JPH066612A - Picture data processing unit - Google Patents

Abstract

PURPOSE:To reduce the processing time of the entire image memory by allocating a split area not processed yet to an idle compander one after another so as to process the area thereby enhancing the operating efficiency of the compander. CONSTITUTION:A processing unstart area detection section 9-1 detects in which area among division areas of an image memory 5 the processing is not started for. A pause compander detection section 9-3 detects which of comanders 6-1-6-n is at a pause at present. Moreover, an allocation matrix control circuit 9-2 controls to which compander the processing of which division area is to be allocated based on a signal from the processing unstart area detection section 9-1 and the pause compander detection section 9-3. Then an allocation matrix 9-4 executes the allocation of the division area to each of the comanders 6-1-6-n according to a command from the matrix control circuit 9-2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image data processing device for performing high speed processing by processing data in each area obtained by dividing an image memory in parallel by a plurality of compression / expansion devices.

[0002]

2. Description of the Related Art As a method for high-speed compression / expansion processing of image data, there is a method in which a plurality of compression / expansion devices are provided and they are operated in parallel. For example, there is one in which an image memory for one page is divided into a plurality of areas, and a compression / expansion device is provided for each area to handle the processing of the area.
FIG. 5 shows a diagram in which the image memory for one page is divided into a plurality of areas. 20 is an image memory for one page,
Reference numerals 20-1, 20-2, and 20-n are divided areas obtained by dividing the image memory 20 for one page into n. 1 of divided area
A compression / expansion device is provided for each one.

If each pixel is represented by multi-valued image data, a compression / decompression device may be provided for each memory of a plane to which each bit forming the multi-value belongs.
Alternatively, a compression / expansion device may be provided for each area obtained by further dividing the memory of each plane. FIG. 6 shows a diagram in which the memory of each plane of the multivalued image is further divided. 21 is the memory of the plane of the least significant bit (2 ⁰ digit), 22 is the memory of the plane of the second least significant bit (the digit of 2 ¹ ), 23 is the memory of the plane of the most significant bit (2 ² digit), 21-1 ~ 2
3-2 is a divided area, A is a pixel, and A ₀ , A ₁ , and A ₂ are image data. This multi-valued image is an image whose density is represented by 8 gradations. A compression / expansion device may be provided for each memory of each plane, or a compression / expansion device may be provided for each area obtained by further dividing the memory of each plane into two as indicated by the dotted line.

FIG. 4 shows a block diagram of such a conventional image data processing apparatus. In FIG. 4, 1 is MPU
(Microprocessor unit), 2 is DMAC
(DirectMemory Access Controller), 3 IIT (image input terminal, image input section), 4 IOT
(Image output terminal, image output section) 5, image memory, 6-1, 6-2, 6-n compression / expansion device, 7 image data bus, 8 coded data memory, 8- Reference numerals 1, 8-2, 8-n are coded data memory division units. The image memory 5 has a capacity capable of storing image data for one page of an image and is called a page memory.

In the image data processing apparatus shown in FIG. 4, a compression / expansion unit in charge of each divided area of the image memory 5 is fixedly assigned. For example, in FIG.
For example, the divided area 20-1
The compression / expansion device 6-1 is responsible for the compression / expansion processing
Are assigned, and the compression / expansion unit 6-2 is assigned as the one in charge of the divided area 20-2.

The data encoded by each compression / expansion unit is stored in the encoded data memory 8, and the encoded data memory 8 is also divided into n, which is the same as the number of divided images. Coded data memory division units 8-1 to 8- in FIG.
n is that. Then, each division unit is associated with each compression / expansion device, and stores the data encoded by the corresponding compression / expansion device. For example, if the encoded data memory division unit 8-1 is associated with the compression / expansion unit 6-1, the encoded data memory division unit 8-1 is encoded by the compression / expansion unit 6-1. The stored data is stored.

The outline of the operation is as follows. IIT3
The read image data is first stored in the image memory 5. Next, the image data is transferred from the image memory 5 to the compression / expansion devices 6-1 to 6-n and compressed. Since each compression / decompression device processes image data in a narrow area obtained by dividing one page in parallel, the time required to complete the processing is faster than that for processing one entire page with a single compression / decompression device. Become. The data encoded by the compression / decompression device is
It is stored in the corresponding coded data memory division unit in the coded data memory 8. Data transfer is done by the DMAC
Done by two.

When outputting an image, each coded data memory division unit transfers the coded data to a corresponding compression / decompression device, and decompresses each. The image data obtained as a result of decompression is transferred to the image memory 5 and developed as a one-page image. After that, it is transferred from the image memory 5 to the IOT 4 and output as an image. Also in this case, since the decompression processing is performed in parallel in each divided area, the processing speed is higher than that performed by a single compression / decompression device.

As a conventional document relating to such a technique, there is, for example, JP-A-62-176374.

[0010]

(Problems) However, the above-mentioned conventional image data processing apparatus has the following problems. The first problem is that if there is a difference in the compression ratio depending on the divided areas of the image memory, the operating efficiency of the compression / decompression device will be degraded. The second problem is that when a large-capacity encoded data storage means (eg hard disk) having a low random access speed and a low cost is used as the encoded data memory 8 because of the large amount of image data to be handled, each compression / expansion is performed. This is because if there is a difference in the compression rate depending on the divided area of the image memory assigned to the container, the decompression processing time becomes longer than the compression processing time.

(Description of Problems) The first problem is that the divided areas of the image memory and the compression / expansion device are fixedly assigned. FIG. 3 is a diagram showing a correspondence relationship between the image memory divided areas and the compression / expansion devices in the conventional data processing apparatus. When the image memory 5 is divided into areas 5A to 5D, the divided areas 5A to 5D are As indicated by arrows, they are fixedly assigned to the compression / expansion units 6-1 to 6-4, respectively. The compression / expansion device pauses after processing of its own area and does not assist other compression / expansion devices.

For example, it is assumed that the divided area 5A is an area of data having a poor compression rate, and the other divided areas are areas of data having a good compression rate. The compression / expansion devices 6-2 to 6-4, which are in charge of the data having a good compression ratio, finish processing in a short time and pause, but the compression / expansion device 6-in which is in charge of the data having a low compression ratio. 1 still continues to operate. However, the compression decompressors 6-2 to 6-4 which are at rest do not
Do not help -1. Therefore, the operating efficiency is poor, and the processing time until the entire processing is completed becomes long.

Next, the second problem will be described. When the document size becomes large or the image data handled by processing a plurality of documents increases, a large-capacity memory is required as the coded data memory 8.
If it is prepared in RAM, it becomes expensive. Therefore, it is conceivable to use a large-capacity encoded data storage means such as a hard disk having a low random access speed but a low cost.

However, one hard disk is divided into coded data memory division units 8-1 to 8-n to store the data of the corresponding compression / expansion units 6-1 to 6-n and read by random access. The processing speed is slow.
This is because, in general, when randomly accessing the hard disk, the seek operation of the head takes time, and it takes longer than when reading is performed in the order of storage.

In order to increase the processing speed by using the hard disk, the encoded data obtained by compression by the compression / expansion devices 6-1 to 6-n are written in the hard disk in the order in which they are obtained, and are written when the data is expanded. There is no choice but to take the method of reading in order. It should be noted that the transfer to the hard disk for writing is performed when the encoded data is collected to some extent for each compression / decompression device.

FIG. 7 is a diagram for explaining the compression processing time and the decompression processing time. The compression processing time T _C will be described with reference to FIG. The data input to a certain compression / expansion device is data with a good compression ratio (data with little change between "1" and "0". For example, in the case of data representing 4-level density with 2 bits It is assumed that the data input to the other compression / expansion device is data having a poor compression ratio (for example, lower bits in the case of data representing 4-level density with 2 bits).

The data having a low compression rate has a large amount of encoded data obtained by compression, and when time T _{3 has} elapsed, a certain large amount of encoded data D ₁ which is a unit to be stored in the hard disk is accumulated. , Which is transferred to the hard disk and stored at time T ₄ . Further, when time T _{5 has} elapsed, a large amount of encoded data D ₂ is accumulated, and this is stored in the hard disk at time T ₆ .

However, the data having a high compression rate is a certain amount of coded data which is a unit to be stored in the hard disk for the first time when a certain time T ₁ has passed after the coded data D ₂ is stored. D ₃ collects, time T ₂
It is stored in the hard disk with. After that, if the encoded data D ₄ of the data having a poor compression ratio is stored at the time T ₈ , the compression processing time T _C is the time until the end of the time T ₈ .

FIG. 8 is a diagram showing a data storage state in the hard disk when the data is stored in the above order. Reference numeral 8 denotes a hard disk which is a large capacity encoded data storage means. D _{1 to} D ₄ correspond to those in FIG. 7, and are stored in the order of occurrence, that is, D ₁ , D ₂ , D ₃ , and D ₄ .

Next, referring to FIG. 7B, the extension processing time T _E
Will be described. In order to perform reading from the hard disk 8 at high speed, it is stated that the method of reading is performed in the order of writing. According to this method, the encoded data D ₁ (data having a poor compression rate) written first is read,
It is expanded. The expansion process requires time T ₃ . Next, the coded data D ₂ written _second is read out. The coded data D ₃ having a good compression rate is read next.

However, it takes a long time T ₁ to decompress the encoded data D ₃ because the data has a good compression rate. The coded data D ₄ is read before the time has passed, and the decompression process is also completed. After all, the decompression processing time T _E until the decompression processing of both data ends is the time until the decompression processing of the encoded data D ₃ of the data having a good compression rate ends. This expansion processing time T _E and the previous compression processing time T
_When compared with _C , the extension processing time T _E becomes longer as shown in the figure. T _D in the figure is the time difference between the two. The reason for this is that the reading speed in the hard disk is not slowed down, and the reading method of reading in the order of writing is adopted.

An object of the present invention is to solve the above problems.

[0023]

In order to solve the above-mentioned problems, according to the present invention, in a data processing device in which a plurality of compression / expansion devices perform compression / expansion processing of divided areas of an image memory in parallel, An image memory divided into a larger number of divided areas than the number of decompressors, and an allocation matrix unit for allocating compression / decompression processing relating to the divided areas to an arbitrary compression / decompression device. It was decided to allocate so that there is no compression / decompression device that is idle while there is.

[0024]

[Operation] In an image data processing device in which the image memory is divided into multiple areas and the compression / expansion processing of each area is processed in parallel by multiple compression / expansion devices, the number of divisions of the image memory is determined by Do more. Then, the divided areas and the compression / expansion units are not fixedly processed in a one-to-one correspondence, but the uncompressed compression / expansion units are sequentially assigned with unprocessed divided areas for processing.

As a result, while there is a divided area where the processing has not started, there is no resting compression / expansion unit, and the operating efficiency of the compression / expansion unit is improved. As a result, it is possible to reduce the overall processing time. Further, since the size of one divided area is smaller than that in the case where the image memory is divided into the same number as the compression / expansion unit, even if the expansion processing time becomes longer than the compression processing time, the difference is small. .

[0026]

Embodiments of the present invention will now be described in detail with reference to the drawings. Conventionally, the number of divisions of the image memory and the number of compression / expansion devices are made equal and both are fixedly associated, but in the present invention, the number of divisions of the image memory is made larger than the number of compression / expansion devices, Both are arbitrarily associated.

FIG. 2 is a diagram for explaining the correspondence relationship between the image memory division area and the compression / expansion device in the data processing apparatus of the present invention. The reference numerals correspond to those in FIG.
Reference numeral 5f is a divided area, 6 is a compression / expansion unit, and 9-4 is an allocation matrix. The allocation matrix 9-4 serves to allocate the divided areas to the compression / expansion units.

The compression / expansion devices 6-1 to 6-4 are not fixed to which divided areas of the image memory 5 are allocated, but can be allocated to any divided areas. Then, when the processing of the allocated area is finished, and there is an area in which the processing has not started yet, the area is allocated next. For example, if the compression / expansion unit 6-1 is initially assigned to the divided area 5a and the processing of the divided area 5f is not yet started when the processing is finished,
Next, the divided area 5f is assigned. In order to perform such allocation, it is detected which divided area has not been processed yet, and which compression / expansion device is available now.

FIG. 1 is a block diagram of the image data processing apparatus of the present invention. Reference numerals correspond to those in FIG. 4, 9 is an allocation matrix section, 9-1 is a non-processing start area detecting section, and 9 is a
Reference numeral -2 is an allocation matrix control circuit, 9-3 is a pause compression / expansion detector detection unit, and 9-4 is an allocation matrix. The same reference numerals as those in FIG. 4 operate similarly to the corresponding reference numerals in FIG.

The unprocessed area detection unit 9-1 detects which area of the divided areas of the image memory 5 has not been processed yet. Pause compression / expansion detector 9-
3 detects which of the compression / decompressors is currently idle. The allocation matrix control circuit 9-2 controls which compression / expansion device is to be allocated to which divisional region, based on the signals from the unprocessed region detection portion 9-1 and the pause compression / expansion detector detection portion 9-3. To do. The allocation matrix 9-4 is the allocation matrix control circuit 9-.
According to the command from 2, the divided areas are assigned to each compression / expansion device.

As described above, the image memory 5 is divided into a large number of small areas, and the compression / expansion unit that has finished processing the allocated small areas is continuously processed with unprocessed small areas. By allocating and processing the data, it is possible to prevent the state in which some of the compression / expansion devices continue to perform processing and the other compression / expansion devices do not operate for a long time. By doing so, the operating efficiency of the compression / expansion device is improved and the overall processing time is shortened.

Also at the time of decompression, it is detected which decompressed data is not supplied to any of the small areas, and which compression / decompression device is inactive is detected, and the compressed data for the small area is decompressed. And assign the decompressed data to the small area. Also in the present invention, the extension processing time T
_E becomes longer than the compression processing time T _C for the same reason as described with reference to FIG. However, since the divided area is smaller than the conventional one, the amount of data per area is small, and the time difference based on the area having a good compression rate and the area having a poor compression rate becomes shorter than the conventional one.

[0033]

As described above, in the image data processing apparatus of the present invention, the image memory is divided into a number larger than the number of compression / expansion units, and each divided area and the compression / expansion unit are fixed one to one. Instead of processing in accordance with the above, the uncompressed decompressor is sequentially assigned unprocessed divided areas to be processed.

Therefore, the operating efficiency of the compression / expansion device is improved, and the time required to complete the processing for the entire image memory is shortened. Further, since the size of the divided area is smaller than that of the conventional one in which the image memory is divided into the same number as the compression / expansion unit, if the expansion processing time becomes longer than the compression processing time as shown in FIG. However, the difference is small.

[Brief description of drawings]

FIG. 1 is a block diagram of an image data processing device according to the present invention.

FIG. 2 is a diagram illustrating a correspondence relationship between an image memory divided area and a compression / expansion device in the data processing device of the present invention.

FIG. 3 is a diagram showing a correspondence relationship between an image memory division area and a compression / expansion device in a conventional data processing device.

FIG. 4 is a block diagram of a conventional image data processing device.

FIG. 5 is a diagram in which the image memory for one page is divided into a plurality of areas.

FIG. 6 is a diagram in which a memory of each plane of a multivalued image is divided.

FIG. 7 is a diagram illustrating compression processing time and decompression processing time in a conventional data processing device.

FIG. 8 is a diagram showing how data is stored in a hard disk in a conventional data processing device.

[Explanation of symbols]

1 ... MPU, 2 ... DMAC, 3 ... IIT, 4 ... IOT,
5 ... Image memory, 6 is compression / expansion unit, 6-1, 6-
2, 6-3, 6-4, 6-n ... Compressor / decompressor, 7 ... Image data bus, 8 ... Coded data memory, 8-1, 8
-2, 8-n ... Encoded data storage means dividing unit, 9 ... Allocation matrix unit, 9-1 ... Unprocessed region detection unit, 9
-2 ... Allocation matrix control circuit, 9-3 ... Pause compression / expansion detector detection section, 9-4 ... Allocation matrix, 20 ... 1
Image memory for pages, 20-1, 20-2, 20-
n ... Divided areas 21, 22, 23 ... Plane memory,
21-1～23-2 ... divided area, D ₁ to D ₄ ... coded data, T ₁ through T ₈ ... time

Claims (1)

[Claims] 1. A data processing device in which a plurality of compression / expansion devices perform compression / expansion processing of a divided region of an image memory in parallel, and the data processing device is divided into a plurality of division regions larger than the number of the compression / expansion devices. An image memory and an allocation matrix section for allocating compression / expansion processing relating to the divided area to an arbitrary compression / expansion unit. An image data processing device characterized by performing allocation so as not to exist.