KR101469182B1 - An apparatus and method for booting with images - Google Patents

Abstract

The present invention provides an image processing apparatus comprising: an image generation unit for generating a snapshot image; A service unit for executing the service; A storage unit for storing the snapshot image; And a control unit for controlling the image generating unit, the service unit, and the storage unit to execute the service, generating a snapshot image including only the service without the set value of the service, and storing the snapshot image A snapshot image generating device and a booting device. Therefore, since the snapshot image having a small size is generated, the present invention has the effect of shortening the snapshot image creation time and boot time.

Description

[0001] The present invention relates to an apparatus and method for booting images,

The present invention relates to an apparatus and method for creating and booting a snapshot image, and more particularly, to an apparatus and method for creating and booting a snapshot image including only a service without changing a set value.

If execution speed is very slow or frequent errors occur, the user must format the storage device in use and reinstall the program. However, when formatting the storage device and reinstalling the program, it takes a lot of time and the user is very inconvenient. Therefore, when the device is normally operating, the file or data stored in the storage device is backed up, and when restoration of data is required, the user can restore the data based on the backed-up data.

In recent years, the snapshot function described above has been used not only to conveniently restore data but also to boot the system. For example, when a signal for executing the snapshot function is input, the snapshot image processing apparatus generates a snapshot image containing data stored in the memory and stores the snapshot image in the storage device. Each time a signal for executing the snapshot function is input, snapshot images can be created and stored in the storage device. Thereafter, when a signal for booting the system is inputted, the snapshot image processing apparatus can boot the system by loading the snapshot image stored in the storage device into the memory. Accordingly, the user can easily restore the booting to the system state used at a specific point in time (when the signal for executing the snapshot function is input) by using the snapshot function. The use of snapshot images in this way is called hibernation.

The snapshot function is also applied to a mobile communication terminal or a set-top box (STB). On the other hand, the use of set-top boxes is also increasing as set-top boxes become more popular due to the spread of household cable or satellite broadcasting. Therefore, there is a need to reduce the power consumption of the set-top box. In order to reduce the power consumed by the boot by shortening the time of the conventional boot, quick boot using the above snapshot image is required in the set-top box.

However, if the size of the snapshot image is large and the data input / output speed is slow, it may take a long time to load the snapshot image and restore the data.

As an example for solving the above problems, Korean Patent Laid-Open Publication No. 2002-0055352 A discloses a boot device and method using a snapshot image. The patent publication discloses a method of loading a snapshot image and booting the snapshot image, which is compressed by the image generation unit 102 to shorten boot time. However, the above-mentioned patent publication also discloses that the snapshot image information is not only a service having no set value (for example, an application whose set contents are not updated and unchanged) but also a service having set values (for example, Changing applications). Therefore, the capacity of the snapshot image becomes large and the loading time becomes long, so that the boot time becomes long.

It is an object of the present invention to provide an apparatus and a method for creating and booting a snapshot image for shortening the time for generating a snapshot image.

It is another object of the present invention to provide an apparatus and method for creating and booting a snapshot image for shortening a boot time using a snapshot image.

It is still another object of the present invention to provide an apparatus and method for creating and booting a snapshot image that does not go through a duplicated boot step.

In one aspect of the present invention, an image generating unit for generating a snapshot image; A service unit for executing the service; A storage unit for storing the snapshot image; And a control unit for controlling the image generating unit, the service unit, and the storage unit to execute the service, generating a snapshot image including only a service having no set value among the services, and storing the snapshot image And a snapshot image generating device.

Preferably, the service unit executes only the service without the set value.

Preferably, the snapshot image is compressed and stored in the storage unit.

Preferably, the image generating unit regenerates a snapshot image including the changed set-value-free service when the set-value-free service is changed.

According to another aspect of the present invention, there is provided a method of generating a snapshot image, the apparatus comprising: a first step of detecting a boot event; A second step of executing a boot according to the boot event and making a service state capable of executing a service; A third step of executing the service; And a fourth step of generating a snapshot image containing only the service without the set value; And a fifth step of storing the snapshot image.

Preferably, the third step is a step of executing only the service without the set value.

Preferably, the fifth step is a step of compressing and storing the snapshot image.

Preferably, the method further comprises a sixth step of regenerating and storing the snapshot image including the changed service without the set value if the service without the set value is changed.

According to another aspect of the present invention, there is provided a storage system including a storage unit storing a snapshot image including a service without a set value; And a boot loader for executing the snapshot image during boot initialization standby; A kernel for executing boot initialization after the snapshot image is executed; And a control unit for extracting the snapshot image from the storage unit, loading the extracted snapshot image into the boot loader, and controlling the boot by controlling the boot loader and the kernel. to provide.

Preferably, the service unit further includes a service unit that executes a service, wherein the control unit controls the service unit to execute a service having a set value, and provides an apparatus for generating and booting a snapshot image.

Preferably, the snapshot image includes an interruption point of the boot initialization of the kernel, and provides a device for generating and booting a snapshot image.

Preferably, the controller controls the kernel to perform a boot initialization from an interruption point of the boot initialization.

In yet another aspect of the present invention, there is provided a method of booting a boot device for generating and booting a snapshot image, the method comprising: detecting a boot event; waiting for a boot initialization corresponding to the event; Executing a snapshot image including a service without a waiting value of the boot initialization; Executing boot initialization; And executing a service having a set value after the boot initialization is completed. The present invention provides a method for generating a snapshot image and booting the snapshot image.

Preferably, the snapshot image includes an interruption point of a boot initialization, and provides a method of generating and booting a snapshot image.

Preferably, boot initialization is executed from an interruption point of the boot initialization, and a method of booting a snapshot image is provided.

Preferably, a program for executing a method of generating a snapshot image by the resolution means is recorded and a computer-readable recording medium is provided.

Preferably, a program for executing a method for creating and booting a snapshot image by the resolution means is recorded, and a computer-readable recording medium is provided.

Since the present invention generates a snapshot image having a small size, the time for generating the snapshot image is shortened.

In addition, the present invention has the effect of shortening the boot time because it boots using a snapshot image of a small size.

In addition, the present invention has the effect of efficiently using resources of the booting device without burdening the booting device because it does not go through a duplicated booting step.

1 is a diagram illustrating a conventional boot device and method using a snapshot image.
FIG. 2 is a block diagram illustrating an apparatus for generating a snapshot image and an apparatus for generating and booting a snapshot image according to an exemplary embodiment of the present invention. Referring to FIG.
FIG. 3 is a flowchart illustrating a snapshot image generation process of a snapshot image generation device and a device for generating and booting a snapshot image according to a preferred embodiment of the present invention.
FIG. 4 is a flowchart illustrating a snapshot image generation process of a snapshot image generation apparatus and a device for generating and booting a snapshot image according to a preferred embodiment of the present invention.
5 is a flowchart illustrating a booting method of a boot device using a snapshot image according to an exemplary embodiment of the present invention.
FIG. 6 is a flowchart illustrating a detailed method of booting a device for generating and booting a snapshot image according to an exemplary embodiment of the present invention. Referring to FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. In order to facilitate a thorough understanding of the present invention, the same reference numerals are used for the same means regardless of the number of the drawings.

FIG. 2 is a block diagram illustrating an apparatus for generating a snapshot image and an apparatus for generating and booting a snapshot image according to an exemplary embodiment of the present invention. Referring to FIG.

2, the apparatus for creating and booting a snapshot image and the snapshot image includes a storage unit 210, a service unit 220, an image generation unit 230, a boot loader 240, a kernel 250 And a control unit 260. As shown in FIG.

The snapshot image generating device is a device included in the device for generating and booting the snapshot image, and is a device not including only a boot function. Both of them generate the snapshot image in the same way and have the same configuration. Accordingly, the following description will be made on the basis of a device for generating and booting the snapshot image, but the above description is also applied to the snapshot image generation device.

A device for booting by creating a snapshot image can be applied to various terminals that require an operating system (OS). For example, the terminal may be a computer, a smart phone, a digital TV, a set-top box, and an MP3 player that require loading of the initialization routine using the boot loader 240 and the kernel 250 when the power is turned on And the like.

In particular, the device for creating and booting the snapshot image may be a terminal supporting a hibernation function. Typically, a terminal supporting the hibernation function is a set-top box. Hibernation means booting from a snapshot image. The snapshot image refers to the packaged data when the data for booting is packaged in a nonvolatile memory to a predetermined standard and the packaged data is loaded into the volatile memory while booting. When the hibernation function is executed, that is, when booting is performed using the snapshot image, the device for creating and booting the snapshot image restores the existing system state to the system state according to the packaged data.

The storage unit 210 stores all the services including the set value service and the set value service and stores the generated snapshot image. The storage unit 210 may be a volatile memory and / or a non-volatile memory. Since the created snapshot image that is once created must be continuously used and stored frequently or intermittently at boot time, the storage unit 210 stores the snapshot image in the nonvolatile memory. The storage unit 210 stores the service in the nonvolatile memory since the service is also executed when the booting apparatus operates after booting.

The service is software or an application for operating a device for generating and booting the snapshot image. For example, a graphic driver of a PC implements a PC monitor with a color of a predetermined resolution that the graphic service can support, and a camera driver implements a camera (cam) provided in the PC to operate. The graphic driver, the camera driver, and the like that implement the operation of the device correspond to the service. In addition, a graphical user interface tool that displays information on the screen by receiving information from the Internet without using an Internet browser, such as a desktop, a toolbar containing a collection of frequently used items, a clock or calendar, a notepad, search, GUI) widgets, Bluetooth, WiFi, LTE, and the like. That is, the service includes all the other components that control the device that generates and boots the snapshot image as well as the contents information of the memory, the application to be executed and data related thereto.

The service includes a service without set value and a service with set value.

The service without the set value is a service which is not changed by the user. For example, the above-mentioned device driver (such as a graphic driver and a camera driver) and other components that control the device correspond to the service without the set value. The service without the set value is reflected in the snapshot image in the form of the packaged data in order to restore the system state of the booting device by generating the snapshot image and referring to the definition of the snapshot image.

The set value service is a service that is frequently changed by the user. For example, Widgets, Network. A toolbar, a desktop, and the like correspond to the set value service. The set value service is reloaded after booting using the snapshot image.

The service unit 220 is controlled by the control unit 260 and executes the service. The service unit 220 implements the service state for executing the service and executes the service. The service unit 220 executes both the service without set value and the service with set value. The service unit 220 functions as a kind of operating system and receives an operation signal and a service to be executed from the control unit 260 and executes the service.

The service unit 220 receives the service unit status data request signal from the image generation unit 230 and transmits the service unit status data to the image generation unit 230 in order to generate the snapshot image.

The image generation unit 230 is controlled by the control unit 260 and generates a snapshot image. The image generating unit 230 receives the operation signal and the snapshot image generating signal from the control unit 260 after the service unit 220 executes the service without the set value. The image generation unit 230 transmits a service status data request signal and a kernel status data request signal to the service unit 220 and the kernel 250, respectively.

The image generation unit 230 receives the service status data from the service unit 220 and receives the kernel status data from the kernel 250. Then, the image generating unit 230 generates the snapshot image including the kernel state data and the service state data. The image generation unit 230 transmits the generated snapshot image to the storage unit 210. The image generating unit 230 may compress the generated snapshot image, reduce the size thereof, and store the reduced snapshot image in the storage unit 210.

The image generating unit 230 may regenerate the snapshot image including the changed service without the set value if the service without the set value is changed. The snapshot image is repeatedly used once it is created, and booting is performed corresponding to the snapshot image. However, there is a case where a user wants to change a snapshot image accordingly by adding, deleting, or updating a service without a set value to be reflected in the snapshot image. At this time, when the user inputs the service change information without the set value, the image generator 230 receives the set change value service change information and regenerates the snapshot image accordingly.

The kernel state data refers to the kernel process state until the kernel 250 receives the request signal. Here, the point of the kernel process in which the kernel 250 receives the request signal and stops execution is referred to as an interruption point, and the kernel process at this time is referred to as an interruption point kernel process. The interruption point kernel process becomes a resuming point at which the kernel process is resumed at boot time using the snapshot image. The kernel state data includes data relating to the breakpoint and breakpoint kernel processes.

The service status data refers to the service execution status until the service unit 220 receives the request signal. The service execution state refers to a state in which a service having no set value and / or a service having a set value are executed.

The snapshot image includes kernel state data and service state data.

The boot loader 240 is a code that is executed first when a specific system is started, and is responsible for initializing the device. This is for the main CPU to initialize the peripheral processing apparatus so that smooth communication can be achieved. Accordingly, the boot loader 240 is composed of various codes for initializing the device, and the code is initially written in an assembly which is a low-level language. The execution of the boot loader 240 such as the initialization of the device is referred to as a boot initialization wait. In addition, the boot loader 240 copies the Ramdisk to the volatile memory (RAM). When the boot loader 240 finishes initializing the device, the boot loader 240 transmits a kernel operation signal to operate the kernel 250.

The boot loader 240 also executes the snapshot image loaded by the control unit 260 when booting is performed using the snapshot image. Execution of the snapshot image is done by copying the snapshot image to a volatile memory (e.g., RAM). When the snapshot image is compressed, the boot loader 240 copies the image to the volatile memory, decompresses it, and executes it. Thereafter, the boot loader 240 transmits a kernel operation signal to the kernel 250, extracts a service without a set value from the executed snapshot image, and transmits the extracted service to the service unit 220.

The kernel 250 implements a state that the operating system can execute. The kernel 250 inspects the device (hard disk, network adapter, floppy disk, etc.) initialized by the boot loader 240 and sets a device driver. In addition, the kernel 250 sets a Ramdisk copied to the volatile memory. The execution of the operation by the kernel 250 is referred to as a boot initialization. Hereinafter, in the present invention, the kernel 250 operates a service unit 220 that functions as an operating system.

When the snapshot image is generated, the kernel 250 receives the kernel status data request signal from the image generation unit 230 and transmits the kernel status data to the image generation unit 230.

When the boot process is executed using the snapshot image, the kernel 250 generates the snapshot image based on the service status data and the kernel status data included in the snapshot image, Restore.

The control unit 260 controls the storage unit 210, the service unit 220, the image generation unit 230, the boot loader 240, and the kernel 250.

In generating the snapshot image, the controller 260 detects a boot event through on-off of a power source and causes the boot loader 240 to execute a boot initialization wait. After the boot initialization, the control unit 260 extracts the service without the set value from the storage unit 210 and operates the service unit to transmit the service without the set value.

In generating the snapshot image, the control unit 260 detects a boot event through on-off of the power source, and causes the boot loader 240 to execute a boot initialization wait. The control unit 260 extracts the snapshot image from the storage unit 210 and loads the extracted snapshot image into the boot loader 240. After the snapshot image is executed, the control unit 260 extracts the set value service from the storage unit 210 and transmits the service to the service unit 220.

Hereinafter, a method for generating a snapshot image of a device booting using the snapshot image will be described.

FIG. 3 is a flowchart illustrating a snapshot image generation process of a snapshot image generation device and a device for generating and booting a snapshot image according to a preferred embodiment of the present invention.

Referring to FIG. 3, in step S301, the controller 260 detects a boot event through on-off detection of power.

In step S303, when the boot event is detected and the power is turned on, the control unit 260 transmits a boot loader operation signal to the boot loader 240 so that the boot loader 240 executes the boot initialization wait.

In step S305, the boot loader 240 receiving the boot loader operation signal executes a boot initialization wait.

In step S307, the boot loader 240 transmits a kernel operation signal to the kernel 250 so that the kernel 250 performs boot initialization when the boot initialization wait time is over.

In step S309, the kernel 250 receiving the kernel operation signal performs boot initialization.

In step S311 and step S313, when the boot initialization is completed, the controller 260 extracts a service without a set value from the storage unit 210 and transmits the set value free service and service part operation signal to the service unit 220 .

In step S315, the service unit 220 receiving the service unit operation signal executes the received service without setting value.

In operation S317, when the service unit 220 is operated, the control unit 260 transmits a snapshot image generation signal to operate the image generation unit 230 to generate the snapshot image.

In steps S319 and S321, the operated image generating unit 230 sends each request signal to the kernel 250 and the service unit 220 to include the kernel state data and the service state data in the snapshot image .

In step S323 and step S325, the image generation unit 230 receives the kernel status data and the service status data from the kernel 250 and the service unit 220, respectively.

If the service change information without the set value is input, the image generating unit 230 may change the service state data according to the change information (not shown). As a result, when the snapshot image generation step is performed, the snapshot image is regenerated to be different from the previously generated snapshot image.

In step S327, the image generating unit 230 generates the snapshot image. Referring to FIG. 4, step S327 in which the image generating unit 230 generates the snapshot image will be described in detail. 4 is a detailed flowchart illustrating a snapshot image generation process of the snapshot image generation apparatus according to an exemplary embodiment of the present invention. It is to be noted that the state of step S327 is a state in which the boot initialization and service unit (OS, operating system) are executed and only the service without the set value is executed and the snapshot image generation signal is received from the control unit 260. [

Referring to FIG. 4, in steps S401 and S403, the image generating unit 230 stops the kernel process, the memory and the device, and powers down to prepare for the snapshot image generation. The power down means that the power is not completely turned off and is lowered to a minimum power state for generating the snapshot image. In step S405, the kernel process that has been executed so far is stored. The kernel process in step S405 is recognized as a resuming point of the kernel 250 at boot time using the snapshot image. In step S407, the kernel state data and the service state data are packaged to generate the snapshot image. In steps S409 and S411, the power and the memory and the device are resumed to complete the snapshot image generation. Thereafter, the device for generating and booting the snapshot image reboots.

In step S329, the image generation unit 230 stores the generated snapshot image in the storage unit 210. In step S329,

Hereinafter, a booting method of a boot device using the generated snapshot image will be described.

5 is a flowchart illustrating a booting method of a boot device using a snapshot image according to an exemplary embodiment of the present invention.

Referring to FIG. 5, in step S501, the controller 260 detects a boot event through on-off detection of power.

In step S503, when the boot event is detected and the power is turned on, the control unit 260 transmits a boot loader operation signal to the boot loader 240 so that the boot loader 240 executes the boot initialization wait.

In step S505, the boot loader 240 receiving the boot loader operation signal waits for boot initialization.

In step S507 and step S509, the controller 260 extracts the snapshot image from the storage unit 210 and loads the snapshot image into the boot loader 240 while the boot initialization wait is being executed.

In step S511 and step S513, the boot loader 240 loaded with the snapshot image executes the snapshot image and transmits a kernel operation signal to the kernel 250. [

In step S515, the kernel 250 receiving the kernel operation signal executes boot initialization from the interruption point kernel process included in the snapshot image.

Referring to FIG. 6, the steps S511 to S515 will be described in detail. FIG. 6 is a flowchart illustrating a detailed method of booting a device for generating and booting a snapshot image according to an exemplary embodiment of the present invention. Referring to FIG. Referring to FIG. 6, in step S601, when the control unit 260 loads the snapshot image, the boot loader 240 copies the snapshot image to the volatile memory Ram and executes the snapshot image. When the snapshot image is compressed, the image is decompressed and executed. In step S603, the boot loader 240 causes only a minimum number of devices for resuming the suspended kernel process to operate. The minimum device operation means that the unnecessary device is turned off and the required device is powered down. In step S605, the boot loader 240 transmits a kernel operation signal to the kernel 250. [ In operation S607, the kernel 250 operated by the kernel operation signal executes a kernel process, that is, an interruption point kernel process, at a point where the snapshot image is stopped to be generated. In step S609, the kernel 250 resumes the device by powering on or powering up the device that has performed the least operation. In step S611, the kernel 250 performs a file system recovery to correspond to the snapshot image data.

In step S517, while the kernel 250 executes boot initialization, the control unit 260 transmits a service unit operation signal.

In step S519, the boot loader 519 transmits the service without set value to the service unit 220 from the snapshot image executed in step S511.

In step S521, the service unit 220 receiving the service sub-operation signal and the service without the set value of the boot loader 240 executes the service without the set value.

In step S523, the control unit 260 extracts the set value service from the storage unit 210 to allow the service unit 220 to execute the set value service.

In step S525, the control unit 260 transmits the extracted set value service to the service unit 220. [

In step S527, the service unit 220 executes the service having the set value.

As described above, when the present invention generates a snapshot image including a service without a set value, the capacity of the snapshot image is reduced and the creation time is also shortened.

The present invention can also be embodied as a computer-readable recording medium on which a program for executing the snapshot image generation method and / or the method for creating and booting the snapshot image is recorded.

Therefore, according to the present invention, when booting using the snapshot image including the service without the set value, the load time and execution time are shortened due to the small snapshot image capacity, thereby reducing the overall boot time.

210:
220: Service Department
230:
240: Boot loader
250: Kernels
260:

Claims (17)

An image generating unit for generating a snapshot image;
A storage unit for storing a service including a set value service having a fixed value and a set value service for which a set value is changed without changing the snapshot image and the set value;
A service unit for executing the service; And
Wherein the management server reads the service without the set value service from the storage unit and transmits the set value free service to the service unit and executes the service without the set value service to generate the snapshot image including only the service without the set value, And a controller for storing the data in the storage unit
Wherein the snapshot image generating device is a snapshot image generating device.
The method according to claim 1,
The service unit executes only the service without the set value
Wherein the snapshot image generating device is a snapshot image generating device.
The method according to claim 1,
Wherein the snapshot image is compressed and stored in the storage unit
Wherein the snapshot image generating device is a snapshot image generating device.
The method according to claim 1,
Wherein the image generating unit regenerates the snapshot image including the changed set-value-free service when the service without the set value is changed
Wherein the snapshot image generating device is a snapshot image generating device.
A method of generating a snapshot image by a snapshot image generating apparatus,
A first step of storing a service including a service without a set value and a service with a set value in which a set value is changed without changing a set value;
A second step of detecting a boot event, executing a boot corresponding to the boot event, and creating a service state capable of executing the service;
A third step of executing the service;
A fourth step of generating a snapshot image including a service without a set value among the services; And
And a fifth step of storing the snapshot image
Wherein the snapshot image is a snapshot image.
6. The method of claim 5,
The third step is a step of executing only the service without the set value
Wherein the snapshot image is a snapshot image.
The method according to claim 6,
The fifth step is to compress and store the snapshot image
Wherein the snapshot image is a snapshot image.
6. The method of claim 5,
And a sixth step of regenerating and storing the snapshot image including the changed service without the set value if the service without the set value is changed
Wherein the snapshot image is a snapshot image.
A storage unit for storing a snapshot image including a service without a set value; And
A boot loader that executes the snapshot image while waiting for a boot initiation;
A kernel for executing boot initialization after the snapshot image is executed; And
And a control unit for extracting the snapshot image from the storage unit, loading the snapshot image into the boot loader, and controlling the boot loader and the kernel to control booting
An image boot device characterized by. 10. The method of claim 9,
And a service unit for executing a service including the service having the set value and the service having the set value,
Wherein the set value service is stored in the storage unit,
Wherein the boot loader extracts the service without the set value included in the snapshot image and transmits the extracted service to the service unit,
Wherein the control unit reads the set value service from the storage unit and transmits the set value service to the service unit for execution
An image boot device characterized by.
10. The method of claim 9,
The snapshot image containing the interruption point of the boot initialization of the kernel
An image boot device characterized by.
12. The method of claim 11,
Wherein the control unit controls the kernel to perform a boot initialization from an interruption point of the boot initialization
An image boot device characterized by.
As for how the boot device creates and boots the snapshot image,
Detecting a boot event;
Waiting for a boot initialization corresponding to the event;
Executing a snapshot image including a service without a waiting value of the boot initialization;
Executing boot initialization; And
Executing the set value service after the boot initialization is completed
To create and boot up a snapshot image.
14. The method of claim 13,
The snapshot image contains the breakpoint of the boot initialization
To create and boot up a snapshot image.
15. The method of claim 14,
Executing the boot initialization from the interruption point of the boot initialization
To create and boot up a snapshot image.
9. A computer-readable recording medium having recorded thereon a program for executing a method of generating a snapshot image according to any one of claims 5 to 8.
A computer-readable recording medium having recorded thereon a program for executing a method of creating and booting a snapshot image according to any one of claims 13 to 15.

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