JP3731377B2 - Information processing apparatus and method, and recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an information processing apparatus capable of setting various functions realized by data processing, a method thereof, and a recording medium.
[0002]
[Prior art]
Generally, when a printer as a peripheral device is connected to a computer and print data created by the computer is to be printed on the printer, it is necessary to incorporate a device driver for the printer (hereinafter referred to as a printer driver) into the computer. The printer driver is a computer program that controls various printer information such as printer functions, interfaces, font information, and control codes in the computer and controls the printer, and is prepared for each printer model to be printed.
[0003]
The operator can operate the computer to start the printer driver incorporated in the computer and set various information. To perform such setting, a data input window is displayed on the display. According to the display, the keyboard and mouse are operated to input data. As a result, various information can be set in the printer driver.
[0004]
In order to make this printer driver easy to use, default conditions are prepared in advance in such a data input window so that a standard setting is automatically made even when the operator does not specify anything. . When the operator intends to perform standard printing, the default condition may be used as it is.
[0005]
[Problems to be solved by the invention]
However, in the conventional printer driver, the default condition needs to be set so that the computer operates comfortably to a certain degree whether the performance of the computer is high or low, so that only the minimum functions operate. It was always set to such a value. In recent years, as the performance of computers has improved dramatically year by year, the difference in data processing capabilities of computers to be used has become large. For this reason, those who use high-performance computers cannot use the default conditions as they are because of the default conditions that are disproportionate to the performance, and it is necessary to always reset various types of information. It was bad.
[0006]
The present invention has been made to solve the above-described problems in the prior art, and an object thereof is to exhibit excellent operability even if the performance of a computer used is different.
[0007]
[Means for solving the problems and their functions and effects]
In order to solve such a problem, the first device of the present invention is:
Data processing execution means for performing data processing for realizing a predetermined function;
Function setting for displaying a data input window on the display device, taking in an input from the input device operated according to the data input window, and setting a function realized by the data processing according to the input Means and
In an information processing apparatus comprising:
Storage means for storing in advance the default conditions of the data input window;
Capability detection means for detecting the data processing capability of the information processing device;
Default changing means for changing the default condition according to the detected data processing capacity;
It is characterized by having.
[0008]
Here, the input captured from the input device by the function setting means includes input of character data from a keyboard, input of a click operation signal by a mouse for button selection, and the like.
[0009]
According to the first apparatus configured as described above, the default condition of the data input window is changed according to the data processing capability of the information processing apparatus detected by the capability detection means. For this reason, it is possible to provide the worker with default conditions that are commensurate with the data processing capability of the information processing apparatus, and even if the data processing capability of the information processing apparatus is high, the worker maintains the default conditions as they are. Can be used. Therefore, this first apparatus has an effect that it can exhibit excellent operability regardless of the data processing capability of the information processing apparatus.
[0010]
In the information processing apparatus configured as described above, the capability detection unit may be configured to detect a data processing capability of a central processing unit provided in the information processing device.
[0011]
According to this configuration, it is possible to provide the operator with default conditions for a data input window that is commensurate with the data processing capability of the central processing unit.
[0012]
In the information processing apparatus configured as described above, the capability detection unit may be configured to detect a data transfer capability of a communication path connected to the information processing device.
[0013]
According to this configuration, the data transfer capability of the information processing device can be detected by the data transfer capability of the communication channel, and the default condition of the data input window that matches the data transfer capability of the information processing device can be determined. Can be provided to a person.
[0014]
In the information processing apparatus having the above configuration, the default changing unit may change a default value prepared in advance in a data input field included in the data input window.
[0015]
According to this configuration, by changing the default value prepared in advance in the data input field included in the data input window, it is possible to provide the operator with a default condition that is commensurate with the data processing capability of the information processing apparatus. .
[0016]
In the information processing apparatus configured as described above, the default changing unit may be configured to limit a range of functions that can be set in the data input window.
[0017]
According to this configuration, by limiting the range of functions that can be set in the data input window, it is possible to provide the operator with default conditions that are commensurate with the data processing capability of the information processing apparatus.
[0018]
In the information processing apparatus configured as described above, the default changing unit may change a display position of a data input field included in the data input window.
[0019]
According to this configuration, by changing the display position of the data input field included in the data input window, it is possible to provide the operator with default conditions that are commensurate with the data processing capability of the information processing apparatus.
[0020]
In the information processing apparatus having the above configuration, the data processing performed by the data processing execution unit may be a process according to a predetermined peripheral device driver.
[0021]
According to this configuration, a function realized by data processing is set by processing according to the device driver.
[0022]
The information processing apparatus having the above configuration may include an installation unit that copies the device driver to a storage device, and the capability detection unit detects the data processing capability at the time of installation of copying the device driver. it can.
[0023]
According to this configuration, it is possible to detect the data processing capability of the information processing apparatus when installing the device driver.
[0024]
The information processing apparatus having the above-described configuration further includes an installation unit that copies the device driver to a storage device, and the capability detection unit includes the data processing capability when the device driver is started by the data processing execution unit. It can be set as the structure which performs a detection.
[0025]
According to this configuration, the data processing capability of the information processing apparatus can be detected when the device driver is activated.
[0026]
The second device of the present invention is
Data processing execution means for performing data processing for realizing a predetermined function;
Function setting means for setting various functions realized by the data processing in response to a command from the worker while exchanging various types of information with the worker
In an information processing apparatus comprising:
A capability detecting means for detecting the data processing capability of the information processing apparatus is provided,
The function setting means includes
Algorithm setting means for setting the algorithm so that an algorithm that realizes at least one of the various functions is optimized according to the data processing ability detected by the ability detecting means.
It is characterized by having.
[0027]
According to this configuration, an algorithm that realizes at least one of various functions is optimized in accordance with the data processing capability of the information processing apparatus detected by the capability detection unit. For this reason, the operator can realize the function by an algorithm optimal for the data processing capability of the information processing device without being aware of the data processing capability of the information processing device. Therefore, the second apparatus has an effect that an optimum function can be realized with excellent operability regardless of the data processing capability of the information processing apparatus.
[0028]
In the second apparatus, the capability detection means may be configured to detect a data processing capability of a central processing unit provided in the information processing apparatus.
[0029]
According to this configuration, the function is realized by an algorithm that matches the data processing capability of the central processing unit.
[0030]
The first method of the present invention is:
(A) performing data processing for realizing a predetermined function in the information processing apparatus;
(B) Displaying a data input window on the display device, capturing an input from the input device operated according to the data input window, and setting a function realized by the data processing according to the input And the process
In an information processing method comprising:
(C) predefining default conditions for the data input window;
(D) detecting the data processing capability of the information processing apparatus;
(E) changing the default condition according to the detected data processing capability;
It is characterized by providing.
[0031]
The second method of the present invention is:
(A) performing data processing for realizing a predetermined function in the information processing apparatus;
(B) A step of setting a function realized by the data processing according to a command from the worker while exchanging various types of information with the worker.
In an information processing method comprising:
(C) including a step of detecting the data processing capability of the information processing apparatus;
The step (b)
(B1) A step of setting the algorithm so that an algorithm that realizes at least one of the various functions is optimized according to the data processing capability detected by the capability detection means.
It is characterized by having.
[0032]
According to the first or second method of the present invention, similarly to the first or second device of the present invention, it is possible to exhibit excellent operability regardless of the data processing capability of the information processing apparatus. Play.
[0033]
The first recording medium of the present invention is:
(A) a function of performing data processing for realizing a predetermined function;
(B) Displaying a data input window on the display device, capturing an input from the input device operated according to the data input window, and setting a function realized by the data processing according to the input Function to
A computer-readable recording medium recording a computer program for causing a computer to realize
The computer program further includes:
(C) a function for predetermining default conditions for the data input window;
(D) a function of detecting the data processing capability of the computer;
(E) a function of changing the default condition according to the detected data processing capacity;
Is implemented by the computer.
[0034]
The second recording medium of the present invention is
(A) a function of performing data processing for realizing a predetermined function;
(B) a function of setting various functions realized by the data processing in response to a command from the worker while exchanging various types of information with the worker;
A computer-readable recording medium recording a computer program for causing a computer to realize
The computer program further includes:
(C) Function for detecting the data processing capability of the information processing apparatus
Is to make the computer realize,
The function (b) is
(B1) A function for setting the algorithm so that an algorithm that realizes at least one of the various functions is optimized in accordance with the data processing capability detected by the capability detection means.
It is characterized by providing.
[0035]
The first or second recording medium of the present invention is excellent regardless of the data processing capability of the information processing apparatus, like the first or second apparatus of the present invention or the first or second method of the present invention. There is an effect that operability can be exhibited.
[0036]
Other aspects of the invention
The present invention includes other aspects as follows.
[0037]
According to the first aspect, the means, process or function for detecting the data processing capability of the central processing unit in each of the above inventions is executed by repeating a predetermined calculation process a predetermined number of times and taking the time required for the execution. This is an aspect of a desired configuration. The second mode is a mode in which a means, a process or a function for detecting the data processing capability of the central processing unit is obtained based on ID information stored in the central processing unit in advance. The third aspect is an aspect in which the means, process or function for detecting the data processing capacity of the central processing unit is similarly obtained by estimating the data processing capacity of the CPU from the specifications of the surrounding environment such as memory and free hard disk space. It is. In the first to third aspects, the data processing capability of the central processing unit can be easily detected.
[0038]
The fourth aspect is an aspect as a computer program that causes a computer to realize the functions of the respective steps or means of the invention described above. A fifth mode is a mode as a data signal embodied in a carrier wave by including the computer program. A 6th aspect is an aspect as a program supply apparatus which supplies a computer program via a communication path. In the sixth aspect, the above method and apparatus can be realized by placing the program on a server on the network, etc., downloading the necessary program to a computer via a communication path, and executing it. .
[0039]
DETAILED DESCRIPTION OF THE INVENTION
In order to further clarify the configuration and operation of the present invention described above, embodiments of the present invention will be described based on examples. FIG. 1 is an external view of a computer system to which the first embodiment of the present invention is applied. This computer system includes a computer 10 and a CRT display 12 and a printer 14 as peripheral devices. The computer 10 includes a computer main body 16, a keyboard 18, and a mouse 20. The computer main body 16 is equipped with a floppy disk drive 24 for reading the contents of the floppy disk 22. The printer 14 is a so-called ink jet printer that forms dots on the surface of the paper by ejecting ink droplets. The printer 14 transports the paper in the sub-scanning direction while reciprocating the carriage in the main scanning direction. The image is recorded.
[0040]
FIG. 2 is a block diagram illustrating a schematic configuration of hardware of the computer system. As shown in the figure, the computer main body 16 includes a ROM 31, a RAM 32, a display image memory 33, a mouse interface 34, a keyboard interface 35, an FDC 36, an HDC 37, and a CRTC 38, which are connected to each other by a bus around a CPU 30 as a central processing unit. A printer interface 39 and an I / O port 40.
[0041]
The ROM 31 is a read-only memory that stores various built-in programs and the like. The RAM 32 is a readable / writable memory for storing various data. The display image memory 33 is a memory for storing image data of an image to be displayed on the CRT display 12. The mouse interface 34 is an interface that manages data exchange with the mouse 20. The keyboard interface 35 is an interface that manages key input from the keyboard 18. The FDC 36 is a floppy disk controller that controls the floppy disk drive (FDD) 24. The HDC 37 is a hard disk controller that controls a hard disk drive (HDD) 41. The CRTC 38 is a CRT controller that controls display of an image on the CRT display 12 based on display image data stored in the display image memory 33. The printer interface 39 is an interface that controls the output of data to the printer 14. The I / O port 40 includes a serial output port, and is connected to a modem 44, and is connected to a public telephone line 46 via the modem 44. The computer 10 is connected to an external network via a modem 44 and can be connected to a specific server 48.
[0042]
In this computer system, the operating system is stored in the HDD 41, and when the computer main body 16 is turned on, it is loaded into a predetermined area of the RAM 32 according to the loader written in the boot block of the HDD 41. A printer driver prepared for each model of the printer 14 is stored in the floppy disk 22 in advance, and is installed in the computer main body 16 from the floppy disk drive 24 by starting a predetermined installation program. The installed printer driver is stored in the HDD 41. When the computer main body 16 is turned on, the installed printer driver is incorporated into the operating system and loaded into a predetermined area of the RAM 32.
[0043]
Various constituent requirements of the present invention are realized by the CPU 30 executing the printer driver. As described above, the printer driver software program is stored in the floppy disk 22, but instead of this, other portable recording media such as a CD-ROM, a magneto-optical disk, and an IC card. It is good also as a structure stored in (portable recording medium). The software program described above can also be obtained by downloading program data provided via a network from a specific server 48 connected to an external network and transferring the program data to the RAM 32 or the HDD 41. .
[0044]
Next, how printing is performed by the computer system having the hardware configuration described above will be described. FIG. 3 is a block diagram showing a state of processing from image information handled by the computer main body 16 until printing is performed. As shown in the figure, an image is displayed on the CRT display 12 via the video driver 52 while processing the image by the application program 51 operating inside the computer main body 16. When the application program 51 issues a print instruction, the printer driver 53 in the computer main body 16 receives the image information from the application program 51 and converts it into a signal that can be printed by the printer 14. The printer driver 53 is installed from the floppy disk drive 24 to the computer main body 16 by the installation program 58.
[0045]
In the example shown in FIG. 3, the printer driver 53 includes a rasterizer 54 that converts image information handled by the application program 51 into color information in dot units, and image information (floor level) converted into color information in dot units. A color correction module 55 that performs color correction on the tone data) according to the color development characteristics of the printer 14, so-called expressing density in a certain area depending on the presence or absence of ink in dot units from image information after color correction. A halftone module 56 for generating halftone image information is provided. In addition, an information setting module 57 for setting various information for printing by the printer 14 is provided inside the printer driver 53. Various information for printing includes information related to basic printing settings such as print quality, color correction, and halftone type, and information related to paper settings such as paper size and printing direction.
[0046]
The color correction information set by the information setting module 57 is sent to the color correction module 55, and the halftone type information is sent to the halftone module 56. The information setting module 57 displays an image indicating the setting contents on the CRT display 12 via the video driver 52. Inside the information setting module 57, a default changing unit 57a as a main part of the present invention is provided. Inside the installation program 58, a capability detection unit 58a as a main part of the present invention is provided. The information setting module 57 and the installation program 58 will be described in detail below.
[0047]
The printer driver 53 can control various printing by the printer 14 by changing the setting, but the user needs to perform such setting in advance. The information setting module 57 executes such an operation for setting various information for printing. Here, what operation the user performs by the operation of the information setting module 57 will be described first. In this description, Windows 95 (trademark of Microsoft Corporation) will be described as an example of an operating system on which the printer driver 53 operates. The description will be made assuming that the name of the printer 14 is “PM-00”.
[0048]
First, the user operates the computer 10 as follows to open a dialog box for setting various information for printing. That is, a “printer” window is opened by performing an operation of [start] → [setting] → [printer]. Then, double-click the icon of the desired printer on the window, here “PM-00” to open the window for that printer. Thereafter, a [printer] → [property] operation is performed from the window to display a dialog box for setting various information about the printer.
[0049]
FIG. 4 is an explanatory diagram illustrating the dialog box DA. As shown in the figure, the dialog box DA includes six types of cards CD1, CD2, CD3, CD4, CD5 of “information”, “details”, “basic settings”, “paper settings”, “layout”, and “utility”. , CD6 is prepared. The “information” card CD1 is for setting information about the printer such as a comment of the printer. The “detail” card CD2 is used for setting detailed information about the printer such as a port to which the printer is connected. The “basic setting” card CD3 is used to set basic information related to print quality. The “paper setting” card CD4 is used to set various information about paper. The “layout” card CD5 is used to set layout information about paper. The “utility” card CD6 is used to set other useful information.
[0050]
When the operator operates the mouse 20 and clicks a tab portion, one of the cards CD1 to CD6 corresponding to the tab is displayed in the dialog box DA. FIG. 4 illustrates a state in which the “basic setting” card CD3 is displayed. The contents of the cards CD1 to CD6 are not limited to the above example, and may be configured to include all the contents with one card, or may be divided into seven or more cards in a more detailed manner. Alternatively, the contents of the cards CD1 to CD6 may be based on different groupings.
[0051]
As shown in the figure, the “basic setting” card CD3 has three data input fields E1, E2, “paper type”, “ink”, and “mode setting” as data input fields for receiving data input from the operator. E3 is provided. Further, the card CD3 is provided with a data display field E4 for displaying some information of the current setting contents of the printer driver.
[0052]
The “paper type” data entry field E1 is used to set the paper type, and “plain paper”, “super fine paper”, “exclusive gloss film”, and the like are prepared as options. The “ink” data input field E2 is used to set the type of ink used in the printer 14, and “color” and “black” are prepared as options. The “mode setting” data entry field E3 is used to select a basic setting mode. A “recommended setting” mode in which a predetermined setting is automatically performed, and a “detailed setting” in which manual setting is performed in detail. The “setting” mode can be selected by the buttons E3a and E3b.
[0053]
When the button "E3a" is clicked and the "recommended setting" mode is selected, a slide lever type button E3e (not shown) is clearly shown, and it is possible to easily specify the quality of printing by the printer 14. It becomes.
[0054]
When the button E3b is clicked and the “detailed setting” mode is selected, the following operation is performed. When the “detailed setting” mode is selected, the data input field E3c and the data input field E3d are displayed as “current setting” and “setting change” and become active. As a result, it is possible to input a printing purpose from the data input field E3c, and it is possible to open a dialog box for performing manual setting from the data input field E3d. The data input field E3c is used to set the type of image data to be printed, and options such as a word processor, a graph, and a photograph are prepared.
[0055]
FIG. 5 is an explanatory diagram illustrating a dialog box DB for manual setting opened from the data input field E3d. As shown in the drawing, data input fields E11, E12, E13 for “print quality”, “paper type”, “ink”, “halftone”, “microweave”, “bidirectional printing”, “color adjustment”, and the like. , E14, E15, E16, and E17 are provided.
[0056]
The “print quality” data input field E11 is used to set the resolution for printing, and four types of “draft”, “fine”, “super fine”, and “photo” are prepared as options. Here, “draft”, “fine”, “superfine”, and “photo” are 180 × 180 [dot], 360 × 360 [dot], 720 × 720 [dot], and 1440 × 720 [dot] in this order. The resolution is shown. The “paper type” data input field E12 and the “ink” data input field E13 are the “paper type” data input field E1 and the “ink” data input field E2 provided on the “basic setting” card CD3. The data entered later is given priority, and the display in the data entry field of the data entered earlier is changed according to the data entered later.
[0057]
The “halftone” data input field E14 is used to set the type of halftone, and “high speed halftone” and “high quality halftone” are prepared as options. This halftone type information is used in the halftone module 56 (FIG. 3). The “microweave” data entry field E15 is for turning on / off the microweave function. Here, the microweave is a function provided in the printer 14, and the quality of printing can be improved by scanning different lines with the same nozzle. The “bidirectional printing” data entry field E16 is for turning on / off the bi-directional printing function. Here, bi-directional printing is a function provided in the printer 14, and the printing speed can be increased by moving the head from left and right bi-directional.
[0058]
The “color adjustment” data entry field E17 is used to set various information related to color correction, and “color correction by driver”, “auto photo fine”, and “ICM” can be selected using buttons E17a, E17b, and E17c. It has become. “Color correction by driver” is a setting for manually performing color correction. When the button E17a is clicked and “color correction by driver” is selected, a box of “color correction method” and “lightness” are selected. , “Contrast”, “Saturation”, “Cyan”, “Magenta”, and “Yellow” correction item boxes can be set. “Auto Photo Fine” automatically prints an image in a document with high image quality. “ICM (Image Color Matching)” matches the display on the display with the actual color of the printed output.
[0059]
Returning to FIG. 4, the data display column E4 can display a list of the current contents input and set from the various cards CD1 to CD6, and more specifically, “paper size” and “printing direction”. , “Layout page number”, “stamp mark presence / absence”, “print quality”, “microweave”, “bidirectional printing”, and “color adjustment” are displayed.
[0060]
Among various processes executed by the CPU 30 of the computer main body 16, some processes related to the present invention will be described below.
[0061]
FIG. 6 is a flowchart showing an installation processing routine for installing the printer driver 53 in the computer main body 16. This installation processing routine is realized by an installation program 58 that is executed in response to an instruction to start installation by an operation of the mouse 20 by an operator.
[0062]
As shown in the figure, when the process is started, the CPU 30 first activates the floppy disk drive 24, reads the printer driver 53 from the floppy disk 22, and copies the printer driver 53 to the HDD 41 (step). S100). Next, the CPU 30 performs a processing capability detection process for detecting the data processing capability of the CPU itself (step S110). The processing in step S110 corresponds to the capability detection unit 58a described in FIG.
[0063]
FIG. 7 is a flowchart showing details of the processing capacity detection processing in step S110. As shown in the figure, when the processing shifts to the processing capacity detection processing, the CPU 30 takes in the current time from a real time timer (not shown) built in the computer main body 16, and stores the time in the RAM 32 as a variable t1 (step S1). S112). Next, a relatively time-consuming calculation process, for example, a process for performing a high-precision floating-point operation is repeatedly executed a predetermined number of times (step S114). Thereafter, the CPU 30 fetches the current time from the real time timer and stores the time as a variable t2 in the RAM 32 (step S116).
[0064]
Subsequently, the CPU 30 calculates the time td required for the repetitive processing of step S116 by subtracting the variable t1 stored in step S114 from the variable t2 stored in step S116 (step S118). Thereafter, the processing capacity detection process is temporarily terminated.
[0065]
Returning to FIG. 6, when the processing capacity detection process of step S110 is completed, a processing capacity evaluation process for evaluating the detected data processing capacity is performed (step S120).
[0066]
FIG. 8 is a flowchart showing details of the processing capability evaluation processing in step S120. As shown in the figure, when the processing shifts to the processing capability evaluation processing, the CPU 30 determines whether or not the time td calculated by the processing capability detection processing is smaller than a predetermined value t0 (step S122). Here, when it is determined that the time td is smaller than the predetermined value t0, the time required for the predetermined calculation processing is short. Therefore, it is evaluated that the data processing capability is high, and the result of the evaluation is stored in the RAM 32. (Step S124). On the other hand, if it is determined in step S122 that the time td is equal to or greater than the predetermined value t0, the CPU 30 evaluates that the data processing capability is low and stores the evaluation result in the RAM 32 (step S126). After the execution of step S124 or S126, the processing capacity evaluation process is temporarily terminated.
[0067]
Returning to FIG. 6, when the processing capability evaluation process in step S120 is completed, the installation process routine is terminated.
[0068]
That is, according to the installation process having the above-described configuration, the data processing capability of the CPU 30 is detected when the printer driver is installed, and the data processing capability of the CPU 30 is high or low based on the detected data processing capability. Rated in stages.
[0069]
In the installation process routine, prior to the execution of the processing capacity evaluation process in step S120, the time td calculated in the processing capacity detection process in step S110 is multiplied by a coefficient that varies depending on the amount mounted on the RAM 32. It is possible to adopt a configuration in which the process of step S120 is executed with the remaining time as a new time td. Here, as the coefficient, for example, when the RAM 32 mounting amount is 32 megabytes or less, the coefficient is 1.2, and when the RAM 32 mounting amount is larger than 32 megabytes, the coefficient is 1.0. . This is because if the capacity of the RAM 32 is small, swapping to the HDD 41 occurs, and even if the data processing capability of the CPU 30 is high, the data processing speed decreases, and the data processing capability of the computer 10 decreases. Based on the above coefficients, the data processing capability as the computer 10 can be appropriately determined.
[0070]
When the CPU 30 finishes installing the printer driver by the installation process, the CPU 30 starts the printer driver and operates the information setting module 57 provided in the printer driver to set various print information. Perform the following process.
[0071]
FIG. 9 is a flowchart showing a print information setting processing routine related to the card CD3 in the processing routine of the information setting module 57. This print information setting processing routine is repeatedly executed at predetermined time intervals when the tab of the card CD3 is clicked with the mouse 20 from the five types of cards CD1 to CD6 displayed in the dialog box DA.
[0072]
As shown in the figure, when the process is started, the CPU 30 first executes a card display process for displaying various images represented by the “basic setting” card CD3 on the CRT display 12 (step S200). Thereafter, in response to a data input operation using the keyboard 18 and mouse 20 by the operator who has viewed the display screen of the CRT display 12, various data are input (step S210), and the input various data are stored in the RAM 32. Is stored in the print information file (step S220). Thereafter, the process returns to “RETURN” to end the process. This print information setting process routine is repeatedly executed at predetermined time intervals as described above, but waits for a click operation of the “OK” buttons BT1 and BT2 (see FIGS. 4 and 5) on the display screen. finish.
[0073]
FIG. 10 is a flowchart showing details of the card display process executed in step S200. As shown in the figure, when the processing shifts to the card display processing, the CPU 30 first determines whether or not the current processing is the first processing after the installation of the printer driver (step S201). Here, if it is determined that the data is the first, it is determined whether the data processing capability of the CPU 30 obtained by the installation processing routine is high or low (step S202). Here, if it is determined that the data processing capability is high, then the CPU 30 executes a process of rewriting the default value of the print information file (step S203).
[0074]
As described above, the print information file is updated in step S220 in FIG. 6, and a standard value (default value) is prepared in advance for this print information file from the time of installation. FIG. 11 is an explanatory diagram illustrating an example of a default value of the print information file. As shown in the figure, this print information file has default values of “print quality” as “fine”, “paper type” as “plain paper”, “ink” as “color”, and “halftone” as “High-speed halftone”, “Microweave” is set to “On”, “Bidirectional printing” is set to “On”, and “Color adjustment” is set to “Color correction by driver”.
[0075]
In step S203, a process of rewriting the default value of the print information file having the above configuration is performed. Specifically, as shown in FIG. 12, “halftone” is rewritten to “high quality halftone”, “color adjustment” is rewritten to “auto photo fine”, and other items are not rewritten. . Note that the processing in step S203 corresponds to the default changing unit 57a described in FIG.
[0076]
On the other hand, if it is determined in step S201 that it is not the first, or if it is determined in step S202 that the data processing capability is low, the default value of the print information file is set at the time of installation without performing the default value rewriting process in step S203. Leave as it is.
[0077]
Thereafter, the CPU 30 determines whether or not there is an instruction of “manual setting” (step S204). This instruction is issued when the “detailed setting” button E3b on the card CD3 is clicked with the mouse 20 while the “basic setting” card CD3 is displayed on the CRT display 12. In step S204, it is determined whether or not the button E3b has been clicked.
[0078]
If it is determined in step S204 that there is no “manual setting” instruction, the CPU 30 executes a card display process for displaying an image of the “basic setting” card CD3 on the CRT display 12 (step S205). The process returns to “RETURN” and the process is temporarily terminated.
[0079]
On the other hand, if it is determined in step S204 that there is an instruction of “manual setting”, the following processing is executed. First, manual setting base image data representing the “manual setting” dialog box DB is read from the RAM 32 (or the HDD 41 in which the printer driver is stored), and the base image data is transferred to the display image memory 33 (step S206). . FIG. 13 is an explanatory diagram showing an image of the base image data Dp1 for manual setting. As shown in the figure, the base image data Dp1 indicates an image in which the insides of the various data input fields E11 to E16 and the buttons E17a to E17c in the dialog box DB shown in FIG. 5 are blank. .
[0080]
Next, the CPU 30 performs processing for transferring the contents of the print information file to the display image memory (step S207). Specifically, the transfer is performed so that the contents of the print information file are stored in the blank positions of the base image data Dp1 in the display image memory 33, respectively. Thereafter, the CPU 30 operates the CRTC 38 to control the display of the image on the CRT display 12 based on the image data stored in the display image memory 33 (step S208). As a result, an image of the “manual setting” dialog box DB illustrated in FIG. 5 is displayed on the CRT display 12.
[0081]
The image of the “manual setting” dialog box DB illustrated in FIG. 5 is the case where the print information file remains at the standard value originally prepared in the printer driver, and the data of the CPU 30 at the time of the first processing. This image is displayed when the processing capability is low. On the other hand, when the data processing capability of the CPU 30 is high at the time of the first processing, the default value of the print information file is rewritten as described above, so that “halftone” is displayed as shown in FIG. The data input column E14 displays “high quality halftone”, and the “color adjustment” data input column E17 displays an image “auto photo fine”. When the data processing capability of the CPU 30 is high, in general, it is easy to set high functions such as “high image quality halftone” and “auto photo fine”. Therefore, the image shown in FIG. 14 is displayed during the initial processing. It is configured. After the execution of step S208, the process returns to “Return” to end the process once.
[0082]
As described in detail above, the computer main body 16 of the first embodiment detects the data processing capability of the CPU 30, and according to the level of the detected data processing capability, the “Manual setting” dialog box DB defaults. In detail, the display of default values in the “halftone” data input field E14 and the “color adjustment” data input field E17 is switched. For this reason, it is possible to display a default value commensurate with the data processing capability of the CPU 30, and the operator can use the default value as it is even when the data processing capability of the CPU is high. Therefore, in the first embodiment, there is an effect that excellent operability can be exhibited regardless of the data processing capability of the CPU 30.
[0083]
In this embodiment, the display of both the “halftone” data input field E14 and the “color adjustment” data input field E17 is switched, but instead, either one is switched. It is good also as a structure. Further, the display of data input fields other than these data input fields E14 and E17 can be switched according to the data processing capability of the CPU 30.
[0084]
Next explained is the second embodiment of the invention. In the first embodiment, the capability detection unit 58a as the main part of the present invention is provided in the installation program 58. Instead, in the second embodiment, the capability setting unit 58a is provided in the information setting module 57. The detection unit 58a is provided. Specifically, the first embodiment is modified as follows.
[0085]
First, in the “installation process routine” described with reference to FIG. 6, the processes in steps S110 and S120 are deleted. Then, a card display process shown in FIG. 15 is executed instead of the card display process shown in FIG.
[0086]
As shown in FIG. 15, when the processing is started, the CPU 30 determines whether or not the current processing is the first processing after the installation of the printer driver (step S301; same as step S201 in the first embodiment). ). Here, if it is determined that it is the first time, processing capacity detection processing and processing capacity evaluation processing are executed (steps S310 and S320; the same as steps S110 and S120). The processing capacity detection process and the processing capacity evaluation process are the same as those described in the first embodiment with reference to FIGS. After execution of step S320, the CPU 30 determines whether the data processing capability of the CPU 30 obtained in step S320 is high or low (step S302; the same as step S202). If it is determined that the data processing capability is high here. Then, a process of rewriting the default value of the print information file is executed (step S303; same as step S203).
[0087]
On the other hand, if it is determined in step S301 that it is not the first, or if it is determined in step S302 that the data processing capability is low, the default value of the print information file is not changed at the time of installation without performing the default value rewriting process in step S303. Leave as it is.
[0088]
Thereafter, the CPU 30 executes the same processing as that in steps S204 to S208 in the first embodiment (steps S304 to S308), and once ends the execution of this card display processing.
[0089]
In the second embodiment configured as described above, the default condition of the “manual setting” dialog box DA is set in the “halftone” data input field E14 in the same manner as in the first embodiment, and the “high quality halftone” is set. The “color adjustment” data input field E17 can be changed according to the data processing capability of the CPU, such as “auto photo fine”. Therefore, in the second embodiment, as in the first embodiment, excellent operability can be exhibited regardless of the data processing capability of the CPU. In particular, in the second embodiment, since the data processing capability of the CPU 30 can be detected when the card is first displayed after the printer driver is activated, only a copy of the printer driver is conventionally used for the installation process. If you do.
[0090]
Next explained is the third embodiment of the invention. The third embodiment is the same as the first embodiment except for the details of the card display process of the print information setting process routine, and the other software and hardware are the same.
[0091]
FIG. 16 is a flowchart showing details of the card display processing in the third embodiment. As shown in the figure, when the processing shifts to the card display processing, the CPU 30 first determines whether or not there is an instruction of “manual setting” (step S401; the same as step S204 in the first embodiment). If it is determined that there is no instruction, the CPU 30 executes a card display process for displaying an image of the “basic setting” card CD3 on the CRT display 12 (step S402; same as step S205), and thereafter. , The process returns to “RETURN” to end this process once.
[0092]
On the other hand, if it is determined in step S401 that there is an instruction of “manual setting”, it is determined whether the evaluation result of the data processing capability of the CPU 30 obtained by the same installation processing routine as in the first embodiment is high or low (step S403). If it is determined that the data processing capability is high, a dialog box for high function is displayed (step S404). If it is determined that the data processing capability is low, a dialog box DBb for low function is displayed. The process is performed (step S405).
[0093]
The high function dialog box DBa is the same as the “manual setting” dialog box DB shown in FIG. 5 used in the first embodiment. In this “manual setting” dialog box DB, the “color adjustment” data input field E17 can be selectively set to three types of “color correction by driver”, “auto photo fine”, and “ICM”. there were. On the other hand, in the low function dialog box DBb, as shown in FIG. 17, the “color adjustment” data input field E17 has only the item “color correction by driver”, “auto photo fine”, The item “ICM” has been deleted. That is, the low-function dialog box DBb does not originally include the items “Auto Photo Fine” and “ICM” that cannot be set unless the data processing capability of the CPU 30 is high. After the execution of step S404 or S405, the process returns to “RETURN” and the process is temporarily terminated.
[0094]
As described in detail above, in the computer main body 16 of the third embodiment, the data processing capability of the CPU 30 is detected and set in the “manual setting” dialog box DB according to the level of the detected data processing capability. The range of possible functions is limited. For this reason, only settings that are commensurate with the data processing capability of the CPU 30 can be made, so that unnecessary setting operations are not performed. Therefore, in the third embodiment, the operability is excellent regardless of the data processing capability of the CPU 30.
[0095]
The third embodiment can be modified as follows. In the third embodiment, the low function dialog box has a configuration in which display of settable items is limited. Instead, in order to distinguish between low function and high function. Further, only the display position of the item is changed without restricting the settable item. FIG. 18 is an explanatory diagram showing a dialog box DBa2 for high functions. As shown in the figure, in this advanced function dialog box, the “color adjustment” data input field E17 is displayed in the order of “auto photo fine”, “ICM”, and “color correction by driver”. The low function dialog box paired with the high function dialog box DBa2 is the same as the dialog box DB shown in FIG. 5 described in the first embodiment. In this low-function dialog box, the “color adjustment” data input field E17 is displayed in the order of “color correction by driver”, “auto photo fine”, and “ICM”.
[0096]
According to the above configuration, when the data processing capability of the CPU 30 is high, items such as “Auto Photo Fine” and “ICM”, which are generally set easily, are displayed at positions ahead of the “Color correction by driver” item. Therefore, there is an effect that the setting according to the data processing capability of the CPU 30 is easy.
[0097]
As a modification of the third embodiment, the data processing capability of the CPU 30 can be detected when the printer driver is activated, as in the second embodiment.
[0098]
Next explained is the fourth embodiment of the invention. The fourth embodiment is different from the first embodiment only in the details of the installation processing routine, and the other software and hardware are the same.
[0099]
FIG. 19 is a flowchart showing an installation processing routine in the fourth embodiment. As shown in the figure, when the process is started, the CPU 30 performs a process of copying the printer driver 53 from the floppy disk 22 to the HDD 41 (step S500; the same as step S100 of the first embodiment). Next, a process of reading the CPU ID information written at a specific address of the CPU 30 is performed (step S510). For example, for an Intel CPU, information indicating a CPU ID, a CPU type, a model, and a stepping is embedded in a specific address. As an example, if the CPU is Intel Celeron 266Mhz, the information that CPUID = “GenuieIntel”, CPU type = “6”, model = “5”, stepping = “2” is written. The contents are published by Intel. In step S510, the CPU 30 reads these data from itself as ID information.
[0100]
Next, the CPU 30 detects its own data processing capability by comparing the ID information read in step S510 with a table that stores information disclosed by the manufacturer in advance (step S511). Thereafter, the CPU 30 determines from the detected data processing capability whether or not it is a CPU capable of high-speed image processing having a multimedia extension instruction (hereinafter referred to as an MMX instruction) corresponding to a moving image or the like (step S512). ). If it is determined that the CPU is capable of high-speed image processing using the MMX instruction, the CPU 30 evaluates that the data processing capability is high and stores the evaluation result in the RAM 32 (step S513). On the other hand, when a negative determination is made in step S512, it is evaluated that the data processing capability of the CPU 30 is low, and the result of the evaluation is stored in the RAM 32 (step S514). After the execution of step S513 or S514, this installation processing routine is once ended.
[0101]
The CPU 30 also executes a print information setting process routine including a card display process for switching and displaying the default condition of the “manual setting” dialog box DB using the evaluation result of the data processing capability of the CPU 30. This print information setting processing routine has the same configuration as that of the first embodiment.
[0102]
In the fourth embodiment configured as described above, the data processing capability of the CPU 30 can be easily evaluated as in the first embodiment. The default condition of the “manual setting” dialog box DB can be switched and displayed according to the evaluation result. Therefore, as in the first embodiment, the operator can use the default condition as it is even when the CPU has a high data processing capability. As a result, the operability is excellent regardless of the data processing capability of the CPU 30. There is an effect that can be exhibited.
[0103]
As a method for detecting the data processing capability of the CPU 30, there are the following methods in addition to the methods of the first and fourth embodiments. The CPU 30 obtains the size of the RAM 32 using a function of Windows 95 that is an OS, and determines whether or not the size is equal to or larger than a predetermined value. If the RAM size is large, it is determined that the CPU 30 has a high processing capacity, and the CPU 30 determines that the data processing capacity is high. On the other hand, if the RAM size is small, the CPU 30 has a low data processing capacity. Determine. Even with this configuration, the data processing capability of the CPU can be easily evaluated. Further, the data processing capability of the CPU may be evaluated from another peripheral environment such as the size of the free area of the HDD 41 instead of the RAM size.
[0104]
Furthermore, in the fourth embodiment, the evaluation of the CPU 30 is performed when the printer driver 53 is installed, but instead, it is configured so that it is performed when the printer driver 53 is started, as in the second embodiment. You can also.
[0105]
Next explained is the fifth embodiment of the invention. The fifth embodiment includes the same installation processing routine as that of the fourth embodiment. The card display process of the print information setting process routine has a configuration different from the first to fourth embodiments. Other software and hardware are the same as those in the first embodiment.
[0106]
FIG. 20 is a flowchart showing details of the card display processing in the fifth embodiment. As shown in the figure, when the processing shifts to the card display processing, the CPU 30 first determines whether or not there is an instruction of “manual setting” (step S601; the same as step S204 in the first embodiment). If it is determined that there is no instruction, the CPU 30 executes a card display process for displaying an image of the “basic setting” card CD3 on the CRT display 12 (step S602; same as step S205), and thereafter , The process returns to “RETURN” to end this process once.
[0107]
On the other hand, if it is determined in step S601 that there is an instruction of “manual setting”, it is determined whether the evaluation result of the data processing capability of the CPU 30 obtained by the same installation processing routine as in the fourth embodiment is high or low (step S603). If it is determined that the data processing capability is high, a dialog box for high function is displayed (step S604). If it is determined that the data processing capability is low, a dialog box for low function is displayed. Processing is performed (step S605).
[0108]
Both the high function dialog box and the low function dialog box are composed of the same images as the “manual setting” dialog box DB shown in FIG. 5 used in the first embodiment. The difference is that, for high-function ones, when at least one of the various set information defines a function that can be described by an algorithm using the MMX instruction, it depends on the algorithm using the MMX instruction. Information is set so that the function is realized. On the other hand, the low function dialog box sets information so that the function is realized by an algorithm that does not use the MMX instruction. After execution of step S604 or S605, the process returns to “RETURN” and the process is temporarily terminated.
[0109]
In the fifth embodiment configured as described above, the CPU 30 is set by a “manual setting” dialog box depending on whether or not the CPU 30 is a high-function capable of high-speed image processing using the MMX instruction. Information indicating the function realized by the algorithm using the MMX instruction and information indicating the function realized by the algorithm not using the MMX instruction. Therefore, the operator can realize the function by an algorithm using the MMX instruction without being aware of the data processing capability of the CPU. Therefore, in the fifth embodiment, an optimum function can be realized with excellent operability regardless of the data processing capability of the CPU 30.
[0110]
Next explained is the sixth embodiment of the invention. FIG. 21 is a block diagram showing a schematic hardware configuration of a computer system to which the sixth embodiment of the present invention is applied. As shown in the figure, the computer (client) 1000 of the sixth embodiment is connected to a computer (server) 1010 provided with a shared database via a computer network 1020 constructed by a local area network (LAN). ing. Note that the computer network 1020 can be replaced with various networks such as the Internet, an intranet, and a wide area network (WAN) instead of the LAN.
[0111]
As in the first embodiment, the client computer 1000 is connected to a CRT display as a peripheral device, and includes a keyboard and a mouse. The computer main body includes a CPU, a ROM, a RAM, and the like. As described above, the server computer 1010 is a computer having a shared database, to which a printer 1030 is connected in addition to a CRT display as a peripheral device, and includes a keyboard and a mouse. A CPU, ROM, RAM and the like are provided.
[0112]
In the computer system having this configuration, the client computer 1000 performs print settings using a printer driver, and transmits print data to the server computer 1010 via the computer network 1020. The computer 1010 receives the print data and performs printing with the printer 1030.
[0113]
A printer driver is provided in the client computer 1000, and the same rasterizer 54, color correction module 55, and halftone module 56 as in the first embodiment are provided in the printer driver. However, this printer driver has a configuration in which the case where the three modules 54, 55 and 56 are made to function and the case where the three modules 54, 55 and 56 are not made to function can be selected. In the former case, similarly to the first embodiment, the client computer 1000 executes processing up to halftone processing, and transmits image data expanded into a binary bitmap to the server computer 1010. In the latter case, the client computer 1000 transmits data at the drawing command stage, and the server computer 1010 performs rasterizer, color correction, and halftone processing.
[0114]
The selection between the former case and the latter case is performed by an information setting module built in a printer driver provided on the client computer 1000 side. FIG. 22 is an explanatory diagram illustrating a dialog box DC displayed on the screen by such an information setting module. As shown in the figure, the “details” card CD 12 is provided with a data input field E101 for “print destination port” and a data input field E102 for “driver used for printing”. Further, the card CD12 is provided with a data input field E103 for setting a computer for performing rasterizer, color correction, and halftone image processing. The data input field E103 includes a “self” mode in which the computer that performs the image processing is set as its own computer, and a “print destination” mode in which the computer that performs the facial image processing is set as the printing destination computer. The radio buttons E104 and E105 can be selected.
[0115]
FIG. 23 is a flowchart showing card display processing for displaying the “details” card CD12. As shown in the figure, when processing is started, the CPU of the client computer 1000 first determines whether or not the current processing is the first processing after switching the data input field E101 of “print destination port”. (Step S1100). When the data input field E101 of “print destination port” is switched, it indicates that the printer of the print destination has been switched, for example, from local to network. It is determined whether or not.
[0116]
If it is determined in step S1100 that it is the first time, processing for detecting the data transfer capability of the computer network 1020 is executed (step S1110). Specifically, this capability detection is performed by reading out interface standards such as Centronics, SCSI, and IEEE1394 from the setting contents of the operating system. Subsequently, the process which evaluates the capability detected by step S1110 is performed (step S1120). Specifically, it is assumed that the network capability is low in the case of Centronics, and the network capability is high in the case of SCSI or IEEE1394.
[0117]
Next, the image of the “details” card CD 12 shown in FIG. 22, which is a “print destination port” data input field E101, a “printer driver” data input field E102, radio buttons E104, Basic image data indicating an image in which each inner side of E105 is blank is displayed on the CRT display 12. Thereafter, it is determined whether the ability evaluated in step S1120 is “high” or “low” (step S1140). If “high” is determined here, the process proceeds to step S1150, and “image processing” is performed. The default condition of “Computer performing” is set to the “self” mode, and the upper radio button E104 is displayed in a selected state.
[0118]
On the other hand, if “low” is determined in step S1140, the process proceeds to step S1160 to set the default condition of “computer that performs image processing” as the “print destination” mode, and press the lower radio button E105. Display in selected state. After the execution of step S1150 or S1160, the process returns to “RETURN” and this processing routine is temporarily terminated.
[0119]
As described above, the card display processing program is included in the printer driver. As in the first embodiment, the printer driver software program is stored in advance on the floppy disk and stored in the HDD. Once installed, the computer 1000 is loaded into the RAM and used when the power is turned on. The printer driver may be stored in another portable recording medium (portable recording medium) such as a CD-ROM, a magneto-optical disk, or an IC card, instead of the floppy disk. The printer driver can also download and obtain program data provided via a network from a specific server connected to the external network.
[0120]
In the computer system of the sixth embodiment configured as described above, the data transfer capability of the network 1020 is detected, and depending on the level of the detected capability, the default condition of the dialog box DC, The display of the radio buttons E104 and 105 in the selected state in the data input field E103 of “Computer for Image Processing” is switched. For this reason, it is possible to display a default condition commensurate with the capability of the network 1020, and the operator can use the default value as it is even when the data transfer capability of the network 1020 is high. Therefore, in the first embodiment, there is an effect that excellent operability can be exhibited regardless of the data transfer capability of the network 1020.
[0121]
In the sixth embodiment, the data transfer capability of the network is detected from the interface standard. Instead, it may be obtained by detecting the load state of the computer 1010 of the server.
[0122]
As another example of switching the display default condition according to the data transfer capability of the communication path, when the printer is locally connected to the computer, the “manual setting” dialog box DB described in the first embodiment is “ The default display of the “halftone” data entry field E14 may be switched as follows. That is, when the communication path data transfer capability is low, it is assumed that the computer has sufficient capacity, and the "halftone" data input field E14 is set to "high quality halftone", while the communication path data transfer capability is high. In this case, the “halftone” data entry field E14 is set to “high speed halftone”.
[0123]
Although various embodiments of the present invention have been described in detail above, the present invention is not limited to these embodiments and can be implemented in various modes without departing from the scope of the present invention. it can.
[0124]
(1) For example, in the above-described embodiment, the present invention is applied to a driver for a printer. However, instead of this, it may be configured to be applied to a driver for other peripheral devices such as a scanner, a monitor, a keyboard, and a mouse. Further, the present invention can be applied to a peripheral device that records a moving image, and can be configured to set a compression mode in the peripheral device. Further, the present invention is not limited to the device driver for the peripheral device. For example, a predetermined function (for example, interpolation processing) in an application program that performs image processing may be set.
[0125]
(2) In the above-described embodiment, the printer 14 is applied to a computer system directly connected to the local computer 10 via a cable. Instead, a printer connected to a server on the LAN can be connected to a plurality of computers. The configuration may be applied to a shared computer system.
[0126]
(3) Alternatively, a printer connected to a server connected via the Internet may be applied to a computer system controlled by a computer via the Internet.
[Brief description of the drawings]
FIG. 1 is an external view of a computer system to which a first embodiment of the present invention is applied.
FIG. 2 is a block diagram showing a schematic configuration of hardware of a computer system.
FIG. 3 is a block diagram showing a state of processing from image information handled by a computer main body 16 until printing is performed.
FIG. 4 is an explanatory diagram showing a dialog box DA in which a “basic setting” card is opened.
FIG. 5 is an explanatory diagram showing a “manual setting” dialog box DB;
FIG. 6 is a flowchart showing an installation processing routine for installing the printer driver 53 in the computer main body 16;
FIG. 7 is a flowchart showing details of processing capacity detection processing;
FIG. 8 is a flowchart showing details of processing capacity evaluation processing.
FIG. 9 is a flowchart showing a print information setting processing routine for setting print information related to the card CD3.
FIG. 10 is a flowchart showing details of card display processing.
FIG. 11 is an explanatory diagram illustrating an example of a default value of a print information file.
FIG. 12 is an explanatory diagram showing a print information file after rewriting default values.
FIG. 13 is an explanatory diagram showing an image of base image data Dp1 for manual setting.
FIG. 14 is an explanatory diagram showing a “manual setting” dialog box DB displayed when the data processing capability of the CPU 30 is high.
FIG. 15 is a flowchart showing details of card display processing in the second embodiment;
FIG. 16 is a flowchart showing details of card display processing in the third embodiment;
FIG. 17 is an explanatory diagram showing a dialog box DBb for low functions in the third embodiment.
FIG. 18 is an explanatory diagram showing a dialog box DBa2 for high functions in a modification of the third embodiment.
FIG. 19 is a flowchart showing an installation processing routine in the fourth embodiment;
FIG. 20 is a flowchart showing details of card display processing in the fifth embodiment.
FIG. 21 is a block diagram showing a schematic configuration of hardware of a computer system to which a sixth embodiment of the present invention is applied.
FIG. 22 is an explanatory diagram showing a dialog box DC in which a “detail” card is opened.
FIG. 23 is a flowchart showing details of card display processing in the sixth embodiment.
[Explanation of symbols]
10 ... Computer
12 ... CRT display
14 ... Printer
16 ... computer body
18 ... Keyboard
20 ... Mouse
22 ... Floppy disc
24 ... Floppy disk drive
30 ... CPU
31 ... ROM
32 ... RAM
33 ... Display image memory
34 ... Mouse interface
35 ... Keyboard interface
36 ... FDC
37 ... HDC
38 ... CRTC
39 ... Printer interface
40 ... I / O port
41 ... HDD
44 ... Modem
46 ... Public telephone line
48 ... Server
51. Application program
52 ... Video driver
53 ... Printer driver
54 ... Rasterizer
55. Color correction module
56 ... Halftone module
57 ... Information setting module
57a ... Default change part
58 ... Installation program
58a ... Ability detection unit

Claims (21)

Data processing execution means for performing data processing for realizing a predetermined function;
Function setting for displaying a data input window on the display device, taking in an input from the input device operated according to the data input window, and setting a function realized by the data processing according to the input And an information processing apparatus comprising:
Storage means for storing in advance the default conditions of the data input window;
Capability detection means for detecting the data processing capability of the information processing device;
An information processing apparatus comprising: a default changing unit that changes the default condition according to the detected data processing capability. The information processing apparatus according to claim 1, wherein the capability detection unit is configured to detect a data processing capability of a central processing unit provided in the information processing apparatus. The information processing apparatus according to claim 1, wherein the capability detection unit is configured to detect a data transfer capability of a communication path connected to the information processing apparatus. 4. The information processing apparatus according to claim 1, wherein the default changing unit is configured to change a default value prepared in advance in a data input field included in the data input window. 4. The information processing apparatus according to claim 1, wherein the default changing unit is configured to limit a range of functions that can be set in the data input window. 4. The information processing apparatus according to claim 1, wherein the default changing unit is configured to change a display position of a data input field included in the data input window. The information processing apparatus according to claim 1, wherein the data processing performed by the data processing execution unit is processing according to a predetermined device driver for a peripheral device. The information processing apparatus according to claim 7,
Installation means for copying the device driver to a storage device;
The information processing apparatus is configured to detect the data processing capability at the time of installation for copying the device driver. The information processing apparatus according to claim 7,
Installation means for copying the device driver to a storage device;
The information processing apparatus configured to detect the data processing capability when the capability detection unit is activated to execute the device driver by the data processing execution unit. Data processing execution means for performing data processing for realizing a predetermined function;
In an information processing apparatus comprising function setting means for setting a function realized by the data processing in response to a command from the worker while exchanging various types of information with the worker,
A capability detecting means for detecting the data processing capability of the information processing apparatus is provided,
The function setting means includes
An algorithm setting unit configured to set the algorithm so that an algorithm that realizes at least one of the various functions is optimized in accordance with the data processing capability detected by the capability detection unit; An information processing apparatus characterized by The information processing apparatus according to claim 10, wherein the capability detection unit is configured to detect a data processing capability of a central processing unit provided in the information processing apparatus. (A) performing data processing for realizing a predetermined function in the information processing apparatus;
(B) Displaying a data input window on the display device, capturing an input from the input device operated according to the data input window, and setting a function realized by the data processing according to the input And an information processing method comprising:
(C) predefining default conditions for the data input window;
(D) detecting the data processing capability of the information processing apparatus;
(E) A step of changing the default condition according to the detected data processing capability. (A) performing data processing for realizing a predetermined function in the information processing apparatus;
(B) In an information processing method comprising a step of setting various functions realized by the data processing in response to a command from the worker while exchanging various types of information with the worker,
(C) including a step of detecting the data processing capability of the information processing apparatus;
The step (b)
(B1) including a step of setting the algorithm so that an algorithm that realizes at least one of the various functions is optimized according to the data processing capability detected by the capability detection unit. An information processing method characterized by the above. (A) a function of performing data processing for realizing a predetermined function;
(B) Displaying a data input window on the display device, capturing an input from the input device operated according to the data input window, and setting a function realized by the data processing according to the input A computer-readable recording medium recording a computer program for causing a computer to realize the function to perform,
The computer program further includes:
(C) a function for predetermining default conditions for the data input window;
(D) a function of detecting the data processing capability of the computer;
(E) A recording medium for causing a computer to realize a function of changing the default condition according to the detected data processing capability. The recording medium according to claim 14, wherein the function (d) is configured to detect a data processing capability of a central processing unit provided in the computer. The recording medium according to claim 14, wherein the function (d) is configured to detect a data transfer capability of a communication path connected to the computer. 17. The recording medium according to claim 14, wherein the function (e) is configured to change a default value prepared in advance in a data input field included in the data input window. 17. The recording medium according to claim 14, wherein the function (e) is configured to limit a range of functions that can be set in the data input window. The recording medium according to claim 14, wherein the function (e) is configured to change a display position of a data input field included in the data input window. 20. The recording medium according to claim 14, wherein the data processing performed by the function (a) is processing according to a predetermined device driver for a peripheral device. (A) a function of performing data processing for realizing a predetermined function;
(B) A computer program for causing a computer to realize a function of setting a function realized by the data processing in accordance with a command from the worker while exchanging various types of information with the worker A recorded computer-readable recording medium,
The computer program further includes:
(C) for causing a computer to realize a function of detecting the data processing capability of the information processing apparatus;
The function (b) is
(B1) A function of setting the algorithm so that an algorithm that realizes at least one of the various functions is optimized according to the data processing capability detected by the capability detection unit. recoding media.

Images