KR20070025076A - Electric apparatus and control method thereof - Google Patents

Abstract

An electronic apparatus and a control method thereof are provided to delete function data recorded in a function processor when an external device cuts off communication between the function processor and a microcomputer in order to access the function processor, thereby basically cutting the external device off from accessing the function data recorded in the function processor. An electronic apparatus comprises the followings: a power unit(20) for outputting driving power to a plurality of function processors(10); a storage(30) for storing communication status information by intrinsic ID(Identification) of the plural function processors(10); and a controller(40). The controller(40) checks a communication status of the plural function processors(10) at initial driving time. According to the check result, the controller(40) stores each communication status of the plural function processors(10) in the storage(30) according to intrinsic ID of the plural function processors(10). The controller(40) continuously checks the communication status of the plural function processors(10). If the checked communication status information is inconsistent with the pre-stored communication status information by intrinsic ID, the controller(40) controls the power unit(20) so as to cut off output of the driving power.

Description

Electronic device and control method {Electric Apparatus And Control Method Thereof}

1 is a control block diagram of an electronic device according to the present invention;

2A and 2B are control flowcharts of an electronic device according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: a plurality of function processing unit 12: A / D converter

14 video decoder 16 scaler

20: power supply unit 22: power output unit

24: switching unit 30: EEPROM

40: micom

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device, and more particularly, to an electronic device and a control method thereof capable of blocking an external device from accessing functional data of a plurality of function processing units at its source.

In general, the electronic device includes a plurality of function processing units performing various functions, a controller connected to the plurality of function processing units through an I2C communication line, and controlling the plurality of function processing units. Here, the plurality of function processing units may include various circuit units according to the type of electronic device such as an A / D converter, a scaler, a deinterlacer, and the like.

Accordingly, the communication method between the controller of the conventional electronic device and the plurality of functional processors will be described below. First, at the initial stage of driving of the electronic device, the controller goes through a recognition process to recognize a plurality of function processing units connected to the controller, that is, to check a communication state of the plurality of function processing units. This recognition process is a process in which the controller repeats an operation of checking each function processing unit one by one, thereby identifying the function processing units connected to the controller. That is, the controller checks the first function processing unit among the plurality of function processing units, and if it is determined that the first function processing unit can communicate with the connected state, the controller initializes the first function processing unit. Thereafter, the controller checks the second function processing unit among the plurality of function processing units, and if it is determined that the second function processing unit can communicate in a state connected to the controller, initializes the second function processing unit. As such, the controller sequentially checks and initializes the plurality of function processing units one by one through a recognition process, and then controls the initialized function processing units. Accordingly, the conventional electronic device operates in a general driving state.

Here, the process of initializing the function processing units will be described in more detail. The controller prestores, in the form of function data corresponding to each function processing unit, a register value designed so that each of the plurality of function processing units can perform its corresponding function under the control of the controller. Therefore, the controller sequentially records the function processing unit determined to be communicable by recording the corresponding function data in the function processing unit determined to be communicable as a result of the check. At this time, the function processing unit stores the function data recorded by the controller in the memory RAM.

Here, the I2C communication used in the communication in the conventional electronic device as described above, in general, it is easy to read and copy data by connecting an external device. Therefore, the conventional electronic device cuts off I2C communication between the controller and the function processing unit in a normal driving state, and prevents an external device from copying the function data stored in the memory RAM of the function processing unit by accessing the function processing unit through the I2C communication line. Can not. That is, the conventional electronic device has a problem in that it is not possible to protect another person from taking the technical power of the functional data designed by investing a lot of time and money in the production company producing the electronic device.

Accordingly, it is an object of the present invention to provide an electronic device and a control method thereof capable of blocking an external device from accessing functional data of a plurality of function processing units at its source.

An object of the present invention is to provide an electronic device including a plurality of function processing units having a unique ID, comprising: a power supply unit for outputting driving power to the plurality of function processing units; A storage unit for storing communication state information for each unique ID of the plurality of function processing units; The communication state of the plurality of function processing units is checked at an initial stage of operation, and the communication state of each of the plurality of function processing units is stored in the storage unit for each unique ID of the plurality of function processing units according to the check result. And a control unit which controls the power supply unit to block the output of the driving power when the communication state of the processing unit is continuously checked and does not match the communication state information for each unique ID. do.

Here, the control unit, I2C communication with the plurality of function processing unit via the I2C communication line is preferable.

The control unit initializes a function processing unit in a communicable state and communicates with the initialized function processing unit based on the check result at the initial stage of driving, and communicates the communication state of the plurality of function processing units in the normal driving state with the I2C communication. If it is determined that it is not consistent with the pre-stored communication state information for each unique ID by continuously checking through a line, it is preferable to control the power supply unit to cut off the driving power provided to the plurality of function processing units.

On the other hand, according to another field of the present invention for achieving the above object, a plurality of function processing unit having a unique ID, a power supply unit for providing a driving power to the plurality of function processing unit, and a control unit for controlling the plurality of function processing unit A control method for an electronic device, comprising: checking, by the controller, a communication state of the plurality of function processing units at an initial stage of driving; Storing the communication states of each of the plurality of function processing units for each unique ID according to the check result; Initializing, by the controller, a function processing unit in a communicable state as a result of the check, and communicating with the initialized function processing unit; Continuously checking, by the controller, the communication state of the plurality of function processing units, and continuously determining whether the check result is identical to the previously stored communication state information for each unique ID; And when the check result does not match the communication status information for each unique ID, controlling the power supply unit to cut off the driving power provided to the plurality of function processing units by the control unit. It is achieved by the control method of the electronic device.

Here, the control unit, it is preferable to check the communication state of the plurality of function processing unit through the I2C communication line and communicate with the initialized function processing unit.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a control block diagram of an electronic device according to an exemplary embodiment of the present disclosure. As shown in the figure, the electronic device according to the present invention includes a plurality of function processing units 10, a power supply unit 20, a microcomputer 40, and an EEPROM 30. Here, as shown in the figure, it is preferable that the microcomputer 40 and the plurality of function processing units 10 of the electronic device of the present invention communicate with each other through the I2C communication line.

The plurality of function processing units 10 are circuit units provided to perform an operation of the electronic device, and may include various circuit units according to the type of the electronic device. In FIG. 1, in consideration of the case where the electronic device of the present invention is a display device such as a television, the plurality of function processing units 10 are provided with the A / D converter 12, the video decoder 14, and the scaler 16. As shown in FIG. Shows the configuration to include. Of course, the plurality of function processors 10 may include more function processors (not shown) in addition to the A / D converter 12, the video decoder 14, and the scaler 16, for example, an electronic device. When the sound function has a sound function, the plurality of function processing units 10 may include a sound decoder (not shown) and a sound processing unit (not shown) that are not shown in FIG.

Here, the A / D converter 12, the video decoder 14, and the scaler 16 each have their own unique ID. In addition, the A / D converter 12, the video decoder 14, and the scaler 16 are provided with a memory RAM (not shown) that stores its own function data recorded by the microcomputer 40. FIG.

The power supply unit 20 supplies driving power to the A / D converter 12, the video decoder 14, and the scaler 16, respectively. The power supply unit 20 is output from the power output unit 22 and the power output unit 22 for outputting the driving power for providing to the A / D converter 12, the video decoder 14 and the scaler 16 A / D converter 12, a video decoder 14 and a switching unit 24 for intermitting the driving power provided to the scaler 16 is included. That is, the switching unit 24 may output or block the driving power output from the power output unit 20 to the plurality of function processing units 10 under the control of the microcomputer 40.

The EEPROM 30 is a storage unit for storing predetermined information, and serves to store communication state information for each unique ID of the plurality of function processing units 10. For example, when the unique ID of the A / D converter 12 is "0A", the unique ID of the video decoder 14 is "0B", and the unique ID of the scaler 16 is "0C", the EEPROM 30 In accordance with the check result initially checked by the microcomputer 40 will store the communication status information for each unique ID as shown in Table 1.

Table 1.

Unique ID Communication status information 0A 1 OR 0 0B 1 OR 0 0C 1 OR 0

The microcomputer 40 is provided as a control unit for controlling the power supply unit 20, the plurality of function processing units 10, and the EEPROM 30. The microcomputer 40 performs a recognition process in order to recognize a function processing unit connected to itself, that is, to check a communication state of the plurality of function processing units 10 at the beginning of driving of the electronic device according to the present invention. In this recognition process, the microcomputer 40 repeatedly checks each function processing unit of the plurality of function processing units 10 one by one, so that the microcomputer 40 has the function processing units 12, 14, and 16 connected thereto. Is the process of figuring out. The microcomputer 40 stores the communication status of each of the function processing units 12, 14, and 16 identified by the check result of the recognition process in the EEPROM 30 for each unique ID.

On the other hand, the microcomputer 40 has a register value designed so that each of the function processing unit 12, 14, 16 can perform its corresponding function under the control of the microcomputer 40, each function processing unit (12, 14, 16). It is stored in the form of function data corresponding to).

Here, the recognition process performed at the beginning of driving the above-mentioned electronic device will be described in more detail.

First, the microcomputer 40 outputs a check signal for checking the communication status of the A / D converter 12 at the beginning of driving, and the A / D converter 12 outputs a corresponding response signal to the microcomputer 40. do. Accordingly, when the response signal is received from the A / D converter 12, the microcomputer 40 determines that the A / D converter 12 is mounted and capable of communication, and corresponds to the prestored A / D converter 12. The function data is stored in the memory RAM (not shown) of the A / D converter 12 to initialize the A / D converter 12. On the other hand, when the response signal is received from the A / D converter 12, the microcomputer 40 communicates the communication status information of the EEPROM 30 corresponding to the unique ID (0A) of the A / D converter 12 included in the response signal. Record as "1". Of course, if a predetermined time elapses after the response signal is not received from the A / D converter 12, the microcomputer 40 determines that the A / D converter 12 is not mounted and initializes the A / D converter 12. Instead, the communication status information of the EEPROM 30 corresponding to the unique ID (0A) of the A / D converter 12 is recorded as "0".

After checking the A / D converter 12, the microcomputer 40 outputs a check signal for checking the communication status of the video decoder 14, and the video decoder 14 outputs a response signal corresponding thereto. ) Accordingly, when the response signal is received from the video decoder 14, the microcomputer 40 determines that the video decoder 14 is mounted and can communicate with the video decoder 14, and the corresponding function data corresponding to the previously stored video decoder 14 is stored in the video. The video decoder 14 is initialized by writing to a memory RAM (not shown) of the decoder 14. On the other hand, when the response signal is received from the video decoder 14, the microcomputer 40 sets the communication status information of the EEPROM 30 corresponding to the unique ID (0B) of the video decoder 14 included in the response signal to "1". Record as.

Of course, if a predetermined time elapses after the response signal is not received from the video decoder 14, the microcomputer 40 determines that the video decoder 14 is not mounted and does not initialize the video decoder 14. Communication status information of the EEPROM 30 corresponding to the unique ID (0B) of 14) is recorded as " 0 ".

After checking the video decoder 14, the microcomputer 40 outputs a check signal for checking the communication state of the scaler 16, and the scaler 16 outputs a corresponding response signal to the microcomputer 40. . Accordingly, when the response signal is received from the scaler 16, the microcomputer 40 determines that the scaler 16 is mounted to communicate with the scaler 16. The scaler 16 stores corresponding function data corresponding to the stored scaler 16. The memory 16 is initialized by writing to a memory RAM (not shown). On the other hand, when the response signal is received from the scaler 16, the microcomputer 40 records the communication status information of the EEPROM 30 corresponding to the unique ID (0C) of the scaler 16 included in the response signal as "1". do.

Of course, when the predetermined time elapses without the response signal from the scaler 16, the microcomputer 40 determines that the scaler 16 is not mounted and does not initialize the scaler 16, and thus the intrinsic value of the scaler 16 is not generated. The communication state information of the EEPROM 30 corresponding to the ID (0C) is recorded as "0".

As such, the microcomputer 40 stores the result of checking the communication state of the plurality of function processing units 10 through the recognition process at the initial stage of driving of the electronic device in the EEPROM 30 as communication state information for each unique ID as shown in Table 1 below. And communicate with the initialized function processor to control the function processor. Accordingly, the electronic device of the present invention operates in a general driving state.

On the other hand, the microcomputer 40 continuously checks the communication state of the plurality of function processing units 10 during normal driving in communication with the initialized function processing unit to control the initialized function processing unit. That is, the microcomputer 40 continuously checks the state in which the plurality of function processing units 10 are connected to the microcomputer 40 itself even during normal driving.

As described above, the microcomputer 40 sequentially checks the communication state of the plurality of function processing units 10 by the A / D converter 12, the video decoder 14, and the scaler 16. The microcomputer 40 checks whether the signal is repeatedly output and the response signal corresponding to each check signal is received.

Of course, the microcomputer 40 does not output a separate check signal to the A / D converter 12, the video decoder 14, and the scaler 16. 12) through the operation of controlling the video decoder 14 and the scaler 16, the communication state of the plurality of function processing units 10 can be checked to some extent.

Accordingly, the microcomputer 40 continuously checks the communication state of the plurality of function processing units 10 and compares the check result checked during normal operation with communication state information for each unique ID previously stored in the EEPROM 30.

The microcomputer 40 controls the switching unit 24 to block the output of the driving power when the check result checked during normal operation does not match the communication state information for each unique ID. As a result, the driving power provided to the plurality of function processing units 10 is cut off, so that the function data recorded in the memory RAM (not shown) which has been initialized and operated is deleted.

Here, when the check result checked during normal operation does not match the communication status information for each unique ID, the unique state recorded as "1" in the communication status information for each unique ID of the EEPROM 30 through the recognition process at the initial stage of driving. This corresponds to a case where the function processing unit (A / D converter 12) having an ID (for example, 0A) is disconnected from the microcomputer 40 during the normal operation, and thus the microcomputer 40 does not check even if the microcomputer 40 checks during the normal operation. Of course, the case where the function processing unit of the unique ID, which is recorded as "0" in the communication status information for each unique ID, is newly connected to the microcomputer 40 during the normal operation, and the microcomputer 40 checks and checks the normal operation. In general, however, the electronic device does not additionally connect a new function processing unit in a general driving state, and thus it is not considered.

Thus, the microcomputer 40 preferably checks only the function processing unit (eg, 12, 14, 16) that is initialized, that is, the function processing unit in which communication status information is recorded as "1".

The electronic device of the present invention having the configuration as described above, when the communication between the function processing unit and the microcomputer 40, which is initialized at the initial stage of driving and operates with the corresponding function data, during the normal operation, is interrupted, provides the driving power provided to the function processing unit. Block it. Therefore, the electronic device of the present invention deletes the function data recorded in the function processing unit when the communication between the function processing unit and the microcomputer 40 is terminated so that the external device connects to the function processing unit. You can block access to your data.

Accordingly, the electronic device of the present invention effectively solves the conventional problem that it is not possible to protect another person from taking the technical power of the functional data designed by investing a lot of time and money at the production company producing the electronic device.

Here, the control flow of the electronic device according to the present invention will be described with reference to FIGS. 2A and 2B.

Prior to the description, the microcomputer 40 may register a register value designed for each of the function processing units 12, 14, and 16 to perform its corresponding function under the control of the microcomputer 40. 16 is stored in the form of function data corresponding to (16).

First, when the driving of the electronic device starts, the microcomputer 40 checks the A / D converter 12 by outputting a check signal for checking the communication state of the A / D converter 12 at the beginning of driving (S10). . Accordingly, the microcomputer 40 determines whether a response signal is received from the A / D converter 12 (S20). When the response signal is received, the communication status information of the EEPROM 30 corresponding to the unique ID (0A) of the A / D converter 12 included in the response signal is recorded as "1" (S70). Here, when a predetermined time elapses without the response signal from the A / D converter 12, the microcomputer 40 determines that the A / D converter 12 is not mounted, and determines that the A / D converter 12 is not installed. The communication state information of the EEPROM 30 corresponding to the unique ID (0A) is recorded as "0" (S80). On the other hand, although not shown in FIG. 2A, when the response signal is received from the A / D converter 12, the microcomputer 40 determines that the A / D converter 12 can communicate, and stores the A / D previously stored. The function data corresponding to the converter 12 is recorded in the memory RAM (not shown) of the A / D converter 12 to initialize the A / D converter 12.

After checking the A / D converter 12, the microcomputer 40 outputs a check signal for checking the communication status of the video decoder 14 to check the video decoder 14 (S30). Accordingly, the microcomputer 40 determines whether a response signal is received from the video decoder 14 (S40). When the response signal is received, communication state information of the EEPROM 30 corresponding to the unique ID (0B) of the video decoder 14 included in the response signal is recorded as "1" (S70). Here, when a predetermined time elapses after the response signal is not received from the video decoder 14, the microcomputer 40 determines that the video decoder 14 is not mounted, and the microcomputer 40 determines the unique ID (0B) of the video decoder 14. The communication state information of the corresponding EEPROM 30 is recorded as "0" (S80). On the other hand, although not shown in FIG. 2A, when the response signal is received from the video decoder 14, the microcomputer 40 determines that the video decoder 14 is capable of communication and stores the video decoder 14 in a pre-stored video decoder 14. The corresponding function data is recorded in a memory RAM (not shown) of the video decoder 14 to initialize the video decoder 14.

After checking the video decoder 14, the microcomputer 40 checks the scaler 16 by outputting a check signal for checking the communication state of the scaler 16 (S50). Accordingly, the microcomputer 40 determines whether a response signal is received from the scaler 16 (S60). When the response signal is received, communication status information of the EEPROM 30 corresponding to the unique ID (0C) of the scaler 16 included in the response signal is recorded as "1" (S70). Here, when a predetermined time elapses after the response signal is not received from the scaler 16, the microcomputer 40 determines that the scaler 16 is not mounted, and the EEPROM corresponding to the unique ID (0C) of the scaler 16 is determined. The communication state information of 30 is recorded as "0" (S80). Although not shown in FIG. 2A, when the response signal is received from the scaler 16, the microcomputer 40 determines that the scaler 16 is capable of communication, and corresponding functions corresponding to the stored scaler 16. The data is written to a memory RAM (not shown) of the scaler 16 to initialize the scaler 16.

Through this process, the microcomputer 40 repeatedly checks the plurality of function processing units 10 one by one, recognizes and initializes the function processing unit connected to the microcomputer 40 itself, and is identified by the check result. The communication state of the function processing unit is stored in the EEPROM 30 for each unique ID.

Thereafter, the microcomputer 40 communicates with the initialized function processor to control the function processor. Accordingly, the electronic device of the present invention operates in a general driving state.

On the other hand, the microcomputer 40 communicates with the initialized function processing unit to control the initialized function processing unit, i.e., after checking the plurality of function processing units 10 (①), Check the communication status continuously. At this time, the microcomputer 40 preferably checks only the initialized function processing unit (eg, 12, 14, 16). Here, the continuous check will be described with reference to Fig. 2B.

The microcomputer 40 checks the plurality of function processing units 10 at the initial stage of driving (①), and determines whether the unique ID of the A / D converter 12 is checked (S120). This determination is performed by the microcomputer 40 by outputting a separate check signal for checking the communication state and outputting it to the A / D converter 12, or by performing a general control operation of controlling the A / D converter 12. Judgment can also be made. The microcomputer 40 has a unique ID of the A / D converter 12 stored in the EEPROM 30 if the unique ID of the A / D converter 12 is not checked, that is, if communication with the A / D converter 12 is not performed. It is determined whether the communication state information of (0A) is "1" (S170). When the communication state information is "1", the microcomputer 40 determines that communication with the A / D converter 12 that was initially available for communication is interrupted, and controls the switching unit 24 to block the provision of the driving power. (S180). Thus, the plurality of function processing units 10 are turned off, and the function data of the function processing units 12, 14 and 16 which are initialized and operated are deleted.

As a result of the determination, when the unique ID of the A / D converter 12 is checked, the microcomputer 40 determines whether the unique ID of the video decoder 14 is checked (S140). This determination may be determined by the microcomputer 40 outputting a separate check signal for checking the communication state and outputting it to the video decoder 14, or through a general control operation of controlling the video decoder 14. can do. When the unique ID of the video decoder 14 is not checked, that is, when the communication with the video decoder 14 is not performed, the microcomputer 40 communicates with the unique ID (0B) of the video decoder 14 stored in the EEPROM 30. It is determined whether the information is "1" (S170). When the communication state information is "1", the microcomputer 40 determines that communication with the video decoder 14 that has been able to communicate at the initial stage of driving is interrupted, and controls the switching unit 24 to block the provision of the driving power ( S180). Thus, the plurality of function processing units 10 are turned off, and the function data of the function processing units 12, 14 and 16 which are initialized and operated are deleted.

As a result of the determination, when the unique ID of the video decoder 14 is checked, the microcomputer 40 determines whether the unique ID of the scaler 16 is checked (S160). Such determination may be determined by the microcomputer 40 outputting a separate check signal for checking the communication state and outputting the output to the scaler 16, or through a general control operation of controlling the scaler 16. If the unique ID of the scaler 16 is not checked, that is, if communication with the scaler 16 is not made, the communication state information of the unique ID (0C) of the scaler 16 stored in the EEPROM 30 is "". It is determined whether 1 "(S170). If the communication state information is "1", the microcomputer 40 determines that communication with the scaler 16 that has been able to communicate at the initial stage of driving is interrupted, and controls the switching unit 24 to block the provision of the driving power (S180). ). Thus, the plurality of function processing units 10 are turned off, and the function data of the function processing units 12, 14 and 16 which are initialized and operated are deleted.

Here, as a result of the determination (S170), when the pre-stored communication state information of the A / D converter 12 or the video decoder 14 or the scaler 16 is not "1", that is, "0", the initial driving is performed. Since the A / D converter 12 or the video decoder 14 or the scaler 16 is not connected to the microcomputer 40, it will not be considered.

As a result of the determination, when the unique ID of the scaler 16 is checked, the microcomputer 40 performs the operation S120 again to perform the initialized function processing unit (eg, 12, 14, 16). The check repeats the operation.

Therefore, the control method of the electronic device according to the present invention as described above, when the communication between the function processing unit and the microcomputer 40, which is initialized at the initial stage of driving and operates with the corresponding function data, during normal operation, is provided to the function processing unit. Shut off the power. Accordingly, the control method of the electronic device of the present invention deletes the function data recorded in the function processing unit when the communication between the function processing unit and the microcomputer 40 is terminated so that the external device connects to the function processing unit. Access to recorded functional data can be blocked at source.

As described above, the electronic device and the method for controlling the electronic device according to the present invention can not protect others from taking the technical power of the functional data designed by investing a lot of time and money in the production company producing the electronic device. Solves the problem effectively.

As described above, according to the present invention, it is possible to provide an electronic device and a control method thereof capable of blocking an external device from accessing data of a plurality of function processing units.

Claims (5)

An electronic device comprising a plurality of function processing units having a unique ID, A power supply unit for outputting driving power to the plurality of function processing units; A storage unit for storing communication state information for each unique ID of the plurality of function processing units; The communication state of the plurality of function processing units is checked at an initial stage of operation, and the communication state of each of the plurality of function processing units is stored in the storage unit for each unique ID of the plurality of function processing units according to the check result. And a controller which continuously checks the communication state of the processor and controls the power unit to block the output of the driving power when the communication state of the processor does not match the pre-stored communication state information for each unique ID. The method of claim 1, The control unit, And an I2C communication with the plurality of functional processors through an I2C communication line. The method of claim 2, The control unit, Initially, based on the check result, the function processing unit in a communicable state is initialized to communicate with the initialized function processing unit, and during the normal driving, the communication state of the plurality of function processing units is continuously checked through the I2C communication line. If it is determined that it does not match the pre-stored communication status information for each unique ID, the electronic device characterized in that for controlling the power supply unit to cut off the driving power provided to the plurality of function processing unit. A control method of an electronic device comprising a plurality of function processing units having a unique ID, a power supply unit for supplying driving power to the plurality of function processing units, and a control unit controlling the plurality of function processing units, Checking, by the control unit, a communication state of the plurality of function processing units at the initial stage of driving; Storing the communication states of each of the plurality of function processing units for each unique ID according to the check result; Initializing, by the controller, a function processing unit in a communicable state as a result of the check, and communicating with the initialized function processing unit; Continuously checking, by the controller, the communication state of the plurality of function processing units, and continuously determining whether the check result is identical to the previously stored communication state information for each unique ID; And when the check result and the communication state information for each unique ID do not match, controlling the power supply unit to block driving power provided to the plurality of function processing units by the control unit. A control method of an electronic device. The method of claim 4, wherein The controller checks the communication state of the plurality of function processing units through an I2C communication line and communicates with the initialized function processing unit.

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