KR101319466B1 - Method of synchronizing data of terminals using hash function - Google Patents

Abstract

The present invention relates to a method in which a server synchronizes data of a using terminal in a cloud computing environment implementing N-Screen, and the present invention comprises a plurality of terminals and a server, and the application executed on any one of the terminals. Data stored in the server, and when the same application is executed in another terminal, the data stored in the server is provided to the other terminal so that a plurality of terminals can be used as one terminal, A method for synchronizing, the data synchronization between the terminal and the server is performed periodically according to a designated time; The file system of the data stored in the terminal and the file system stored in the server are compared to determine whether synchronization is required. According to the present invention, it is possible to periodically synchronize the data of the terminal, to provide a data synchronization method between a plurality of terminals using a hash function that can minimize the effect of whether or not the wireless communication of the terminal on the N-Screen implementation.

Description

Method of synchronizing data between multiple terminals using hash function {METHOD OF SYNCHRONIZING DATA OF TERMINALS USING HASH FUNCTION}

The present invention relates to a method for a server to synchronize data of a using terminal in a cloud computing environment implementing N-Screen.

N-Screen is a service that allows users to seamlessly use a single content on various devices such as TVs, PCs, tablet PCs, and smartphones. Such an N-Screen environment is generally implemented under a cloud computing environment in which content is stored and used in a server. In order to implement such an N-Screen service, many synchronization processes must be involved between various terminals and servers.

For example, Korean Patent Laid-Open Publication No. 10-2010-0003116 discloses a method of synchronizing data between heterogeneous terminals in order to apply a widget application to an N-Screen service (see FIG. 1).

However, such a data synchronization method between heterogeneous terminals has a problem in that the number of synchronization increases and the amount of communication due to synchronization increases.

Accordingly, the present invention uses a file system and a hash function in synchronizing data. Hereinafter, the file system and the hash function of the prior art will be described.

A file system refers to a system for storing or organizing files or data on a computer so that they can be easily found and accessed. The structure of a FAT file system which is generally used is shown in FIG. 2.

As shown in the drawing, the conventional file system is divided into PBR, Reserved, FAT, Root Directory, and Data Cluster.

At this time, PBR serves as a header of the corresponding file system and stores basic information related to the entire system such as disk size, cluster size, volume name, and number of clusters.

The reserved area is reserved for the performance of the disk hardware.

In addition, the FAT area distinguishes free space from allocated space when a cluster is allocated, and records the number of the next connected cluster when a file occupies more than one cluster.

In the Root Directory area, entries (including files / sub directories) of files stored in the Root Directory are stored, and since they are usually provided in a fixed size, the number of files that can be stored in the Root Directory is limited.

In addition, the data cluster area is an area where actual file data is stored and is allocated in a cluster unit. Sub Directory information is also stored in the Data Cluster area.

Meanwhile, FIG. 3A is a flowchart illustrating a method of searching a file using a conventional file system, and FIG. 3B is a flowchart illustrating a method of synchronizing files in the prior art.

As shown in FIG. 3A, in the file search by the conventional file system, all file accesses are PBR scanned (S11).

The file is searched through the search of RootDir and SubDir (S13, S15).

Next, access to the cluster through FAT scan (S17, S19), and determines whether the cluster is linked to read the file (S21).

On the other hand, as shown in Figure 3b, when the file is synchronized, changes of the file are tracked through the file reading process (S11 to S21) as described above (S31). That is, the change of the file is recognized through the last modification time, the file size, etc. by searching for RootDir and SubDir.

Then, the tracked change is transmitted to the server (S33), and the file of the path corresponding to the transmission path of the server is synchronized in the process of the same file read / write (S35).

Then, the above synchronization process is repeated until all the files to be synchronized are synchronized (S37).

On the other hand, the Republic of Korea Patent Publication No. 10-2008-0006558 describes a method for synchronizing the file system, which is to synchronize the file system itself, and not to synchronize the stored file using the file system, this is the N-Screen environment Is not applicable for synchronizing files on a terminal.

When using an existing file system by using the N-Screen platform or directly using a file system included in the terminal, the following problems are encountered.

The search process of modified files by searching RootDir and SubDir targets the entire file system, so the search time is long. In addition, the time taken to directly calculate the hash value to check for file changes causes a processing delay because it is proportional to the file size.

When using the file system included in the terminal directly, user data cannot be protected from illegal access. Even if the contents are encrypted by file, the file name and the list of installed programs are revealed.

Republic of Korea Patent Publication No. 10-2010-0003116 Republic of Korea Patent Publication No. 10-2008-0006558

The present invention is to solve the above problems, to provide an effective N-Screen environment, to provide a data synchronization method between a plurality of terminals using a hash function that the data of the terminal is periodically synchronized.

In addition, the present invention provides a file synchronization method in which the amount of data required for synchronization is reduced so that the amount of communication between the server and the terminal is increased by periodic synchronization.

In addition, the present invention provides a structure of a file system with enhanced security by improving a file system vulnerable to security in providing file synchronization using a file system.

As described above, the present invention includes a plurality of terminals and a server, and stores data of an application executed in any one of the terminals in a server, and when the same application is executed in another terminal, the data stored in the server. A method for synchronizing data between a terminal and a server so as to be provided to another terminal so that a plurality of terminals can be used as one terminal, the method of synchronizing data between the terminal and the server is performed periodically according to a designated time; The file system of the data stored in the terminal and the file system stored in the server are compared to determine whether synchronization is required.

The comparison of the file system may be performed by converting basic information of the file system into a hash function and comparing the stored values.

The synchronization may include distinguishing whether a synchronization target file is an application file or a general data file other than an application, and when the synchronization target file is an application file, grasping the SSID of the application to determine whether to synchronize; When the synchronization target file is the general data file, the hash function conversion value of each cluster of the FAT may be compared, and only the clusters having different hash function conversion values may be received and synchronized.

The file system includes a PBR area, a FAT area, a root directory area, and a data cluster area. The PBR area includes user account information and a hash value obtained by converting data of the PBR area into a hash function for each cluster. The FAT area comprises a field in which application data is stored, a field in which general data is stored, and a field in which synchronization priority information is stored; The FAT area includes a hash value obtained by converting data of the FAT area and Data Cluster area into a hash function for each cluster; The root directory area may include a hash value obtained by converting data of the root directory area into a hash function for each cluster.

On the other hand, the present invention is configured to include a plurality of terminals and the server, and stores the data of the application executed in any one of the terminal in the server, when executing the same application in another terminal, the data stored in the server In a method for synchronizing data between a terminal and a server so that a plurality of terminals can be used as one terminal by providing to another terminal, (A) a file system converted into a hash function of a PBR area of a file stored in the terminal and stored Reading basic information and transmitting the basic information to the server; (B) the server comparing the received basic information of the file system with the basic information of the file system stored in the server; (C) ending the synchronization process when the basic information of the file system is the same as the basic information stored in the server as a result of performing the step B; (D) transmitting hash conversion data for each cluster in the FAT area to a server when the basic information of the file system is different from the basic information stored in the server as a result of performing step B; (E) the server comparing the received cluster-specific hash conversion data to determine the changed cluster; (F) the server transmitting the changed cluster data to the terminal to perform synchronization; And (G) a method for synchronizing data between multiple terminals using a hash function which is performed by repeating the steps D to F for all clusters.

The present invention provides a method for synchronizing data between a plurality of terminals using a hash function to periodically synchronize the data of the terminal, thereby minimizing the effect of whether the terminal is capable of wireless communication on the N-Screen implementation.

In addition, the present invention provides a method for synchronizing data between multiple terminals using a hash function that reduces the amount of communication between the server and the terminal while reducing the amount of communication between the server and the terminal increased by periodic synchronization.

In addition, the present invention provides a file synchronization using a security-enhanced file system, thereby enhancing the security of the N-Screen system.

1 is a flowchart illustrating a data synchronization method between heterogeneous terminals according to the prior art.
2 is a conceptual diagram showing the structure of a conventional general file system.
3A-3B are flow diagrams illustrating a method for retrieving and synchronizing files using a conventional file system.
4 is a block diagram showing a file synchronization structure according to the present invention.
5 is a conceptual diagram showing the structure of a specific embodiment of a file system according to the present invention;
6 is a flowchart illustrating a specific embodiment of a file synchronization method according to the present invention.

Hereinafter, the characteristics of the N-Screen environment will be described first, and a specific embodiment of a file synchronization method according to the present invention will be described in detail with reference to the accompanying drawings.

N- Screen  Characteristics of the environment

N-Screen platform software must handle synchronization with server data quickly in preparation for user's mobile device.

The creation of many files that occur during synchronization complicates exception handling.

Processing performance is degraded due to large file creation and deletion.

N-Screen's application has an ID according to a user and thus has a restoration capability using data stored in a server.

One application is given a unique ID according to the registered market and can be restored at any time through the network.

Application data does not change, so the client does not need to send application data to the server during synchronization.

Only the application name / icon / short description is required on the N-Screen initial screen.

Most of the installed applications have usage characteristics that are not frequently performed.

Already most of the data resides on servers, and most of the data that is useful to users is stored primarily in cloud environments or other servers.

Only a small amount of data stored locally can be the target of actual synchronization.

Hereinafter, a specific embodiment of a file synchronization method according to the present invention will be described in detail with reference to the accompanying drawings.

Sync target and frequency

In the file synchronization according to the present invention, unlike the prior art illustrated in FIGS. 3A and 3B, the file synchronization is performed by comparing the file systems without comparing and synchronizing the file data.

In this case, specific contents of synchronizing the terminal file using the file system will be described in detail with reference to FIG. 6.

In addition, in the present invention, synchronization using the file system is repeatedly performed at predetermined periods.

On the other hand, the present invention has a structure of a file system suitable for the present invention, unlike the general file system for synchronizing data using the file system. Hereinafter, the structure of the file system according to the present invention will be described.

File system structure

As shown in FIG. 5, the file system according to the present invention includes a PBR, a FAT, a root directory, and a data cluster region as in a general file system.

The PBR area acts as a header of the file system and stores basic information related to the entire system such as disk size, cluster size, volume name, and number of clusters.

In addition, the PBR area according to the present invention stores user account information (seed value of the encryption key) and hash values for each cluster constituting the PBR area.

On the other hand, the FAT area includes a field for distinguishing applications and general data and a field for distinguishing synchronization priority.

Applications can handle comparisons of data and re-downloads from the server by exchanging only universally unique identifiers (UUIDs) because the data rarely changes.

On the other hand, in the case of general data, the hash function is converted and stored, thereby eliminating the need for a separate hash process at the time of synchronization.

In addition, the synchronization priority field stores synchronization priority. The synchronization priority field is divided into elements that can be synchronized according to a user's request and necessary parts for initial synchronization, thereby distributing synchronization time to enable faster synchronization.

Meanwhile, the root directory area, the FAT area, and the data cluster area are encrypted and stored in cluster units.

That is, the data of the root directory area, the FAT area, and the data cluster area are encrypted and stored in cluster units, and then hash values of the encrypted root directory area and the FAT area data are stored in the root directory area and the FAT area. Are stored respectively.

In the FAT area, a hash value for each cluster of the encrypted Data Cluster area is stored.

At this time, the key value used for encryption is set to have the seed value associated with the user account information. That is, it is used as an encryption key through arithmetic processing inside UserUUID and DiskID rk system of PBR.

Also. The encryption method is preferably a symmetric encryption method.

Hereinafter, a detailed execution process of data synchronization according to the present invention will be described in detail with reference to FIG. 6 according to the present invention.

First, referring to the process of generating a file according to the present invention, the synchronization process is generated by two events.

First, the first case is a file request from a user, and the second is a synchronization process that is periodically executed between the server and the terminal.

Of course, the main synchronization process of the present invention is the second synchronization process between the server and the terminal.

First, referring to the case by the file request of the user, it is checked whether the requested file from the user is the same as a file already stored, and performs a synchronization process if not stored (S110).

Thereafter, it is determined whether the requested file data is an application (S120).

When the requested file is an application, the UUID of the application is transmitted to a server, and the corresponding application data is received to perform synchronization (S130).

On the other hand, if the requested file is not an application as a result of the determination of step 120, the server checks the synchronization order (S150), and if the synchronization order is a priority, transmits the corresponding cluster data to the terminal to perform synchronization (S160). ).

At this time, in file synchronization, after recording one cluster unit, a hash value is generated and recorded in the FAT area.

Thereafter, after performing steps 130, 140, and 150, a periodic synchronization process of the terminal is performed.

Hereinafter, a synchronization process that is periodically executed between the server and the terminal will be described.

Periodic synchronization between the server and the terminal is first converted into a hash function of the PBR area of the file stored in the terminal to read the basic information of the stored file system and transmitted to the server and the server compares it to determine whether the file has changed ( S210). Accordingly, basic information of the entire file system can be quickly read with a small amount of data.

Thereafter, if the file is not changed, the file synchronization process is terminated, and if the file is changed, hash conversion data existing for each cluster of the FAT area is transmitted to the server (S220).

Thereafter, the server compares the transmitted hash function conversion data for each cluster to determine the changed cluster (S240).

Accordingly, whether or not the entire file has been changed and the changed part can be determined with a small amount of communication in a short time. That is, it is possible to track whether or not changes are made in units of 204 clusters at a time.

Thereafter, if there are different portions of the hash transform data, the synchronization process is performed through the above-described steps 120 to 150.

That is, the changed data is identified, and when the changed data is an application, the UUID is transmitted to download the application again from the server, and in the case of general data, synchronization is performed through cluster units.

The synchronization process is repeated for all the synchronization target clusters (S250).

On the other hand, applications that are excluded from the initial synchronization and low-priority data are synchronized in real time when a user requests a corresponding file.

It is to be understood that the invention is not limited to the disclosed embodiment, but is capable of many modifications and variations within the scope of the appended claims. It is self-evident.

The present invention relates to a method in which a server synchronizes data of a using terminal in a cloud computing environment implementing N-Screen. According to the present invention, the data of the terminal is periodically synchronized so that wireless communication of the terminal is possible. It is possible to provide a method for synchronizing data between multiple terminals using a hash function that can minimize the impact on the screen implementation.

Claims (6)

Comprising a plurality of terminals and servers, and stores the data of the application executed in any one of the terminals in the server, and when the same application is executed in another terminal, by providing the data stored in the server to the other terminal In the data synchronization method between a plurality of terminals, so that a plurality of terminals can be used as one terminal,
Data synchronization between the terminal and the server,
Carried out periodically according to a specified time;
The file system of the data stored in the terminal and the file system stored in the server are compared to determine whether synchronization is necessary.
The comparison of the file system,
This is done by converting the basic information of the file system into a hash function and comparing the stored values:
The synchronization is,
Identify whether your synced file is an application file or a non-application data file,
If the synchronization target file is an application file, determine whether to synchronize by identifying an SSID of the application;
When the synchronization target file is the general data file, a plurality of terminals using a hash function may be configured to compare hash function conversion values for each cluster of FAT and to receive and synchronize only clusters having different hash function conversion values. How to synchronize data between them.
delete delete The method of claim 1,
The file system comprises:
It consists of a PBR zone, a FAT zone, a root directory zone, and a data cluster zone:
In the PBR region,
The user account information and the hash value obtained by converting the data in the PBR area into a hash function for each cluster are stored.
The FAT area is
A field for storing application data, a field for storing general data, and a field for storing synchronization priority information;
In the FAT area,
A hash value obtained by converting data of the FAT area and the Data Cluster area into a hash function for each cluster is stored;
In the Root Directory area,
And a hash value obtained by converting data of the root directory area into a hash function for each cluster, and storing the hash value.
Comprising a plurality of terminals and servers, and stores the data of the application executed in any one of the terminals in the server, and when the same application is executed in another terminal, by providing the data stored in the server to the other terminal In the data synchronization method between a plurality of terminals, so that a plurality of terminals can be used as one terminal,
(A) reading the basic information of the file system is converted into a hash function of the PBR area of the file stored in the terminal and transmitted to the server;
(B) the server comparing the received basic information of the file system with the basic information of the file system stored in the server;
(C) ending the synchronization process when the basic information of the file system is the same as the basic information stored in the server as a result of performing the step B;
(D) transmitting hash conversion data for each cluster in the FAT area to a server when the basic information of the file system is different from the basic information stored in the server as a result of performing step B;
(E) the server comparing the received cluster-specific hash conversion data to determine the changed cluster;
(F) the server transmitting the changed cluster data to the terminal to perform synchronization; And
(G) a method of synchronizing data between multiple terminals using a hash function, comprising repeating the steps D to F for all clusters.
The method of claim 5, wherein
The file system comprises:
It consists of a PBR zone, a FAT zone, a root directory zone, and a data cluster zone:
In the PBR region,
The user account information and the hash value obtained by converting the data in the PBR area into a hash function for each cluster are stored.
The FAT area is
A field for storing application data, a field for storing general data, and a field for storing synchronization priority information;
In the FAT area,
A hash value obtained by converting data of the FAT area and the Data Cluster area into a hash function for each cluster is stored;
In the Root Directory area,
And a hash value obtained by converting data of the root directory area into a hash function for each cluster, and storing the hash value.

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