD device or MT device. Further, in the automatic generation of the check and code conversion program (S45), the program may be automatically generated as necessary, for example, when the check or the code conversion is performed by another model. When the program is not automatically generated, It can be checked by (check processing) described later.

Next, check and code conversion processing is performed (S46). The transaction data file fetched in S44 is used as a work file, the program automatically generated in S45 is activated, and the above process (S46) is performed.
It is determined whether or not there is an error in the check (S47), and if there is an error, a code error file is created (S48). The contents of this code error file are verified, the transaction data is corrected (S49), and the transaction data is read again (S49).
Go back to 44) and try again. In the check, it is determined whether or not there is an error (S47), and if there is no error, a code-converted master data file is created (S50). The total number of bytes of print data per page of PID to be output is calculated from the printout specification file, and the code-converted master data file is divided so that the hard disk storage device 6 does not overflow when the PID data is stored. A divided master data file is used during PID conversion.

Next, a PID conversion program is automatically generated (S52). This automatic generation is based on transaction data MT specification file, record field specification file,
This is performed by generating a program code from a printout specification file, print information data, and external character font data using a code generator. The program generated at this time is, for example, C language, COBOL
When a program is executed, the load module can be compiled and linked according to the processing device to create a load module, and the device can be selected.
The character code of the PID to be output is unified according to the printer model, such as EBCDIC or JEF code. After automatically generating the PID conversion program,
From the PID creation device name selected earlier, P on this control device 1
It is determined whether the ID conversion process is performed or another model is used. When outputting to another model, it is possible to transfer the PID conversion program via the network or to output to a recording device such as an FD device or MT device. In the automatic generation of the PID conversion program (S52), the program may be automatically generated as necessary, such as when the PID conversion is performed by another model. If the program is not automatically generated, it will be described later. P
ID conversion processing).

Next, the PID conversion program automatically generated in S52 is activated to create a PID (S53). When the control device 1 performs the PID conversion processing, the PID conversion program previously generated is automatically compiled,
After linking and creating the execution module, the execution module can be executed to create the PID suitable for the output printer device. The output MT displays a page serial number range as a message for each volume. EXIT? When no is selected in (S54), the process returns to the business ID input (S41). If yes is selected, the screen returns to the main menu display (S1) of the main program shown in FIG. This is the end of the description of PID formation. Next, backup / registration will be described.

(Backup / Registration) FIG. 17 is a flowchart showing the processing steps in the backup / registration (S9) which is a submenu of the job processing (S4) in FIG. In FIG. 17, the backup and registration menus are displayed (S61) and one is selected (S62). Select Backup if you want to save the data files generated by this system, and select Register if you want to reuse the data files backed up by this system.
When backup is selected (S63), the business ID and data file name currently saved by the main program process of FIG. 5 are displayed (S64). When the business ID is selected, the data file is saved in MT (S6
5) Further, information on which data is stored in which MT is stored in the MT storage status file (S66).
EXIT? When no is selected in (S67), the display returns to the menu display (S61). If yes is selected, the main menu display (S
Return to 1).

When registration is selected (S68), the business ID to be registered is input (S69). The MT storage status file is searched (S70), and the MT in which the data file relating to the input business ID is stored is displayed (S71). The corresponding MT is set in the magnetic tape device (S72), and the data file is registered in the system side (S73). EXIT? When no is selected in (S67), the display returns to the menu display (S61). If yes is selected, the screen returns to the main menu display (S1) of the main program shown in FIG. This completes the description of backup / registration. Next, the check processing, the check program generation, the PID conversion processing, the PID conversion program generation, and the sequence number processing, which are the characteristic parts of the present invention, will be described in more detail in this order.

(Check Processing) FIG. 24 is a flow chart for explaining the transaction data check processing. In FIG. 24, first, the code name (JIS, ASCII,
JEF, IBM, etc.) is read in both 1-byte and 2-byte systems (S81). Next, the external character code value set in the transaction data is read. The external character code is normally read even if it exists outside the regular code area because it is registered in a different file, etc., and therefore is processed differently from the above code (S82). Then, the record layout for one record of the transaction data input earlier is read from the record field specification file. When the check program is not generated, it is not necessary to read the field name and comment contents (repeated by the number of fields). At this time, the total number of transactions processed and the record length are read (S83).

After reading the record layout, discrimination processing is performed based on the data type of each field (S84).
The X item indicates the entire 1-byte character, the 9 item indicates numerical data, and the N item indicates the entire 2-byte Japanese character. Next, a check (S85) is performed, and the processing process will be described by taking the X item as an example. The transaction data for the number of digits is read from the leading position of each field that has been read previously (S86), and it is determined from the input code name whether it is within the normal range of the code table for the X item (S8).
7). At this time, the code value of the read external character is not considered as a check target. When it is determined that the input code is within the normal range of the code table, the next code value is processed and repeated for the number of digits. If the input code is determined to be within the normal range of the code table, the error content is recorded (S88). For example, if the input transaction data is ASCII code 00 (H), it is determined that an error occurs because the character is not defined. At this time, the byte position in the transaction data where the error occurred, the code value 00 (H)
In the error file. Check processing is similarly performed for other data items.

(Automatic Generation of Check Program) FIG. 25 is a flow chart for explaining automatic generation of a check program of transaction data. In FIG. 25, first read the code name of transaction data,
It will be used as a judgment material for importing the check library. Further, the total number of transactions processed and the record length are read (S91). Next, the external character code value set in the transaction data is read (S9
2). Next, the record layout information regarding the first field is read. In this case, the field name (variable name) for generating the program must be read.
Comments (used for debugging, maintenance, etc.) may be read because they relate to the appearance of the source program, or may not be read if not necessary (S93,
S94). And the read field name, start position,
A program for reading the first field data is created according to the number of digits (S95). After that, the attribute of the data and the input code name are determined, and each library name describing the check range in advance is described in a program (S96). Repeat these for the number of fields,
A main function part is created (S93). Finally, for the check library, create a program control statement that uses the external character code value and excludes this value from the check.

(PID conversion process) FIG. 26 is a flow chart showing the PID conversion process. In FIG. 26, first,
The name of the output printer is read, and how to convert the PID output format is determined (S101).
Next, each parameter set in the page specification file is read and the printout specification file is processed in the following order. Next, the parameters set for the first field of the printout specification file are read. The parameters to be read here are the unit of output start coordinates, the coordinate value in the horizontal direction, the number of output digits, the character size,
Presence of input data (transaction data, fixed character string data, etc.) File identifier, field name of input data, etc. exist (S102, S103). Set the control code for the line from the name of the output printer or, in the case of a line printer, from the output start position coordinates. If it is not a line printer but a printer capable of addressing all points, it is not necessary to set the line control code (S104, S105).

Next, the character size is set (S
106). Then, it is determined whether the input data is transaction data, fixed identifier data, or a virtual label such as a serial number from the identifier related to the input data of the printout specification file. Then, from the identifier related to the input data of the printout specification file, whether the input data is transaction data,
It is determined whether the data is fixed character string data (S107). After the discrimination, the input data is read using the start position and the number of digits of the record field specification file. On this occasion,
The attribute of the record field specification file or the fixed character string data is read (S108), and the attribute is used to determine whether the input data is X, 9 items or N items (S109). By this determination, PID
When converting to, if the ANK is read, the shift code is not added to the data (S110), and the Japanese is read (S11).
In the case of 1), the shift code is added to the data (S11).
2). In the case of serial numbers, logical numbers are counted based on the parameters set in the page specification file, and output data is created based on the respective attributes. The above process is performed for each field in the printout specification file (S102, S114), and P
Output as an ID (S113).

(Automatic Generation of PID Conversion Program) FIG. 27
FIG. 7 is a flowchart showing a PID conversion program automatic generation process. In Figure 27, identi in the page specification file
Read the file name of the printout specification file that is set in fier, and incorporate the library that processes each in sequence as follows. In FIG. 27, first,
Input data (transaction data, fixed character string data, etc.) defined in the printout specification file
Field name (variable name) and the file existence identifier of the input data are read, and the variable name of the input data and the data reading unit in the PID conversion program are generated (S1).
21, S122, S123). The i-th parameter (coordinate unit, output start coordinate value, input data field name, input data file existence identifier, output digit number, character size) in the printout specification file is read (S12).
4, S125). If it is a line printer, it is necessary to generate the line control code from the coordinate values in the vertical direction.
A line control library is incorporated (S126, S127).

Next, in order to generate data for controlling the output character size, a library for converting the character size into a character size code is incorporated (S128). The file existence identifier of the input data and the attribute of the input data are determined (S129), and a library for setting the input data is incorporated (S130). At this time, if the attribute of the data to be output is Japanese, a library to which a shift code is added is also incorporated (S131). In the case of a continuous number, a logical number is counted based on the parameters set in the page specification file, and a library including the contents for creating output data based on the attributes is installed. Finally, a part for outputting the PID generated by the above process is created. This series of processing is performed for each field in the printout specification file to create the entire program (S132).

(Sequence Number Processing) In the designated editing processing (S3) of the main program of FIG. 5, in the printout specification input (S29) of the designated editing processing of FIG.
The “sequence” in the printout specification input screen display of FIG. 15 displayed on the display device 3 is an embodiment of this “sequence number processing”. FIG. 28 is a diagram showing data conversion by the sequence number processing. In FIG. 28, (A) is transaction data. If this is output as it is, it is printed out without a sequence number as in (B). When the sequence number processing is performed on this transaction data, the sequence number is added and output as shown in FIG. Sequence number processing is a data processing method in the case where the sequence number corresponding to each output sheet is printed on the output sheet according to the specified edit even when the sequence number is not recorded in the transaction data as described above. Is. In addition, when outputting multiple forms such as multiple sheets on one output sheet,
This is a data processing method when a sequence number is printed for each form.

FIG. 29 shows a state in which the preprinted portion is displayed on the screen in the printout specification input screen display of FIG. Further, FIG. 30 shows a state in which the transaction data is selected, the output position is designated, and added to the screen display. In this state, if it is desired to perform the sequence number processing, then the sequence number processing edit menu "sequence" is selected from the menu as shown in FIG. Then, a window for selecting an output pattern is displayed on the display device 3, where the output pattern is selected with a mouse or the like, the print position is further instructed, and the print position is set as shown in FIG. Further, when a plurality of forms and the like are to be output on one sheet of output paper, the print position is set for each form within one sheet of output paper. After selecting the format of the sequence number, the initial value setting menu opens, and the initial value is set there.

The output pattern has a different number of digits, for example, 3 digits "999", 4 digits "9999", 5 digits "99999", 6 digits "999999", 7 digits "999".
The number of digits before and after can be selected when a hyphen "-" is entered such as "9999" or "99-9999".

In this way, the layout for one page is determined, all the specifications relating to the printout are input and instructed, and then the process is terminated and the data file associated with the printout information is saved. FIG. 33 is a diagram showing the data recorded in the data file as a table for easy understanding. Actually, data is stored in the printout information file as shown in the example of FIG. When creating a PID with this system, the system automatically creates a source program for PID conversion from this data file, automatically compiles and links it to create an execution module (load module), and then sets it. The M
Record the PID in T. When creating in another system, after compiling and linking the source program in that system, the PID is recorded in the set MT.

When a program is generated, it is performed as follows based on the data file shown in FIGS. 19 to 22 (FIG. 22 shows actual printout specification data). First, after the code check, the transaction data code is converted into a character code that can be used by the printer used for printout. Next, a sorting process is performed on the print position of the data file in the vertical direction. A source file for PID conversion is created based on the data obtained by this sort processing, and a transaction data reading unit, an output position designating unit, and a PID output unit are created. Here, if the character string of the edit code * logical * exists in the item label in the data file that has been sorted, 9 (6)
In the item, the PID conversion program is generated so as to set the value obtained by performing the counter processing based on the output position.

Although the present invention has been described with reference to the embodiments, the present invention is not limited only to the embodiments and can be applied and implemented in various modes within the scope of the technical idea of the present invention. It goes without saying that they are also included in the present invention. For example, it is obvious that the sequence number processing of the present invention can be widely applied to other than the system described in the embodiments. Further, the transaction data check program automatic generation process and the check process of the present invention are not limited to the print image data forming process described in the embodiment, but can be applied to any print image data forming process. Further, the PID conversion program automatic generation processing and the PID conversion processing of the present invention can be carried out regardless of the presence or absence of transaction data check processing.

[0062]

As described above, according to the present invention,
Since the transaction data is converted into print image data based on the transaction data, the character pattern, and the print position specified by the screen interaction method, it is not necessary to manually create a program for each different transaction data. The operator can convert the transaction data into the print image data without depending on Further, when a program for converting transaction data into print image data is automatically generated, it is possible to perform time-consuming conversion of data with a device different from the device for automatically generating the check program. It can be performed. In addition, serial numbers are assigned to each predetermined data unit without the complicated work of creating a program, so you can see the number of print image data by just looking at the printed output paper. , If the output paper is jammed by the printer at the time of printing, it is possible to immediately know what number of data and what number of data should be reprinted, so a quick response can be taken.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a system configuration for implementing a print image data creating method and apparatus of the present invention.

FIG. 2 is a diagram exemplifying a record of transaction data.

FIG. 3 is a diagram illustrating a print layout.

FIG. 4 is a diagram illustrating a PID.

FIG. 5 is a flowchart of a main program showing an overall process executed by the control device 1.

FIG. 6 is a flow chart showing a designated edit processing method when an ID is not registered in the designated edit processing (S3) of FIG. 5;

7 is a flow chart showing a designated edit processing method when an ID is registered in the designated edit processing (S3) of FIG.

FIG. 8 is a diagram showing a management information input screen displayed on the display device 3;

9 is a diagram showing an input screen for transaction data MT specifications displayed on the display device 3. FIG.

10 is an input screen of the editor displayed on the display device 3. FIG.

FIG. 11 is a diagram showing an input screen for new external character font creation (S26) displayed on display 3;

FIG. 12 is a diagram showing an input screen for data specifications of record fields displayed on the display device 3;

13 is a diagram showing a display screen of a spacing chart displayed on the display device 3. FIG.

14 is a diagram showing a display screen of a ruled line frame displayed on the display device 3. FIG.

15 is a diagram showing a printout specification input screen displayed on the display device 3. FIG.

16 is a flowchart showing a PID formation processing method and device in PID formation (S8) which is a submenu of the work processing (S4) of FIG.

17 is a flowchart showing a processing method in backup / registration (S9) which is a submenu of the job processing (S4) in FIG.

FIG. 18 shows a table of data corresponding to the transaction data of FIG.

FIG. 19 is a diagram showing the contents of a record field specification file.

FIG. 20 is an example of a fixed information file, and the menu “fixed character” in the printout specification input (S30) of FIG.
This file is generated when is selected and executed.

FIG. 21 is a diagram showing an example of a page information file.

FIG. 22 is a diagram showing an example of a print layout information file.

23 is a diagram showing the relationship between the actual imposition and the logical numbers set by the files of FIGS. 21 and 22. FIG.

FIG. 24 is a flowchart for explaining transaction data check processing.

FIG. 25 is a flowchart showing a process of automatically generating a transaction data check program.

FIG. 26 is a flowchart showing a PID conversion process.

FIG. 27 is a flowchart showing the process of automatically generating a PID conversion program.

FIG. 28 is a diagram showing conversion of data by a sequence number conversion process.

29 shows a state in which the pre-printed portion is displayed on the screen in the printout specification input screen display of FIG.

FIG. 30 shows a state in which transaction data is selected, an output position is designated, and added to the screen display.

FIG. 31 is a diagram showing a screen of the display device 3 in which the sequence number processing edit menu “sequence” is selected.

FIG. 32 is a diagram showing a screen of the display device 3 with print positions of sequence numbers set.

FIG. 33 is a diagram showing the data recorded in the data file saved with the print-out information as a table for easy understanding.

FIG. 34 is a diagram showing a process in the case of creating a bill on output paper of a predetermined form.

FIG. 35 is a diagram showing an example of one record written in a transaction file.

FIG. 36 is a diagram showing an aspect in which transaction data should be printed on an output sheet of a predetermined form.

FIG. 37 is an example of a data format for correctly printing each piece of transaction data at a position to be printed on output paper.

[Explanation of symbols]

 1 Control Device 2 Input Device 3 Display Device 4 FD Device 5 MT Device 6 Storage Device 7 Printer 8 Network

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] February 18, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0037

[Correction method] Change

[Correction content]

The file will be described here. For example, FIG. 19 is a diagram showing the contents of a record field specification file. Information as shown in FIG. 18 is stored as shown in FIG. FIG. 18 corresponds to the transaction data of FIG. In FIG. star
t. : From header. end. : The total number of fields is recorded in the number up to the header, and the following . start: From body . end. : Body
The information entered during each is recorded. label
Is a field name and corresponds to a variable name in generating a program. The comment is just a comment for the field, and an input item is provided so that the content of the field can be easily clarified at the time of correction. kind
Indicates an attribute related to field data, and this attribute item serves as a criterion for determining whether the data code in the field is correct. start records the number of bytes at the beginning start position of the field in each record,
Depends on the number of check start bytes at code check.
The length indicates the data length of each field. This also depends on the data length to be checked at the time of code check as in the case of start.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0050

[Correction method] Change

[Correction content]

After reading the record layout, discrimination processing is performed based on the data type of each field (S84).
The X item indicates the entire 1-byte character, the 9 item indicates numerical data, and the N item indicates the entire 2-byte Japanese character. Next, a check (S85) is performed, and the processing process will be described by taking the X item as an example. The transaction data for the number of digits is read from the leading position of each field that has been read previously (S86), and it is determined from the input code name whether it is within the normal range of the code table for the X item (S8).
7). At this time, the code value of the read external character is not considered as a check target. When it is determined that the input code is within the normal range of the code table, the next code value is processed and repeated for the number of digits. If the input code is determined to be outside the normal range of the code table, the error content is recorded (S88). For example, if the input transaction data is ASCII code 00 (H), it is determined that an error occurs because the character is not defined. At this time, the byte position in the transaction data where the error occurred, the code value 00 (H)
In the error file. Check processing is similarly performed for other data items.

[Procedure 3]

[Document name to be corrected] Drawing

[Correction target item name] All drawings

[Correction method] Change

[Correction content]

[Figure 1]

[Fig. 2]

[Figure 3]

[Figure 4]

[Figure 8]

FIG. 35

[Figure 5]

[Figure 6]

[Figure 7]

[Figure 9]

FIG. 18

[Figure 10]

FIG. 11

[Fig. 12]

[Fig. 13]

FIG. 14

FIG. 17

FIG. 19

FIG. 20

FIG. 21

FIG. 22

FIG. 15

FIG. 16

FIG. 23

FIG. 25

FIG. 29

FIG. 24

FIG. 30

FIG. 31

FIG. 36

FIG. 26

FIG. 32

FIG. 37

FIG. 27

FIG. 28

FIG. 33

FIG. 34

Claims (6)

[Claims] 1. A print image for a printer that prints out transaction data on a print sheet based on information obtained by the designated edit processing for designating the character pattern and print position of the transaction data in a screen interactive mode. A program creation method for automatically generating a print image data conversion program for automatically generating a print image data conversion program for converting data, wherein the designated editing process assigns consecutive numbers to predetermined data units. A method for creating a program, which includes sequence number processing for 2. A print image data conversion process for converting the transaction data into print image data by the print image data conversion program generated by the print image data conversion program automatic generation process according to claim 1. And how to create print image data. 3. A print image for a printer, which prints out transaction data on output paper based on information obtained by the designated edit processing for designating the character pattern and print position of the transaction data in a screen interactive mode. A print image data creating method including a print image data converting process for converting into data, wherein the designated editing process includes a sequence number process for giving a continuous number to each predetermined data unit. Image data creation method. 4. A designated editing means for designating a character pattern and a printing position of transaction data by a screen interactive method, and print image data for a printer which prints out on an output paper based on the information obtained by the designated editing means. A program creating apparatus having a print image data conversion program automatic generation means for automatically generating a print image data conversion program to be converted, wherein the designated editing means gives consecutive numbers to each predetermined data unit. A program creation device comprising sequence number giving means. 5. A print image data converting means for converting the transaction data into print image data by the print image data converting program generated by the program creating apparatus according to claim 4. Creation device. 6. A print for a printer that prints out transaction data on output paper based on information obtained by the designated editing means, and designated editing means for designating the character pattern and printing position of the transaction data in a screen interactive mode. A print image data creating apparatus comprising print image data converting means for converting into image data, wherein the designated editing means includes a sequence number giving means for giving consecutive numbers for each predetermined data unit. Print image data creating device.