JP2013061986A - Image data generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accelerate processing of preparing raster images from data described in a page description language which is not page independent.SOLUTION: An image data generation device for generating image data from data described in a page description language which is not page independent has a plurality of RIPs 40 for generating image data of assigned pages among data described in the page description language. The RIPs 40 execute the development registration of print resources in each page accompanied with at least a change in print resources regardless of the assignment of the assigned pages.

Description

  The present invention relates to an image data generation apparatus that generates image data from data described in a page description language (PDL).

  As for the image forming apparatus, various conventional techniques have been proposed in order to perform high-speed development processing when creating a raster image (data) from data described in a page description language. For example, Patent Document 1 discloses a method in which data described in a page description language is once divided into pages and processed by a plurality of CPUs. Further, Patent Documents 2 and 3 disclose a method for speeding up the drawing information in units of drawing objects output by performing document structure analysis and performing parallel processing by a plurality of drawing processing units. Patent Document 4 discloses a method of performing parallel processing by analyzing a page description language in advance and dividing it into units that can be processed in parallel.

Japanese Patent No. 3555748 JP-A-10-97394 JP 2003-51019 A Japanese Patent No. 3589255

  An object of the present invention is to speed up the process of creating a raster image from data described in a page description language such as PostScript that is not page independent.

According to the first aspect of the present invention, in an image data generating apparatus that generates image data from data described in a page description language that is not page-independent, image data of an allocated page among data described in the page description language A plurality of generation units that generate print resources on each page accompanied by a change in at least the print resource, regardless of the assigned page assignment. The image data generation device.
The invention described in claim 2 further includes a control unit that assigns generation of image data so that the number of pages waiting for image data generation processing is equal in each generation unit. An image data generation device.
The invention according to claim 3 is characterized in that the development registration of the print resource is downloading and registering a form, or downloading and registering a font. It is an image data generation apparatus of description.
The invention according to claim 4 is the image data generation device according to any one of claims 1 to 3, wherein the page description language that is not page-independent is PostScript.

According to the image data generation device of claim 1, even when the data is described in a page description language that is not page-independent, the content of the change of the print resource is generated by each generation unit in the generation of the raster image by the plurality of generation units. The raster image can be created at high speed by reliably reflecting the creation of the raster image.
According to the image data generation device of the second aspect, it is possible to improve the processing efficiency by leveling the difference in processing time in each generation unit.
According to the image data generation device of claim 3, it is possible to reliably reflect the change of the form and the font which are the printing resources in each of the generation units.
According to the image data generation device of claim 4, in the generation of the raster image by the plurality of generation units for the data described in PostScript, the contents of the change of the print resource are surely generated in the generation of the raster image by each generation unit. It is possible to create a raster image at high speed.

It is a figure which shows the function structure of the image data generation apparatus by this embodiment. It is a figure which illustrates the hardware constitutions of the computer suitable for implement | achieving the image data generation apparatus of this embodiment. It is a figure explaining the method of dividing | segmenting PDL data into a page unit. It is a figure which illustrates the mode of allocation of the page data with respect to each RIP in this embodiment. It is a figure explaining the management method of each page by the page index in this embodiment. 5 is a time chart comparing processing times when page data rasterization is performed in parallel with a plurality of RIPs according to the present embodiment and when page data rasterization is performed sequentially with a single RIP. It is a time chart which shows the operation | movement timing of each RIP at the time of performing rasterization of page data in parallel by several RIP by the modification of this embodiment. It is a time chart which shows the operation | movement timing of each RIP at the time of performing rasterization of page data in parallel by several RIP by the other modification of this embodiment. It is a time chart which shows the mode of communication between each RIP and RIP control part in the example of FIG. It is a figure which shows the function structure of the image data generation apparatus in other embodiment of this invention. It is a time chart which shows the operation | movement timing of each RIP at the time of performing rasterization of page data in parallel by several RIP by this embodiment.

The best mode for carrying out the present invention (hereinafter referred to as an embodiment) will be described below in detail with reference to the accompanying drawings.
FIG. 1 is a diagram illustrating a functional configuration of the image data generation apparatus according to the present embodiment.
As shown in FIG. 1, the image data generation apparatus according to the present embodiment divides data described in a processing target page description language into page units, an input processing unit 20, and a page-by-page division. And an input image storage unit 30 for storing the processed data. A plurality of raster image processors (RIP) 40 (40a to 40d) that generate (rasterize) raster images from data stored in the input image storage unit 30 and an RIP control unit 50 that controls the operation of the RIP 40 are provided. . The image data generation device also includes an output image storage unit 60 that stores raster images generated by a plurality of RIPs 40, an I / F (interface) conversion unit 70 for outputting the raster images to the image forming apparatus, and And an image output unit 80. In the figure, thick arrows indicate the flow of data, and thin arrows indicate the flow of control instructions.

FIG. 2 is a diagram exemplifying a hardware configuration of a computer suitable for realizing the image data generation apparatus.
As shown in the figure, the computer 300 includes a CPU (Central Processing Unit) 301 that is a computing means, a main memory 302 that is a storage means, and a magnetic disk device (HDD: Hard Disk Drive) 303. Here, the CPU 301 executes various software such as an OS (Operating System) and an application, and realizes the above-described functions. The main memory 302 is primary storage means for storing various software and data used for execution thereof, and the magnetic disk device 303 is secondary storage for storing input data for various software, output data from various software, and the like. Means. Furthermore, the computer 300 shown in FIG. 2 includes a communication I / F (interface) 304 for performing communication with the outside, a display mechanism 305 including a video memory and a display, and an input device 306 such as a keyboard and a mouse. Is provided. Note that the image data generation device of the present embodiment includes a plurality of RIPs 40 as described above. As will be described in detail later, the RIP 40 is realized by, for example, the CPU 301 of the computer 300 shown in FIG. Therefore, the computer 300 used as the image data generation apparatus of this embodiment is provided with a plurality of CPUs 301 and a plurality of main memories 302 if necessary.

  The page dividing unit 10 illustrated in FIG. 1 is realized by, for example, the CPU 301 of the computer 300 illustrated in FIG. The page dividing unit 10 reads data described in a page description language to be processed (hereinafter referred to as PDL data) and divides the data into page data (hereinafter referred to as page data). The PDL data to be processed is acquired by receiving it from an external device or reading it from a predetermined storage device.

FIG. 3 is a diagram for explaining a method of dividing PDL data into pages.
As shown in FIG. 3A, the PDL data consists of a list of drawing commands and control commands. For example, “TEXT A” is a command for drawing a character using the font A. “DLFONT A” is a command to download font A to the RIP 40 and register it as a print resource. “PSTART” and “PEND” represent page breaks, “PSTART” means the start of the page, and “PEND” means the end of the page. The page dividing unit 10 divides each page based on the control commands “PSTART” and “PEND”.

  When the PDL data shown in FIG. 3A is divided based on the control commands “PSTART” and “PEND”, page data for four pages is obtained as shown in FIG. The first and second pages of the page data include control commands “DLFORM 1” and “DLFONT A” for changing the print resource. “DLFORM 1” is a command to download the form 1 to the RIP 40 and register it as a print resource, and “DLFONT A” is a command to download and register the font A as described above.

  Here, referring to the page data on the third and fourth pages, the font A registered on the second page is used on the third page. Therefore, the image of the third page can be created only after downloading and registering the font A of the second page. Similarly, on the fourth page, the form 1 registered on the first page is used. Therefore, the image of the fourth page can be created only after downloading and registering the form 1 of the first page.

  As shown in FIG. 3, most of the PDL data has a configuration in which the change of the print resource performed on a predetermined page is also used on other pages (not page-independent). Therefore, the page data divided in units of pages cannot be rasterized in parallel by a plurality of RIPs 40 as they are. Therefore, in order to realize the distributed processing of each page data, it is necessary to transmit the change of the print resource performed on a predetermined page to the RIP 40 that has not rasterized the page. In the present embodiment, this information exchange is realized by the control of the RIP control unit 50 described later.

The input processing unit 20 is realized by the CPU 301 of the computer 300 shown in FIG. 2, for example, and sequentially stores the page data divided by the page dividing unit 10 in the input image storage unit 30. Further, the RIP control unit 50 is notified that the page data has been stored in the input image storage unit 30.
The input image storage unit 30 is realized by, for example, the main memory 302 or the magnetic disk device 303 of the computer 300 shown in FIG. 2 and stores the page data sent from the input processing unit 20.

  The RIP 40 is realized by, for example, the CPU 301 and the main memory 302 of the computer 300 shown in FIG. 2, and reads the page data of the allocated page from the input image storage unit 30 under the control of the RIP control unit 50 to generate a raster image. To do. Further, as described above, the image data generation apparatus of this embodiment includes a plurality of RIPs 40, and each RIP 40 is realized by a separate CPU 301. In addition, a plurality of main memories 302 used as development areas for registering print resources can be provided together with the RIP 40, or an area used by each RIP 40 can be set in a single main memory 302.

  The RIP control unit 50 is realized by, for example, the CPU 301 and the main memory 302 of the computer 300 illustrated in FIG. 2, and instructs each RIP 40 to rasterize page data and register the development of print resources. As shown in FIG. 1, the RIP control unit 50 includes a command transmission unit 51 that transmits an instruction command to each RIP 40 and a response reception unit 52 that receives a response from each RIP 40. Then, based on the response from each RIP 40 received by the response receiving unit 52, the page data is dynamically allocated to each RIP 40 so that the waiting time of processing in each RIP 40 is reduced. Specific control contents by the RIP control unit 50 will be described later.

The output image storage unit 60 is realized by, for example, the main memory 302 or the magnetic disk device 303 of the computer 300 shown in FIG. 2, and stores the raster image generated by the RIP 40.
The I / F conversion unit 70 is realized by, for example, the CPU 301 of the computer 300 shown in FIG. 2, reads the raster image stored from the output image storage unit 60 under the control of the RIP control unit 50, and sets the data format to a printer or the like. Convert to a format that the image forming apparatus can handle.
The image output unit 80 is realized by, for example, the communication I / F 304 of the computer 300 illustrated in FIG. 2, and transmits the data converted by the I / F conversion unit 70 to the image forming apparatus.

Next, the control by the RIP control unit 50 will be described in detail.
FIG. 4 is a diagram exemplifying how page data is allocated to each RIP 40. Here, it is assumed that the page data is distributedly processed by the four RIPs 40 RIP 40 a to RIP 40 d.

  Based on the notification from the input processing unit 20, the RIP control unit 50 sends an operation instruction command for each page data from the command transmission unit 51 to the RIPs 40 a to 40 d. At this time, the RIP control unit 50 instructs one RIP 40 to execute rasterization for each page data (page data marked with a circle (◯) in FIG. 4). Then, the other RIP 40 is instructed to execute only the print resource expansion registration (page data marked with a triangle (Δ) in FIG. 4). It is preferable that allocation of pages to be rasterized is performed in units of several pages at least initially. This is because it is inefficient if the RIP control unit 50 assigns the next page data each time the RIP 40 completes rasterization for one page and reads the page data to which the RIP 40 is assigned. Each RIP 40 prefetches several pages of page data and executes rasterization continuously, thereby improving the execution efficiency.

  In the example shown in FIG. 4, page data to be rasterized is assigned to each RIP 40 for two pages. Specifically, the rasterization of the first page (P1) and the fifth page (P5) is RIP 40a, the rasterization of the second page (P2) and the sixth page (P6) is RIP 40b, the third page (P3) and The rasterization of the seventh page (P7) is assigned to the RIP 40c, and the rasterization of the fourth page (P4) and the eighth page (P8) is assigned to the RIP 40d (the ninth page (P9) will be described later). Therefore, for each page, only the print resource development registration is instructed to the other RIP 40 (for example, RIPs 40b to 40d for the first and fifth pages).

  Here, considering the operation of each of the RIPs 40a to 40d taking the page data shown in FIG. 3B as an example, since the RIP 40a is instructed to execute rasterization for the first page, the raster image of the first page Is generated. At this time, naturally, download and registration of Form 1 are performed. Since the RIPs 40b to 40d are instructed only to register the development of the print resource, the raster image is not generated, but the form 1 is downloaded and registered. As a result, the form 1 is registered for expansion in all of the RIPs 40a to 40d. Therefore, even in the RIP 40d that rasterizes the fourth page in which the form 1 is used, a raster image using the form 1 is generated without any problem.

  Similarly, regarding the second page, the RIP 40b is instructed to execute rasterization, so the raster image of the second page is generated, and the font A is downloaded and registered. Since the RIPs 40a, 40c, and 40d are instructed only to register the development of the print resource, the raster image is not generated, but the font A is downloaded and registered. As a result, the font A is registered for expansion in all of the RIPs 40a to 40d. Therefore, even in the RIP 40c that rasterizes the third page in which the font A is used, the raster image using the font A is generated without any problem.

  Each of the RIPs 40a to 40d generates a raster image of the page data assigned to itself as described above, stores the raster image in the output image storage unit 60, and notifies the RIP control unit 50 that the rasterization has been completed. When the response receiving unit 52 of the RIP control unit 50 receives this notification, the RIP control unit 50 allocates page data for the ninth and subsequent pages. Each page data has a different time required for rasterization depending on its contents. Accordingly, when each page data is distributedly processed by a plurality of RIPs 40, the rasterization is not always completed in the page order of the original PDL data. In the example of FIG. 4, notification of rasterization completion is sent to the response receiving unit 52 in the order of the third page, the second page, the first page, and the fifth page. Therefore, the RIP control unit 50 assigns rasterization for the ninth and subsequent pages so that the number of pages waiting for rasterization processing is equal for each RIP 40a to 40d in order to level the difference in processing time between the RIPs 40a to 40d. . In the example shown in FIG. 4, the rasterization of the next ninth page is assigned to the RIP 40c that has completed the rasterization of page data (third page) for one page first. Thereafter, it may be assigned in the same manner for each page, or it may be assigned in units of two pages as in the initial setting. In the former case, the 10th page is allocated to the RIP 40b where the rasterization of the page data (second page) for the second page is completed second. In the latter case, the 10th page (P10) is assigned to the RIP 40c in the same manner as the 9th page.

The RIP control unit 50 manages the rasterization of each page data with a page index that is a pointer to a storage area in which the raster image of each page is stored in the output image storage unit 60. The page index attributes include at least a next created page indicating page data for instructing rasterization (assigning generation of a raster image) and a next transmission page indicating a raster image to be sent to the image forming apparatus. .
FIG. 5 is a diagram for explaining a method of managing each page based on the page index. In the figure, rasterization has already been completed for the second page and the third page, and raster images have been written to the corresponding storage area by the assigned RIP 40 (RIPs 40b and 40c in the example of FIG. 4) (FIG. 4). 5 is shown in gray).

  The RIP control unit 50 examines the storage area of the output image storage unit 60, and if there is an unused area having a size greater than the size specified by the page attribute of the page data at the address specified by the page index of the next created page, The buffer offset is set in the instruction command to be sent to the RIP 40, and the instruction point of the next creation page is advanced by the used size. In this way, by specifying the areas in the page order, rasterized images are created in continuous areas such as the main memory 302 that is the output image storage unit 60.

  If the area specified on the next page of the page index is in use (other rasterized (previous) pages have been saved and not yet printed), that area can be used to save the raster image. Since it cannot be used, transmission of an instruction command to the RIP 40 is awaited. Usually, a raster image stored in a used area is printed, and the used area is released at a timing when a final output from the image forming apparatus can be confirmed. Therefore, if the usable area including the current free area and the released area is larger than the area of the size requested by the page attribute, the RIP control unit 50 sends the waiting instruction command to the assigned RIP 40. .

  In addition, the RIP control unit 50 notifies the I / F conversion unit 70 of the page information for which rasterization has been completed. Based on this notification, the I / F conversion unit 70 reads the raster image of the page that has been rasterized from the output image storage unit 60, converts the data format, and outputs the converted data format to the image forming apparatus. At this time, the notification from the RIP control unit 50 to the I / F conversion unit 70 is not performed in the order of rasterization completion, but guarantees the page order. In the example shown in FIG. 5, the rasterization of the second page and the third page is completed, but the rasterization of the first page is not completed. Accordingly, the page index of the next transmission page remains pointing to the area where the first page is stored, and the RIP control unit 50 does not only the first page but also the second and third pages. Do not notify

  Thereafter, when the rasterization of the first page is completed and the RIP 40 notifies the response reception unit 52 of the RIP control unit 50, the RIP control unit 50 has completed the rasterization for the first, second, and third pages. Are sequentially notified to the I / F conversion unit 70. Then, the I / F conversion unit 70 sequentially reads and processes the first, second, and third pages. On the other hand, after the raster images of the first, second, and third pages are read and output by the image forming apparatus, the RIP control unit 50 stores the raster images of the same page in the output image storage unit 60. The area is released, and the instruction point of the next transmission page is advanced to the area where the fourth page is stored.

FIG. 6 is a time chart for comparing processing times when page data rasterization is performed in parallel with a plurality of RIPs 40 according to the present embodiment and when page data rasterization is performed sequentially with a single RIP. Here, an example is shown in which processing is performed with the allocation shown in FIG. 4 by four RIPs 40a to 40d.
When each of the RIPs 40a to 40d performs processing on the same page data, naturally, the time required to execute only the print resource development registration is shorter than the time required to generate the raster image. Therefore, referring to FIG. 6, while the RIP 40a is rasterizing the first page, the processing of the first page is completed in the RIP 40b, and the rasterization of the second page is started. Similarly, while the RIP 40b is rasterizing the second page, the processing of the first and second pages is completed in the RIP 40c, and the rasterization of the third page is started. Further, while the RIP 40c is rasterizing the third page, the processing of the first to third pages is completed in the RIP 40d, and the rasterization of the fourth page is started.

  Here, as described above, the management of the raster image in the RIP control unit 50 guarantees the page order. Therefore, as shown in FIG. 6, when the rasterization of the second page by the RIP 40b is completed before the rasterization of the first page by the RIP 40a, it is not recognized that the rasterization is completed at the time when the processing of the RIP 40b is completed, When the processing of the RIP 40a is completed, it is determined that the rasterization of the first and second pages has been completed. In FIG. 6, the end time of the RIP 40b process is indicated by a broken line, and is distinguished from other end times (indicated by a dashed line) (the same applies to the processes on the sixth and seventh pages).

  On the other hand, when rasterizing each page data sequentially with a single RIP, the time required for rasterizing each page data is simply added. Therefore, as shown in FIG. 6, by performing distributed processing using a plurality of RIPs 40, the time until the completion of rasterization for each page data on and after the second page is shortened.

Next, a modified example of the control by the RIP control unit 50 described above will be described.
When the page dividing unit 10 detects a control command indicating a page break in order to divide PDL data into pages, it can also check other commands described in the PDL data. Therefore, the page dividing unit 10 adds identification data (such as a flag) indicating the fact to the page data with respect to the page having the print resource change. As a result, the RIP control unit 50 can identify whether or not there is a change in print resource for each page data.

  Since the RIP control unit 50 can identify a page having a print resource change before assigning the rasterization target page data to each RIP 40, the RIP control unit 50 assigns rasterization execution only to the page data having the print resource change. It is possible to instruct the RIP 40 other than the RIP 40 to register the development of the print resource.

FIG. 7 is a time chart showing the operation timing of each RIP 40 when page data is rasterized in parallel by a plurality of RIPs 40 according to this modification. Here, an example is shown in which processing is performed by four RIPs 40a to 40d, taking as an example page data having a change in print resource on the fourth page and the sixth page.
Referring to FIG. 7, with respect to the first to third pages, the fifth page, etc., in which the print resources are not changed, only the rasterization execution instruction is given to the assigned RIPs 40a to 40d. With respect to the fourth page in which the print resource has been changed, the RIP 40d is assigned to execute rasterization, and the RIPs 40a to 40c are also instructed to execute print resource development registration. Similarly, regarding the sixth page, the RIP 40b is assigned to execute rasterization, and the RIPs 40a, 40c, and 40d are also instructed to execute print resource development registration.

  As described above, even in the RIP 40 that does not perform rasterization, the number of executions of the print resource expansion registration by each RIP 40 is reduced by setting the pages for which the print resource expansion registration is performed only to the pages with the print resource change.

Next, another modified example of the control by the RIP control unit 50 described above will be described.
In this modification, the RIP control unit 50 instructs the execution of rasterization by distributing the pages to each RIP 40 without considering the change of the print resource. Each RIP 40 notifies the RIP control unit 50 of the completion of rasterization, and also transmits information to the RIP control unit 50 when the print resource is changed during the rasterization process. When the RIP control unit 50 receives information related to the change of the print resource from the predetermined RIP 40, the RIP control unit 50 ignores the rasterization completion notification for the pages after the page where the change of the print resource is performed. Then, the received print resource change is copied to each of the other RIPs 40. After that, the execution of rasterization is instructed again for the pages after the page where the print resource is changed.

FIG. 8 is a time chart showing the operation timing of each RIP 40 when page data is rasterized in parallel by a plurality of RIPs 40 according to this modification, and FIG. 9 is a diagram between the RIPs 40a to 40d and the RIP control unit 50. It is a time chart which shows the mode of communication.
In the illustrated example, when the RIP 40b rasterizes the sixth page, the print resource is changed (indicated by a black circle (●) in FIG. 8), and the print resource change notification is sent together with the sixth page rasterization completion notice. To the RIP control unit 50 (indicated by a thick arrow in FIG. 9).

  Since the print resource has been changed on the sixth page, the RIP control unit 50 ignores the subsequent rasterization notifications on the seventh and eighth pages (indicated by crosses (x) in FIG. 8). Here, for the seventh page, the notification is received before the rasterization completion notification of the sixth page. However, as described with reference to FIG. 6, the RIP control unit 50 recognizes the completion of the rasterization for the seventh page after waiting for the completion of the rasterization for the sixth page in order to guarantee the page order. The notification regarding the seventh page is also ignored.

  Next, the RIP control unit 50 causes the RIP 40b to copy the contents of the expansion registration of the print resource performed in the rasterization of the sixth page to the other RIPs 40a, 40c, and 40d, and then causes the RIPs 40c and 40d to perform the seventh and eighth. Instruct the page to be rasterized again. For the ninth and subsequent pages, if the RIP control unit 50 has instructed execution of rasterization before instructing to change the print resource, it is necessary to instruct execution of rasterization again. If there is, it suffices to instruct the execution of rasterization in the normal operation.

FIG. 10 is a diagram showing a functional configuration of an image data generation device according to another embodiment of the present invention.
As shown in FIG. 10, the image data generation apparatus according to the present embodiment divides data described in a page description language to be processed into page units, an input processing unit 20, and a page-by-page division. And an input image storage unit 30 for storing the processed data. A plurality of raster image processors (RIP) 40 and 41 that generate (rasterize) raster images from data stored in the input image storage unit 30 and an RIP control unit 53 that controls operations of the RIPs 40 and 41 are provided. The image data generation device also includes an output image storage unit 60 that stores raster images generated by a plurality of RIPs 40, an I / F (interface) conversion unit 70 for outputting the raster images to the image forming apparatus, and And an image output unit 80.

  In the configuration shown in FIG. 10, the page division unit 10, the input processing unit 20, the input image storage unit 30, the output image storage unit 60, the I / F conversion unit 70, and the image output unit 80 correspond to the corresponding configurations shown in FIG. Same as element. Therefore, the same reference numerals are given and description thereof is omitted. Further, the image data generation apparatus shown in FIG. 10 is realized by a computer configured as shown in FIG. 2, for example, similarly to the apparatus shown in FIG.

The RIP 40 shown in FIG. 10 is almost the same as the RIP 40 shown in FIG. However, in this embodiment, each RIP 40 rasterizes page data by sharing print resources expanded and registered in a single storage area in a single main memory 302.
The RIP 41 executes print resource development registration for all page data. That is, the print resource is registered in the shared area of the main memory 302 by the RIP 41 and is used in the processing of each RIP 40.

  Similar to the RIP control unit 50 shown in FIG. 1, the RIP control unit 53 assigns page data to be rasterized to each RIP 40. However, in this embodiment, as described above, only the RIP 41 is instructed to register the development of the print resource. Therefore, each RIP 40 is instructed only to generate a raster image for the assigned page data.

FIG. 11 is a time chart showing the operation timing of each RIP 40 when page data is rasterized in parallel by a plurality of RIPs 40 according to this embodiment.
Referring to FIG. 11, all the print resources are registered for expansion by the RIP 41. In the RIPs 40a to 40d, only the rasterization of the assigned page data is performed. Here, the rasterization of each page data is performed at the timing when the development registration of the print resource of the corresponding page is executed by the RIP 41. This is because the rasterization is performed with reference to the contents of the print resource development registration performed by the RIP 41.

  In the example shown in FIG. 11, for example, in the RIP 40a, when the rasterization of the first page is completed, the development registration of the print resource of the fifth page by the RIP 41 is not performed, so the rasterization of the fifth page is started immediately. I ca n’t do it, and I ’m waiting. Similarly, in RIPs 40b to 40d, there is a waiting time from the completion of rasterization of the previous page to the start of rasterization of the next page. In the initial stage of the job, such a waiting time occurs because the registration development of the print resource by the RIP 41 cannot catch up with the parallel rasterization processing speed by the plurality of RIPs 40. However, as described above, since the time required for registering and developing print resources is shorter than the time required for rasterizing the same page, such a waiting time becomes shorter as the job progresses. When the registration development of the print resource by the RIP 41 is completed, the waiting time in the processing of each RIP 40 does not occur thereafter.

As described above, the case where the image data generation apparatus is configured as an apparatus independent of the image forming apparatus such as a printer has been described as an example. However, the function of the image data generation apparatus described above is realized by a control device inside the image forming apparatus. It is also possible. In this case, the page division unit 10, the input processing unit 20, the input image storage unit 30, the RIP 40, the RIP control unit 50, and the output image storage unit described above are performed by a CPU and a RAM (Random Access Memory) that constitute the control device. Sixty functions are realized. Since the image forming apparatus is an internal device, a raster image generated from the output image storage unit 60 is read out under the control of the RIP control unit 50 instead of the I / F conversion unit 70 and the image output unit 80, Output control means for directly supplying the exposure apparatus of the forming apparatus is provided.
Note that each of the above-described embodiments and modifications thereof can be used not only independently but also by appropriately combining the respective methods.

DESCRIPTION OF SYMBOLS 10 ... Page division part, 20 ... Input processing part, 30 ... Input image preservation | save part, 40a-d, 41 ... Raster image processor (RIP), 50, 53 ... RIP control part, 51 ... Command transmission part, 52 ... Response reception , 60 ... output image storage unit, 70 ... I / F (interface) conversion unit, 80 ... image output unit, 300 ... computer, 301 ... CPU (Central Processing Unit), 302 ... main memory, 303 ... magnetic disk device, 304: Communication I / F (interface), 305 ... Display mechanism, 306 ... Input device

Claims (4)

In an image data generation device that generates image data from data described in a page description language that is not page-independent,
Among the data described in the page description language, it has a plurality of generation units for generating the image data of the allocated page,
The plurality of generation units are:
Regardless of the allocation of the allocated page, executing the print resource expansion registration in each page at least accompanied by the change of the print resource,
An image data generation device characterized by the above.   The image data generation apparatus according to claim 1, further comprising a control unit that assigns generation of the image data so that the number of pages waiting to be processed for generating the image data is equal in each of the generation units.   3. The image data generation apparatus according to claim 1, wherein the expansion registration of the print resource is download and registration of a form, or download and registration of a font.   The image data generation apparatus according to any one of claims 1 to 3, wherein the page description language that is not page-independent is PostScript.

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