KR20180063920A - File conversion system for efficient processing of large files and method thereof - Google Patents

Abstract

A file conversion system according to the present invention includes a first server for changing the path of each of first files included in a first hierarchical directory tree according to a naming rule and generating a second hierarchical directory tree including second files having a new path, and a second server for changing the format and size of each of the second files included in the second hierarchical directory tree according to a change rule and generating each of third files having a changed format and a changed size.

Description

[0001] FILE CONVERSION SYSTEM FOR EFFICIENT PROCESSING OF LARGE FILES AND METHOD THEREOF [0002]

Embodiments in accordance with the concepts of the present invention are directed to file modification techniques and, more particularly, to file modification systems and methods that can efficiently process large files by automatically altering large files.

Special effects work refers to the use of computer graphics programs to create scenes that can not be produced in the real world, or to improve the completeness of movies.

The original images shot directly at the scene have various formats, sizes, and file names. Original images that are not uniform in format and size can not be used immediately during the special effects work step.

The special effects worker performs the direct modification of the original image in unformatted format and size to the special effect work environment, and the special effect work time is delayed.

1. Registration No. 10-0628558 (registered patent publication, publication date September 18, 2006) 2. Registration No. 10-1156227 (registered patent publication, publication date May 31, 2012)

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a method and apparatus for processing a large-capacity and large-sized image sequence into a workable state and reducing the time and errors in a pre- And a hierarchical directory tree having a new path can be created by changing the path of each of the files.

The present invention also relates to a file changing system and a file changing method of the file changing system, which can generate files having a changed format and a changed size by changing the format and size of each of the files.

The file modification system according to the embodiment of the present invention changes the path of each of the first files included in the first hierarchical directory tree according to a naming rule and updates the second hierarchical directory including the second files having the new path A second server for creating a second hierarchical directory tree, a first server for generating a second hierarchical directory tree, a first server for generating a second hierarchical directory tree, And a second server for generating the second server.

A method of operating a file modification system according to an embodiment of the present invention is characterized in that the first server changes the path of each of the first files included in the first hierarchical directory tree according to a naming convention, Creating a second hierarchical directory tree containing files, the second server changing the format and size of each of the second files included in the second hierarchical directory tree according to a change rule, And the second server generates each of the third files having the changed format and the changed size.

The file changing system according to the embodiments of the present invention is intended to reduce the time consuming of the management step for performing the special effect processing on the image. The various original images may be stored in various formats, various sizes, and / And solves the conventional problems caused by using ununified data, thereby maximizing resource utilization.

The file modification system according to the embodiments of the present invention changes the path of each of the files to create a hierarchical directory tree having a new path so that the change server can easily access the large files, There is an effect that can be changed.

The file modification system according to the embodiments of the present invention generates files having a changed format and a changed size by changing the format and size of each of the files to reduce the waste of manpower for changing the files and shorten the consumption time , And the accuracy of the change is improved.

The file modification system according to the embodiments of the present invention can efficiently process large files by changing the format and size of each of the files to generate files having a changed format and a changed size.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to more fully understand the drawings recited in the detailed description of the present invention, a detailed description of each drawing is provided.
1 is a block diagram of a file modification system in accordance with embodiments of the present invention.
2 is a conceptual diagram showing a process in which the controller monitors the operation status of the change server.
3 shows a first hierarchical directory tree and a second hierarchical directory tree.
Figure 4 shows an embodiment of a database of information / log servers.
5 shows a pre-change second hierarchical directory tree and a modified second hierarchical directory tree.
6 is a conceptual diagram illustrating a process of changing files by the change server.
7 is a conceptual diagram showing a case where an error occurs in the process of changing files by the change server.
8 shows a structure of a modification file according to the embodiments of the present invention.
9 is a flowchart illustrating an operation method of the file changing system according to the embodiments of the present invention.

1 is a block diagram of a file modification system in accordance with embodiments of the present invention. 1, a file modification (or file conversion) system 1000 includes an input data storage server 1100, a pre-processor 1200, an information / log server 1300, a controller 1400, A change (or conversion) server 1500, an output device 1600, an output data storage server 1700, and a mail server 1800.

For example, the file modification (or file conversion) system 1000 may automate the task of unifying a large number of previously photographed image sequences with high quality with a certain resolution (e.g., 4K or more) prior to creating video special effects.

In this specification, a server means a server computer or a server program that provides a service to a client through a network. Although the term server is used in this specification, the server may refer to a data processing apparatus that stores a processor and data (or information).

The input data storage server 1100, the pre-processor 1200, the information / log server 1300, the controller 1400, the change server 1500, the output device 1600, the output data server 1700, (1800) may communicate with each other via a closed local area network, e.g., an intranet.

The input data storage server 1100 can simultaneously access the intranet and the external internet network and the input data storage server 1100 can receive large capacity files from each of the plurality of client servers through the external internet network. The input data storage server 1100 may be referred to as a first server.

The input data storage server 1100 may store an image of a shooting source (or an original source) used by an artist, a worker, or a director who is performing an operation to insert a special effect, (The first files described below).

The file modification system 1000 may be configured to store the format and size of each of the large capacity photographic source images (e.g., 4K to 8K UHD (ultra-high-definition) high resolution images) It is possible to change the format and size of each of the original images after changing the path of each of the original images so as to allow the workers to efficiently So that the user can perform the special effect operation.

As is well known, a file, or directory, is a general form of a name, which specifies a unique location within a file system.

The input data storage server 1100 stores the path of each of the first files included in the first hierarchical directory tree according to a naming rule (for example, a rule generated to change the file path) And create a second hierarchical directory tree, each containing second files having a new path. In this case, each of the first files and the second files are the same files having different paths, and a file is an object of a computer storing data, for example, a file extension (e.g., bmp, jpg, pdf, etc.). < / RTI >

Figure 3 shows a first hierarchical directory tree and a second hierarchical directory tree, and Figure 4 shows an embodiment of a database of information / log servers. 1 and 3, the input data storage server 1100 stores files (A) transmitted from an A company client server and / or files B transmitted from a B company client server (Referred to as " first files included in the hierarchical directory tree HDT1 ").

Referring to FIGS. 1, 3 and 4, the input data storage server 1100 stores the path PATH1 of each of the first files included in the first hierarchical directory tree HDT1 as a naming rule (NR) , And may generate a second hierarchical directory tree HDT2 containing second files each having a new path PATH2.

For example, the input data storage server 1100 changes the path "PA_SA_CA_A2100" of the first file " A2100.tif " according to the naming rule (NR) and stores the second file " SP1_SS1_SC1_Image0001.tif "having the new path" SP1_SS1_SC1_Image0001 " Can be generated.

Each of the first files and the second files may be the same file having different paths. Each of the second files may include a series of frames corresponding to a film shot or a film cut. For example, a movie can generate 30 frames per second, and in the case of a 3D image, 60 frames per second. The film shot or the film cut is a term used in film editing.

In the present specification, the film shot refers to continuous frames, for example, shot shooting action, the film cut refers to continuous frames taken in multiple angles, and the film cuts together to form the film shot, The film shots are collected to complete one movie.

As mentioned earlier, the path refers to the general form of a file or directory name, which specifies a unique location in the file system. That is, the path is separated by a delimiter character (e.g., a slash ("/") or an underbar ("_")), and a directory tree represented by a character string containing path components representing each directory Point to the location.

The input data storage server 1100 generates a second hierarchical directory tree. The input data storage server 1100 creates a naming rule for each path of the first files included in the first hierarchical directory tree, And the input data storage server 1100 may generate a second hierarchical directory tree according to the naming rules and store the first files in the first hierarchical directory tree May be assigned to the second hierarchical directory tree.

The change server 1500 changes the format and size of each of the second files included in the second hierarchical directory tree HDT2 according to a change rule (for example, a rule for changing at least one of the format and the size) And generate each of the third files having the changed format and the changed size. The change server 1500 may mean a second server.

FIG. 5 shows a pre-change second hierarchical directory tree HDT2 and a modified second hierarchical directory tree C_HDT2. Referring to FIGS. 1 and 5, the change server 1500 may convert a file (for example, SP1_SS1_SC1_Image0001.tif) having a format of TIF and a size of 3K to a file having a format of JPG and a size of 2K (for example, SP1_SS1_SC1_Image0001.jpg ).

1, the input data storage server 1100 may include a processor 1110 and a data storage (e.g., a data storage or memory device 1130). The data storage 1130 may include a first storage area 1131, a second storage area 1133, and a third storage area 1135. The storage area may refer to a memory area where the file is stored.

The processor 1110 may receive a naming convention (NR) transmitted from an external computer (S101) and store the naming convention (NR) in the first storage area 1131 of the data storage 1130. In accordance with embodiments, processor 1110 may receive and store a naming convention (NR) from pre-processor 1200. For example, the pre-processor 1200 may store user naming rules generated by a user of the file modification system according to embodiments of the present invention and predetermined standard naming rules, You can choose to use one of the naming conventions.

The pre-processor 1200 is a device for processing and processing some information in advance in order to automatically convert the original source.

The processor 1110 receives the first files FILES1 included in the first hierarchical directory tree HDT1 transmitted (or input) from the external apparatus (S102), and stores the first files FILES1 as data And may be stored in the second storage area 1133 of the storage 1130.

Processor 1100 sends a pre-processing job request REQ_PRE to the pre-processor 1200 (S103), and the pre-processor 1200 receives the pre-processing job request (REQ_PRE) Processing command CMD_PRE and send the pre-processing command CMD_PRE to the input data storage server 1100 in response to the request command REQ_PRE (S105).

The processor 1110 reads the naming rules NR and the first files FILES1 from the second storage area 1133 from the first storage area 1131 in response to the pre-processing command CMD_PRE, A second hierarchical directory tree HDT2 including second files FILES each having a new path PATH2 is created by changing the path PATH1 of each of the files FILES1 according to the naming rule NR, (S107). The processor 1110 may store the second files FILES2 in the third storage area 1135 of the data storage 1130. [

According to the embodiments, the path PATH1 of each of the first files FILES1 corresponds to the folder name of each of the first files FILES1 (e.g., "PA_SA_CA" in FIG. 3) A2100 "), and if at least one of the folder name and the file name has already been changed according to the naming rule (NR), the processor 1110 may change or not change the other of the folder name and the file name .

After the second files FILES are stored in the third storage area 1135, the processor 1110 reads the path PATH1 of each of the first files FILES1 and the path PATH2 of each of the second files FILES The pre-processor 1200 transmits the path PATH2 of each of the second files FILES2 to the information / log server (e.g., the third server) 1300 (S109) (S111). According to embodiments, the processor 1110 may further transmit the path (PATH1) of each of the first files (FILES1) to the information / log server (1300) along with the path (PATH2) of each of the second files (S111).

The information / log server 1300 receives the path PATH1 of each of the first files FILES1 and the path PATH2 of the second files FILES2 transmitted from the pre- 1330 and may assign an index value INDEX to each of the second files FILES2 based on the index information IR.

The information / log server 1300 may include a processor 1310 and a data storage 1330. The data storage 1330 may include a first storage area 1331, a second storage area 1333, a third storage area 1335, a fourth storage area 1337, and a fifth storage area 1339 have.

The processor 1310 receives the path PATH1 of each of the first files FILES1 and the path PATH2 of the second files FILES2 from the pre-processor 1200, (PATH1) of the second file and the path (PATH2) of each of the second files in the fifth storage area 1339 of the data storage 1330. According to embodiments, the processor 1310 may further receive index information (IR) from the pre-processor 1200 and store the index information IR in the first storage area 1331 of the data storage 1330 .

For example, the index information IR may indicate the immediately preceding index value so that the index value INDEX is not assigned to the path PATH2 of each of the second files. Accordingly, the processor 1310 can determine the index value of the path of the file to be processed with reference to the immediately preceding index value.

The processor 1310 allocates a different index value INDEX to the path PATH2 of each of the second files based on the index information IR in step S113 and stores the index value INDEX in the data storage 1330 In the second storage area 1333 of FIG.

Referring to FIG. 3, for example, when an index value INDEX is assigned in units of film cut, an index value INDEX "0001" may be assigned to the path "SP1_SS1_SC1" ) "0002" may be assigned to the path " SP1_SS1_SC3 ", an index value INDEX "0003" may be assigned to the path "SP1_SS1_SC3 "

Referring again to FIG. 1, the controller 1140 may include a monitor 1410 and a queue 1430. The controller 1140 may receive the path PATH2 of each of the second files and the index value INDEX allocated to each of the second files from the information / log server 1300 (S115). The controller 1140 may distribute the path PATH2 of each of the second files to the change server 1500 sequentially or in order of priority according to the status of the change server 1500. [

The monitor 1410 may receive the path (PATH2) of each of the second files and the index value (INDEX) assigned to each of the second files from the information / log server 1300 (S115). The index value INDEX for the path (PATH2) of each of the second files may be stored in a queue (or a queue buffer 1430 for storing index values). According to embodiments, the index values stored in the queue 1430 may be stored sequentially or in accordance with a priority. For example, the order of the index values stored in the queue 1430 or the order of the index values output from the queue 1430 may be variously changed according to design specifications.

The change server 1500 may include a plurality of file modifiers. Although only three file modifiers 1510, 1530, and 1550 are shown in FIG. 1 for convenience of description, the number of file modifiers included in the change server 1500 may vary according to embodiments.

The monitor 1410 sequentially reads a plurality of index values (INDEXi, i is a natural number) from the queue 1430 (S117), and selects the i-th index file index (PATH2_TGi), the ith index value (INDEXi), and the change rule (CR) to one of the plurality of file modifiers 1510, 1530, and 1550 (S121). Here, the target file path may refer to a file path to be processed by the conversion server 1500.

According to the embodiments, the monitor 1410 can further transmit to the file changer i-th location information DPi in which the i-th change file whose format and size of the i-th target file FILES2_TGi is changed by the file changer (S121).

The monitor 1410 monitors the operating state (e.g., ready or busy) of each of the plurality of file modifiers 1510, 1530 and 1550 (S119) The ith target file path PATH2_TGi, the ith index value INDEXi, and the change rule CR to any one of the modifiers 1510, 1530, and 1550 (S121).

2 is a conceptual diagram showing a process in which the controller monitors the operation status of the change server. 1 and 2, among the plurality of file modifiers (# 1, # 2, and # 3) included in the change server 1500, the first file changer # (BUSY, e.g., logic 1 or high level) in the flag since the second file changer # 2 is in use at the first time point T1, and the second file changer # State (READY, e.g., logic 0 or low level). The controller 1140 may distribute the task (e.g., file change operation) to the second file changer # 2 at the second time point T2.

Since the third file changer # 3 is not in use at the second time point T2, the third file changer # 3 may indicate the ready state READY in the flag. The controller 1140 may distribute the work from the third time point T3 to the third file changer # 3. The first file modifier # 1 completes the work before the fourth time point T4 after the third time point T3 so that the controller 1140 updates the first file modifier # 1).

1, the change server 1500 receives an i-th target file path PATH2_TGi, an i-th index value INDEXi, a change rule CR, and i-th position information DPi from the controller 1140, (S121), and may transmit the i-th target file path (PATH2_TGi) to the input data storage server 1100 (S123). The i-th position information DPi is information indicating a storage area of the output data storage server 1700 in which the i-th change file is to be stored.

The input data storage server 1100 may transmit the i-th target file FILES2_TGi corresponding to the i-th target file path PATH2_TGi to the change server 1500 (S125).

The change server 1500 changes the format and size of the i-th target file FILES2_TGi according to the change (or conversion) rule CR and generates an i-th change (or conversion) file having the changed format and the changed size (S127). That is, the change server 1500 changes the format and size of each of the second files included in the second hierarchical directory tree HDT2 according to a change rule (C_FILES_CR), and changes the format and size of the second files included in the second hierarchical directory tree HDT2 Each of the third files can be generated (S127). The change server 1500 may mean a second server.

The change server 1500 may include completion information indicating that the change operation of each of the second files included in the second hierarchical directory tree HDT2 is completed or a verification result obtained by verifying whether or not each of the second files has been changed normally VERI) to the controller 1140. A method for the change server 1500 to verify whether each of the second files has been changed normally will be described in detail with reference to FIG.

The change server 1500 may transmit the third files FILES3, the position information DP, and the error information EI to the output apparatus 1600 (S131). The i-th change file may be any one of the third files FILES3, and the i-th position information DPi may be any one of the position information DP.

The error information EI may indicate whether an error has occurred in the file during the change of the file by the change server 1500. [ For example, when the change server 1500 changes the format and size of each of the second files included in the second hierarchical directory tree HDT2 to generate errors (e.g., (For example, the second file itself is not executed), and may indicate that the file change operation is normally completed.

The output device 1600 receives the third files FILES3, the position information DP and the error information EI in step S135 and outputs the third file FILES3 as the position information DP corresponding to the position information DP And may control the output data storage server 1700 to store the output data in the storage area of the output data storage server 1700.

The output data storage server 1700 may include a processor 1710 and a data storage 1730. The processor 1710 receives each third file FILES3 and each positional information DP from the output device 1600 and stores each third file FILES3 in the data storage 1730 corresponding to each positional information DP In the storage areas SP1 to SP4.

The information / log server 1300 may receive the error information EI from the output device 1600 (S137) and store the error information EI in the fourth storage area 1337 of the data storage 1330. The information / log server 1300 may store information for each of the workers in a third storage area 1335 of the data storage 1330.

As shown in FIG. 4, the database of the information / log server 1300 includes a plurality of fields for managing file change information, each of the plurality of fields including a first file path (PATH1) The file path PATH2, the index value INDEX, the format of each of the second files, the size of each of the second files, the error information EI of each of the second files, . ≪ / RTI >

The output device 1600 transmits the worker information request signal REQ_WI to the information / log server 1300 (REQ_WI), and the information / log server 1300 transmits the worker information request signal REQ_WI to the information / The information WI for the first worker may be transmitted to the output device 1600 (S141).

The output device 1600 transmits the first change file among the third files FILES3 stored in the output data storage server 1700 in response to the information WI for the first worker via the mail server 1800, To the operator's computer.

The output device 1600 transmits the information WI, the third files FILES3 and the error information EI to the mail server 1800 (S143), and the mail server 1800 The third file FILES3 and the error information EI may be transmitted to the PC of the first worker (S145).

FIG. 6 is a conceptual diagram illustrating a process of changing files by the change server, and FIG. 7 is a conceptual diagram illustrating a case where an error occurs in the process of changing files by the change server.

Referring to FIGS. 1 and 6, the change server 1500 changes the format and size of a first target file (for example, "SP1_SS1_SC1_Image0001.tif") included in the second hierarchical directory tree 1-1 to a change rule CR), and generate a temporary file (e.g., "SP1_SS1_SC1_Image0001.jpg.tmp") having the changed format and the changed size (1-2). The change server 1500 may change the temporary file to a first change file (e.g., "SP1_SS1_SC1_Image0001.jpg") (1-3).

Referring to FIGS. 1 and 7, there are two cases where an error occurs in the process of changing a file by the change server 1500.

In the first case (1. error during the change), an error occurs in the process of changing the first target file (e.g., "SP1_SS1_SC1_Image0001.tif") included in the second hierarchical directory tree 2-1, (For example, "SP1_SS1_SC1_Image0001.jpg.tmp" of 2-3) is generated. In the second case (2. an error after the change), the change is normally completed but the temporary file (for example, "SP1_SS1_SC1_Image0001.jpg. (e.g., "SP1_SS1_SC1_Image0001.jpg.tmp" of 2-3) is left as it is when an error occurs in the process of changing to the first change file (e.g., "SP1_SS1_SC1_Image0001.jpg" .

The change server 1500 can verify whether the file has been changed normally (S129). The change server 1500 determines whether a temporary file corresponding to the first target file path exists. As a result of the determination, if the temporary file exists, the extension (.tmp) of the temporary file is removed to make it a normal first change file.

If the temporary file does not exist as a result of the determination, the change server 1500 determines whether a first change file corresponding to the first target file path exists. If the first change file exists as a result of the determination, the change server 1500 parses the header of the first change file.

8 shows a structure of a modification file according to the embodiments of the present invention. 7 and 8, the first modification file 10 may include a file format 20, an image size 30, and a file size 30, and data 50 (e.g., a payload) have.

 The change server 1500 parses the header of the first change file 10, extracts the file format 20 and the image size 30 from the parsed header, and extracts the extracted file format (e.g., jpg) (E.g., 2K) matches the image size included in the change rule (2. error after change), the change server 1500 matches the file format included in the first target file path It can be determined that the first target file is normally changed to the first change file.

However, if any one of the extracted file format and the extracted image size does not match the file format and the image size included in the change rule (1. error during change), the change server 1500 It can be determined that the first target file is not normally changed to the first change file.

According to embodiments, the modification server 1500 parses the header of the first modification file 10, extracts the file size 40 from the parsed header, and stores the location corresponding to the extracted file size (e.g., 1M) It is determined whether or not there is data in the memory P. As a result of the determination, if there is data in the position P, it can be determined that the first target file has been normally changed to the first change file, and if there is no data in the position P, It can be determined that the change file has not been changed normally.

If the first target file does not normally change to the first change file, or if there is no temporary file corresponding to the first target file path, and there is no first change file corresponding to the first target file path, The server 1500 may control to change the first target file again.

9 is a flowchart illustrating an operation method of the file changing system according to the embodiments of the present invention. Referring to FIGS. 1, 3 and 9, the input data storage server 1100 changes the path of each of the first files included in the first hierarchical directory tree HDT1 according to a naming rule (NR) (S310) and generate a second hierarchical directory tree HDT2 including second files having a new path (S330).

The change server 1500 changes the format and size of each of the second files included in the second hierarchical directory tree HDT2 according to a change rule (S350). The change server 1500 changes the format and size of the third files (S370).

The operation method of the file change system according to the embodiment of the present invention is such that the first server 1100 changes the path of each of the first files included in the first hierarchical directory tree according to a naming rule, Creating a second hierarchical directory tree including second files having the first hierarchical directory tree and a second hierarchical directory tree including second files having the second hierarchical directory tree having the format and size of each of the second files included in the second hierarchical directory tree, , And the second server generates each of the third files having the changed format and the changed size.

The generating of each of the third files may include generating a first target file path corresponding to one of the second files, a first index value corresponding to the first target file path, Receiving the change rule; transmitting the first target file path to the first server (1500) by the second server (1500); and transmitting the first target file path The second server 1500 changes the format and the size of the first target file according to the change rule, and transmits the changed target file to the second server, And the first change file is any one of the third files.

The computer readable program codes for carrying out the method of operation of the file modification system described herein may be stored in a computer readable recording medium.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1000; File change (file conversion) system
1100; Input data storage server
1200; Pre-processor
1300; Information / Log Server
1400; controller
1500; Change (conversion) server
1600; Output device
1700; Output data storage server
1800; Mail server

Claims (14)

A first server for changing a path of each of the first files included in the first hierarchical directory tree according to a naming rule and generating a second hierarchical directory tree each including second files having a new path; And
A second server for changing the format and size of each of the second files included in the second hierarchical directory tree according to a change rule and generating each of the third files having a changed format and a changed size, Change system. The method according to claim 1,
Further comprising a preprocessor for generating a preprocessing command in response to a preprocessing work request output from the first server and for transmitting the preprocessing command to the first server,
Wherein the first server sends the path of each of the first files and the path of each of the second files to the pre-processor. 3. The method of claim 2,
A third server for receiving and storing the path of each of the first files transferred from the pre-processor and the path of each of the second files, and allocating an index value to each of the second files based on the index information, Further comprising: The method according to claim 1 or 3,
Each of the second files comprising successive frames corresponding to a film shot or a film cut,
Wherein each of the first files and the second files are the same file. The server according to claim 1,
Receiving a first target file path corresponding to one of the first and second files, a first index value corresponding to the first target file path, and the change rule, Lt; / RTI >
Wherein the first server transmits a first target file corresponding to the first target file path among the second files to the second server,
The second server changes the format and size of the first target file according to the change rule, generates a first change file having a changed format and a changed size,
Wherein the first modification file is any one of the third files. 6. The method of claim 5,
Receiving a first path of each of the second files and an index value assigned to each of the second files, monitoring an operation of the second server, and monitoring the first target file path, the first index value And a controller for transmitting the change rule to the second server. The method according to claim 6,
A third server; And
A preprocessing command is generated in response to a preprocessing work request outputted from the first server, the preprocessing command is transmitted to the first server, and the path of each of the first files sent from the first server and the second Further comprising: a pre-processor for receiving a path of each of the files and transmitting the path to the third server,
Wherein the third server generates the index value assigned to each of the second files based on the index information and stores the index value assigned to each of the path of the second files and each of the second files, To a file change system. The method according to claim 6,
The second server receives location information of the first change file to be stored from the controller and transmits the first change file and the location information to an output device,
Wherein the output device controls the output data storage server to store the first change file in an output data storage server corresponding to the location information. 9. The method of claim 8,
A path for each of the second files output from the first server, an index value assigned to each of the second files, a path for each of the paths of the second files, Further comprising a third server for transmitting the index value to the controller and for storing information about each of the workers,
Wherein the output device transmits a worker information request signal to the third server,
And the third server transmits information on the first worker among the workers to the output device in response to the operator information request signal. 10. The method of claim 9,
Wherein the output device transmits the first change file stored in the output data storage server to the first worker's computer via the mail server in response to the information about the first worker. The method according to claim 6,
The second server comprising a plurality of file modifiers,
Wherein the controller monitors the operating state of each of the plurality of file modifiers and updates the first target file path, the first index value, and the second index value to any one of the plurality of file modifiers, The change rule is transmitted,
Wherein the one changer changes the format and size of the first target file transmitted from the first server in response to the first target file path in accordance with the change rule and changes the file change system. The first server changes the path of each of the first files included in the first hierarchical directory tree according to a naming convention and generates a second hierarchical directory tree each including second files having a new path step; And
The second server changes the format and the size of each of the second files included in the second hierarchical directory tree according to a change rule and the second server changes the format and size of each of the third files, And creating each of the files. 13. The method of claim 12, wherein generating each of the third files comprises:
Receiving, by the second server, a first target file path corresponding to one of the second files, a first index value corresponding to the first target file path, and the change rule;
The second server sending the first target file path to the first server;
The first server transmitting a first target file corresponding to the first target file path from the second files to the second server; And
Wherein the second server changes the format and size of the first target file according to the change rule and generates a first change file having a changed format and a changed size,
Wherein the first change file is one of the third files. A computer-readable recording medium storing computer-readable program codes for executing the method of operating the file modification system of claim 12.

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