An image processing apparatus has a plurality of serially connected image processing blocks for sequentially processing image data input thereto. After a first command for controlling the plurality of image processing blocks and image data to be processed by the plurality of image processing blocks are output to the leading image processing block, a second command indicating end of this output is output to the leading image processing block. When the second command is output from a final image processing block, the next first command and image data are output to the leading image processing block.
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8. An image processing apparatus comprising:
a plurality of serially connected image processing units which sequentially process image data input thereto, wherein each of said image processing units outputs data or commands, to the next image processing unit available, in the order of input;
a first transmission unit which outputs a first command for controlling the plurality of image processing units to a leading image processing unit;
a second transmission unit which outputs image data to be processed by the plurality of image processing units to the leading image processing unit;
a third transmission unit which outputs a second command indicating an end of outputting the image data to be processed by said plurality of image processing units to the leading image processing unit; and
a fourth transmission unit which outputs another first command to the leading image processing unit in response to the second command output from a final image processing unit.
1. An image processing method for an image processing apparatus in which a plurality of serially connected image processing blocks sequentially process image data input thereto, wherein each of the image processing blocks outputs data or commands, to the next image processing block available, in the order of input, said method comprising:
a first transmission step of outputting a first command for controlling the plurality of image processing blocks to a leading image processing block;
a second transmission step of outputting image data to be processed by the plurality of image processing blocks to the leading image processing block;
a third transmission step of outputting a second command indicating an end of outputting the image data to be processed by the plurality of image processing blocks to the leading image block; and
a fourth transmission step of outputting another first command to the leading image processing block in response to the second command output from a final image processing block.
15. A non-transitory computer-readable storage medium storing a computer program causing a computer to execute a method for an image processing apparatus in which a plurality of serially connected image processing blocks sequentially process image data input thereto, wherein each of the image processing blocks outputs data or commands, to the next image processing block available, in the order of input, said method comprising:
a first transmission step of outputting a first command for controlling the plurality of image processing blocks to a leading image processing block;
a second transmission step of outputting image data to be processed by the plurality of image processing blocks to the leading image processing block;
a third transmission step of outputting a second command indicating an end of outputting the image data to be processed by the plurality of image processing blocks to the leading image block; and
a fourth transmission step of outputting another first command to the leading image processing block in response to the second command output from a final image processing block.
2. The method according to
3. The method according to
4. The method according to
the first command includes a read command for reading out data of a register possessed by a designated one of the plurality of image processing blocks, and
when the read command is input thereto, the one designated image processing block outputs the first command inclusive of the data of the register.
5. The method according to
6. The method according to
7. The method according to
9. The apparatus according to
10. The apparatus according to
11. The apparatus according to
the first command includes a read command for reading out data of a register possessed by a designated one of said plurality of image processing units, and
when the read command is input thereto, the one designated image processing unit outputs the first command inclusive of the data of the register.
12. The apparatus according to
13. The apparatus according to
14. The apparatus according to
16. The non-transitory computer-readable storage medium according to
17. The non-transitory computer-readable storage medium according to
the first command includes a read command for reading out data of a register possessed by a designated one of the plurality of image processing blocks, and
when the read command is input thereto, the one designated image processing block outputs the first command inclusive of the data of the register.
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1. Field of the Invention
The present invention relates to an image processing method and apparatus for processing image data by a plurality serially connected image processing blocks.
2. Description of the Related Art
An image processing apparatus has been disclosed in which image processing is executed by cascade (serially) connecting a plurality of image processing blocks between a command and data transmission unit 700 and reception unit 704, as illustrated in
In
The operation of the image processing apparatus of
First, a command for setting image processing parameters is transmitted from the transmission unit 700 to the image processing blocks 701 to 703, as indicated at 804. The transmitted command is propagated to each of the image processing blocks successively as indicated at 805 to 807. As a result, the setting of image processing parameters in each image processing block is carried out. Further, when data to undergo image processing is transmitted from the transmission unit 700, as indicated at 808, image processing is executed sequentially by the image processing blocks 701 to 703 as indicated at 809 to 811, respectively, after which the processed data is received by the reception unit 704.
The data 808 that is transmitted from the transmission unit 700 is transmitted in data units (by page, block or band, etc.). After the reception unit 704 senses the end position of such a data unit, it transmits the end signal 705 to the transmission unit 700. Thereafter, the setting of image processing parameters with respect to the next unit of data is started (812 to 815) by the transmission unit 700 with respect to the image processing blocks 701 to 703, and the image processing operation is executed as indicated at 816 to 819.
However, the problem described below arises when a certain image processing block among the plurality of these blocks executes processing, such as trimming processing, in which the amount of data output decreases in comparison with the amount of data input.
Assume that the image processing block 703 of the final stage in
When such a situation arises, internal sequencers of the image processing blocks can no longer operate normally and a normal image processing operation is no longer carried out.
The present invention seeks to prevent malfunction in a plurality of serially connected image processing blocks that process image data.
The present invention provides an image processing method in which a plurality of serially connected image processing blocks sequentially process image data input thereto, the method comprises steps of outputting, to a leading image processing block, a first command for controlling the plurality of image processing blocks, and a second command after image data to be processed by the plurality of image processing blocks is output, the second command indicating end of this output; and outputting a following first command and image data to the leading image processing block when the second command is output from a final image processing block.
The present invention further provides an image processing apparatus comprising a plurality of serially connected image processing units which sequentially process image data input thereto; an output unit which outputs, to a leading image processing unit, a first command for controlling the plurality of image processing units, and a second command after image data to be processed by the plurality of image processing units is output, the second command indicating end of this output; and a control unit which controls the output unit in such a manner that a following first command and image data are output to the leading image processing unit when the second command is output from a final image processing unit.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Exemplary embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
The configuration of an image processing apparatus according to the first embodiment is similar to that shown in
As illustrated in
The transmission unit 700 multiplexes a command and data to be processed and transmits the multiplexed command and data to the image processing block 701.
The image processing blocks 701 to 703 are serially connected and each image processing block executes image processing using the multiplexed command and data. Each image processing block multiplexes and outputs the command and data that is the result of processing while maintaining the sequential relationship of the multiplexed command and data. The details of this processing will be described later.
The reception unit 704 receives the multiplexed command and processed data that have been output from the image processing block 703 that is the last stage of the plurality of serially connected image processing blocks.
Next, the formats of the command and data used by the image processing apparatus of the first embodiment will be described with reference to
The 63rd bit is a mode flag 101 that identifies the command and data. This bit indicates data when it is “0” and a command when it is “1”.
The 56th to 60th bits constitute an ID 102 indicating the processing block number of the processing block to which the command is applied. That is, the ID 102 is identification information for specifying one image processing block. The 55th bit is an RW flag 103 (changeover attribute) for designating read/write of a register. This bit indicates a read command when it is “0” and a write command when it is “1”.
The 32nd to 47th bits constitute a register address 104, and the 0th to 31st bits constitute register data 105. The register address 104 (which may also be referred to as “register 104” below) is an address area for storing an address value that indicates the location from which data is read out of the register at the time of read and the location at which data is written to the register at the time of read. Further, the register data 105 is a data area for storing data that has been read from the register or data that is written to the register. The value of the register data 105 is the read register value at the time of the read command (when RW flag 103=“0” holds), and is the write register value at the time of the write command (when RW flag 103=“1” holds).
The 48th to 54th bits and the 61st and 62nd bits are reserved areas 106 that are unusable.
The 56th bit is a start flag 202 indicating the initial data of a certain unit of data (page, block, band, etc.). The 55th bit is an end flag 203 indicating the final data of this data unit. The start flag and end flag provide data with a start attribute and an end attribute, respectively.
The 0th to 47th bits constitute data 204 that is to undergo image processing. The 48th to 54th bits and the 57th to 62nd bits constitute reserved areas 205. These areas are similar to the reserved area 106.
There are also cases where the command and data illustrated in
Next, operation of the image processing apparatus according to this embodiment will be described with reference to the timing chart of
First, a register address, write data and identification number (ID) of an image processing block are set in the transmission unit 700 from a CPU (processor), not shown. The transmission unit 700 sends the image processing blocks 701 to 703 a command 304, which is for setting image processing parameters, in the format shown in
Further, the reason why the spacing between command C and the start of data D gradually widens in
Thereafter, image data in the amount of the data unit is DMA-transferred from a storage unit such as a DRAM (not shown) to the transmission unit 700 via a DMAC (not shown), whereupon the transmission unit 700 transmits data 308, which is to undergo image processing, to the image processing block 701. The transmitted data 308 is transferred to and subjected to image processing in each of the image processing blocks, as indicated at 309 to 311, and data 311 that has been output from the image processing block 703 of the final stage is received by the reception unit 704. It should be noted that the data 308 to 311 comprises one or a plurality of data words.
The data 308 that is transmitted from the transmission unit 700 is transmitted in the format of
After transmission of the data 308 in the amount of the data unit ends, the transmission unit 700 transmits a synchronization command 312. That is, the transmission unit 700 transmits the synchronization command 312 after the final data (data word) of the data group in the unit of data is transmitted but before the command and data relating to the next data group is transmitted. The synchronization command 312 propagates through each of the image processing blocks as indicated at 313 to 315 and the synchronization command 315 is received by the reception unit 704. After it senses the synchronization command 315, the reception unit 704 transmits the end signal 705 to the transmission unit 700.
After it receives the end signal 705, the transmission unit 700 transmits a command 316 that is for the purpose of starting the setting of image processing parameters with respect to the next unit of data. From this point onward the above-described processing is repeated as indicated at 317 to 327.
Thus, in this embodiment as set forth above, the reception unit 704 notifies the transmission unit 700 of end of processing of the applicable data group in a case where the synchronization command has been received from the image processing block 703 of the final stage. After receiving the notification of end of processing from the reception unit 704, the transmission unit 700 starts the transmission of the multiplexed command and data for processing the next data group. The command includes the register address, write data and identification number (ID) of the image processing block that have been set in the transmission unit 700 from a CPU (processor), not shown. The data is DMA-transferred from a storage unit, such as a DRAM (not shown), to the transmission unit 700 via a DMAC, not shown.
In this embodiment, a command that does not cause a register-write or register-read operation in each processing block is used as the synchronization command. More specifically, and by way of example, use is made of a command in which the mode flag 101 has been set to “1” and the ID 102 has been set to an identification number that is not a duplicate of identification numbers of the image processing blocks.
The internal structure of the image processing blocks 701 to 703 in this embodiment is illustrated in
Multiplexed command and data are input from a command/data input terminal 400. A decoder 401 decodes the command and data. A register 402 controls the storage, reading and writing of register data.
The image processing block further includes an image processing unit 403 and a buffer 404 for assuring the sequential relationship of the command and data. A command holding signal 405 is output from the decoder 401 to the buffer 404. A delay adjustment flip-flop (FF) 406 is inserted into the system. In a case where an input command is not an ID indicating the above-mentioned synchronization command and does not match this block's own ID, the delay adjustment flip-flop (FF) 406 outputs this command as is. Further included is a delay adjustment flip-flop (FF) 407 for mode flags 101, 201 and IDs 102, 202 that have been decoded by the decoder 401.
An encoder 408 is for generating an output command and data, and a selection signal 409 is for selecting an output from the encoder 408. A command/data output terminal 410 is for outputting a command and data. A clear signal 411 is for clearing a sequencer and buffer within the image processing unit 403.
Next, reference will be had to
Shown in
First, as indicated at 501, the following are input to the command/data input terminal 400 of the image processing block:
These entered commands are decoded by the decoder 401. With regard to the commands for which ID 102=“2” holds, the content of the RW flag 103, address 104 and register data 105 is output to the register 402. It should be noted that commands other than those for which the ID is “2” received in the case where image processing is not in progress are output to the FF 406 as is, delayed by one clock in the FF 406 and then output to the encoder 408.
Further, the mode flag 101 and ID 102 are output to the FF 407, delayed by one clock in the FF 407 and then output to the buffer 404. Further, since only commands are input in cycles C0 to C5, the decoder 401 outputs the selection signal 409 in conformity with two cycles, which represent the latency with respect to commands of the image processing block, as indicated at 509.
In other words, as indicated at 504, inputs to the register 402 are as follows:
Further, as indicated at 508, outputs to the encoder 408 area as follows:
Further, the encoder 408 selects the output of buffer 404 when the selection signal 409 is “0”, selects the output of the image processing unit 403 when the selection signal 409 is “1”, and selects the output of the FF 406 when the selection signal 409 is “2”. Accordingly, as indicated at 509, the selection signal 409 is “0” in the period that covers cycles C1 to C4 and is “2” in the period that covers cycles C5, C6.
When the value of the RW flag 103 is “0”, a register read operation of an address designated by address 104 is performed in the register 402, and the data read out is made the register data 105. The RW flag 103=0, address 104 and register data 105 at this time are output to the buffer 404. The register read operation is performed following the end of processing of the data that was input immediately before the register command. When the value of the RW flag 103 is “1”, a register write operation that writes the content of the register data 105 to the address designated by the address 104 is carried out. The RW flag 103, address 104 and register data 105 at this time are output to the buffer 404.
At this time the register data that has been written is output to the image processing unit 403 as image processing parameters. Further, data that has entered from the image processing unit 403 and reflects the internal status, etc., can be mentioned as an example of the register-read data.
In other words, as indicated at 505 in
When the command holding signal 405 is “1”, the entered data is held in the buffer 404. The command holding signal 405 takes on the value “1” in a case where transfer of a command of the register read operation, etc., has been performed during the image processing of a certain unit of data (page, block, band, etc.) in the decoder 401, that is, during data transfer. Since there is no command transfer during image processing in the example of
In accordance with the selection signal 409, the encoder 408 generates an output command that is in accordance with the format of the command shown in
Further, since the selection signal 409 has the value “2” in the period of cycles C5, C6, the encoder 408 selects the output of the FF 406 and outputs the following to the command/data output terminal 410:
Next, reference will be made to
Shown in
As indicated at 601, the following are input to the command/data input terminal 400:
The decoder 401 decodes these items of entered data and outputs the start flag, end flag and data to the image processing unit 403. Further, during image processing, the RW flag 103 of the command, address 104 and register data 105 are output to the register 402 irrespective of the value of the ID 102. The reason for this is to propagate the data and commands to the image processing block of the final stage while the sequential relationship of the data and commands is maintained, even if the ID 102 is a value other than “2”.
Furthermore, the decoder 401 outputs the mode flag 101 and ID 102 to the FF 407. The mode flag 101 and ID 102 are delayed by one clock in the FF 407 and then output to the buffer 404. Further, data is input to the decoder 401 in periods other than that of cycle C2 in
In other words, as indicated at 602, the start flag, end flag and data are input to the image processing unit 403 in cycles C0, C1 and cycles C3 to C7. As indicated at 604, the address 104 and register data 105 are output to the register 402 in cycle C2. Further, as indicated at 609, the selection signal 409 is “1” in the periods that cover cycles C1 to C4 and C6, C7 and is “0” in the period of cycle C5.
The image processing unit 403 executes image processing at a latency of four clock cycles with respect to the entered data and outputs the start flag 202 and end flag 203 of the output data and the data 204 to the encoder 408.
Further, the register read operation described in connection with
Since the decoder 401 senses the register read command during image processing of a certain unit of data (page, block, band, etc.), it sets the command holding signal 405 to “1” in cycles C3 and C4. As a result, as indicated at 607, the buffer 404 outputs the entered mode flag 101, ID 102, RW flag 103, address 104 and register data 105 to the encoder 408 as is in cycle C3. The buffer holds these values in cycles C4 and C5.
The encoder 408 generates an output command in accordance with the format of the command shown in
In the example of
Described next will be operation in a case where the synchronization command has been input to the image processing block shown in
However, when the decoder 401 receives the synchronization command, it immediately outputs the clear signal 411 to the image processing unit 403 so that the sequencer and buffer within the image processing unit 403 are cleared to the initial state. Thus, the processing of the present sequence is terminated by the synchronization command and the buffer for image processing also is cleared. Consequently, while the processing of the present sequence is in progress, the command of the next sequence is no longer accepted and it is possible to prevent a malfunction in image processing.
In the foregoing embodiment, it may be so arranged that an ID that designates all of the image processing blocks (namely an “all designate ID”) can be described in the ID 102 of the command word. In this case, each image processing block executes processing with respect to a command word in which the block's own ID or the all-designate ID has been described. The value of the ID 102 in the synchronization command in this case is a value other than the IDs of all of the image processing blocks and other than the all-designate ID. Further, although the ID 102 of the synchronization command employs a value that does not duplicate those of the image processing blocks, this does not impose a limitation. For example, a specific address number with which each image processing block is not equipped may be described in the register address 104 as the address for the synchronization command, or an identifier for the synchronization command may be provided in the reserved area 106 (an area not being used in the command). In accordance with such a synchronization command, a register write operation or read operation is not performed in each image processing block.
Thus, in accordance with this embodiment as described above, processing of the present sequence is ended immediately and the buffer for image processing is cleared as well. Consequently, while the processing of the present sequence is in progress, the command of the next sequence is no longer accepted and it is possible to prevent a malfunction in image processing.
It should be noted that there are cases where the object of the invention is attained also by supplying a software program directly or remotely to a system or apparatus, reading the supplied program codes with a computer of the system or apparatus, and then executing the program codes. In this case, the program supplied is a program corresponding to flowcharts illustrated in the drawings of the embodiment.
Accordingly, since the functional processing of the present invention is implemented by computer, the program codes per se installed in the computer also implement the present invention. In other words, the present invention also covers a computer program that is for the purpose of implementing the functional processing of the present invention.
In this case, so long as the system or apparatus has the functions of the program, the form of the program, for example, object code, a program executed by an interpreter or script data supplied to an operating system, etc., does not matter.
Examples of storage media for supplying the program are a floppy (registered trademark) disk, hard disk, optical disk, magneto-optical disk, CD-ROM, CD-R, CD-RW, magnetic tape, non-volatile type memory card, ROM, DVD (DVD-ROM, DVD-R), etc.
As for the method of supplying the program, a client computer can be connected to a website on the Internet using a browser possessed by the client computer, and the computer program of the present invention can be downloaded to a recording medium such as a hard disk. In this case, the program downloaded may be a file that is compressed and contains an automatic installation function. Further, implementation is possible by dividing the program codes constituting the program of the present invention into a plurality of files and downloading the files from different websites. In other words, a WWW server that downloads, to multiple users, the program files that implement the functional processing of the present invention by computer also is covered by the scope of the present invention.
Further, it is also possible to encrypt and store the program of the present invention on a storage medium such as a CD-ROM and distribute the storage medium to users. In this case, users who meet certain requirements are allowed to download decryption key information from a website via the Internet, the program decrypted using this key information can be executed and the program can be installed on a computer.
Further, besides implementing the functions of the embodiment by executing a read program using a computer, the functions of the embodiment may be implemented in cooperation with an operating system running on a computer, based upon commands from the program. In this case, the operating system, etc., executes some or all of the functions of actual processing and the functions of the above-described embodiments are implemented by this processing.
Furthermore, a program that has been read from a recording medium may be written to a memory provided on a function expansion board inserted into the computer or provided in a function expansion unit connected to the computer, and some or all of the functions of the embodiment may be implemented. In this case, after the program has been written to the function expansion board or function expansion unit, a CPU or the like provided on the function expansion board or function expansion unit performs some or all of the actual processing based upon the indications in the program.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2007-223091, filed Aug. 29, 2007, which is hereby incorporated by reference herein in its entirety.
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