KR101093808B1 - Network System having a structure of sharing data storage device and Operating method thereof - Google Patents

Abstract

Disclosed are a network system sharing a data storage device and a method of operating the same. According to an example of the network system, a network device generated from one or more data generating devices and receiving and processing a network packet including data and storage instructions, and a network packet connected to the network device to receive a network packet from the data generating device. A data storage device configured to receive data via a network device, process a data storage command included in the network packet, and store data from the data generation device in an internal storage means, wherein the address included in the network packet is Information on the data storage device as a destination on a network, wherein the network device checks the address and transmits the network packet to the data storage device.

Description

Network system having a structure of sharing data storage device and operating method

The present invention relates to a network system sharing a data storage device and a method of operating the same, and more particularly, to a network system and a method of operating the same data storage device a plurality of data generating apparatus and data using apparatus.

In general, a network system is used to connect a plurality of data processing apparatuses that generate and use data such as multimedia. The network system comprises a plurality of devices and a network device for connecting the plurality of devices. In order to implement a network system, a network device is provided in the system. A LAN widely used as a network system may operate based on a router, or may be provided as a network device such as a switching hub to which a switching technology is applied.

Various examples may be described as the data generation / use apparatus. For example, a plurality of personal computers connected to a network device, a device for generating predetermined data (for example, a device for generating audio and / or video data), and a device for using data (for example, using audio and video data, respectively) Devices such as speakers and monitors) may be data generation / use devices. These multiple data generation / use devices are connected to one or more network devices to implement one network system.

Conventionally, in order to implement a network system for a plurality of devices, an address is assigned to each of the plurality of data generating devices, and an address is assigned to each of the plurality of data using devices. It is provided to store the address information of each of the plurality of data generating / using devices. Accordingly, when the network packet including the address information is provided to the network apparatus, the network apparatus checks the address information from the network packet, and performs the operation of providing the network packet to the corresponding data using apparatus according to the result of the verification. In addition, when a plurality of devices are connected to one network device, since traffic may occur in data transmission according to the port state of the destination device, a buffer for temporarily storing network packets is required in the network device.

However, in the conventional network system as described above, the data generated by the data generating apparatus is simultaneously provided to the plurality of data using apparatuses, and accordingly, a plurality of data generating apparatuses and a plurality of data using apparatuses are connected to each other. Multiple data paths must be formed. In particular, since the data amount of high-definition or high-quality video / audio data increases, the number of data paths on the network that can be formed from one data generator is limited. That is, when the network system includes a plurality of data generating apparatuses and a plurality of data using apparatuses, the complexity of the data path has increased according to the conventional method, and the amount of data to be transmitted per unit time has increased. There has been a limit in increasing the number of data generating and data using devices to be implemented.

The present invention is to solve the above problems, by reducing the complexity of the data path and the connection of a plurality of data generating / using devices by allowing a plurality of data generating devices and data using devices to share the data storage device It is an object of the present invention to provide a possible network system and a method of operating the same.

In order to achieve the above object, a network system according to an embodiment of the present invention, a network device and a network device for receiving and processing a network packet generated from one or more data generating device and including data and storage instructions A network packet received from the data generation device via the network device and processing a data storage command included in the network packet to store data from the data generation device in an internal memory unit; And an address included in the network packet includes information destined for the data storage device as a destination on a network, and the network device checks the address and transmits the network packet to the data storage device. Characteristic It shall be.

Preferably, the network device receives the first to nth network packets from the first to nth data generators (where n is an integer equal to or greater than 1) and is included in the first to nth network packets, respectively. The first through nth addresses are characterized in that they each include the same information as the destination for the data storage device on the network.

Also preferably, the memory unit of the data storage device may include any one of a DRAM, a flash memory, and a hard disk drive (HDD), and the storage command included in the network packet from the data generating device is the data. And a protocol corresponding to the type of memory portion of the storage device.

Also preferably, the network device further receives a network packet generated from one or more data using devices and includes a read command, transmitting read data from the data storage device to the data using device, and using the data. The network packet from the device is characterized by including an address having the data storage device as a destination on the network and a data read command for reading data from a memory unit included in the data storage device.

The data storage device may include a network interface unit for interfacing with the network device, a command extractor for extracting a data storage command or a data read command from a network packet received through the network interface unit, and the extracted command. The memory controller may further include a memory controller configured to process the data to store or read data in the storage means.

On the other hand, the data generating apparatus may be a camera for generating image data by photographing the image, the data using apparatus may be a monitor system for monitoring the image data from the camera.

On the other hand, the data generating device and the data using device implements one terminal, the data generating device of the one terminal is a camera and the data using device is a monitor, and the system receives data from any one terminal. It may be a video conferencing system for transmitting to at least one other terminal.

On the other hand, the network system according to another embodiment of the present invention, each generating a first network packet, the first network packet is at least one data generating device including a first address, data and storage instructions, and each of the second Generates a network packet, the second network packet receiving one or more data using devices including a second address and a read command, the first and second network packets, and receiving the first and second network packets according to the first and second addresses. A network device that transmits first and second network packets and the network device connected to the network device to receive the first and second network packets, and process a storage command included in the first network packet to Store data in an internal memory unit, process a read command included in the second network packet, and And a data storage device for reading the stored data.

The method of operating a network system according to an embodiment of the present invention may include generating a first network packet including a first address, data, and a storage command from a data generator, and in response to the first address. Transmitting a first network packet to a data storage device, processing the storage command included in the first network packet in the data storage device, and storing the data in a memory unit; Generating a second network packet including an address and a read command, transmitting the second network packet to the data storage device in response to the second address, and transmitting the second network packet to the data storage device; Reading data stored in the memory unit by processing the read command included in the memory unit; Characterized in that it comprises the step of transmitting the data read out to the data group using the device.

According to the present invention as described above, a plurality of data generating apparatuses and data using apparatuses may be provided in the network system, reducing the complexity of the data path between the data generating apparatus and the data using apparatuses and efficiently storing a large amount of data. There is an effect that can be transmitted.

1 is a block diagram illustrating an embodiment of a network system according to an embodiment of the present invention.
2 is a block diagram illustrating an embodiment of a network system including a network device according to an embodiment of the present invention.
3 is a block diagram illustrating an embodiment of the network system of FIG. 2 in detail.
4A, 4B, and 4C are block diagrams illustrating one embodiment of a network device and a data storage device of the network system of FIG. 2, and one embodiment of a network packet.
5 is a block diagram illustrating an example of a videoconferencing system implemented by the network system of the present invention.
6 is a block diagram illustrating an example of a surveillance camera system implemented by a network system of the present invention.
7 is a flowchart illustrating a method of operating a network system according to an embodiment of the present invention.

DETAILED DESCRIPTION In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings that illustrate preferred embodiments of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a block diagram illustrating an embodiment of a network system according to an embodiment of the present invention. As shown in FIG. 1, the network system 100 may include one or more data generating devices 111 and 112, one or more data using devices 121 and 122, and a data storage device 130. The data generating devices 111 and 112 may be any device for generating data, and may be, for example, a device such as a camera, an audio microphone, or a computer. In addition, the data using apparatuses 121 and 122 are apparatuses using data generated by the data generating apparatuses 111 and 112 and may be monitors, speakers, or other computers. In addition, the data storage device 130 may be any device having a memory capable of storing data, such as a DRAM, a flash memory, or a hard disk (HDD). 1 illustrates an example in which one data storage device 130 is provided in the network system 100, but two or more data storage devices may be provided in the network system 100. In addition, a larger number of data using devices and data generating devices may be provided in the network system 100.

The data storage device 130 is commonly used for the data generating devices 111 and 112 and the data using devices 121 and 122 in the network system 100. That is, the data storage device 130 is connected to the data generating devices 111 and 112 and the data using devices 121 and 122 so that both the data generating devices 111 and 112 and the data using devices 121 and 122 are respectively. Like the internal parts thereof, data is stored in the data storage device 130 or the stored data is read and used.

The data storage device 130 includes various types of memory. The data storage device 130 may include any one type of memory or two or more types of two or more types of memory. The data storage device 130 may implement an interface logic in a hardware or software manner to modify an interface of a conventional DRAM, a flash memory, or a hard disk (HDD) to simultaneously interface to a plurality of devices. However, since the number of devices connected to the data storage device 130 is not constant and the devices are independent of each other and are often separated from each other spatially, network devices such as routers, network switches, etc. may be connected to the network system ( 100) may be further provided.

2 is a block diagram illustrating an embodiment of a network system including a network device according to an embodiment of the present invention. As shown in FIG. 2, the network system 200 may include one or more data generating devices 211 and 212, one or more data using devices 221 and 222, a data storage device 230, and a network device 240. It can be provided.

Network device 240 may include an Ethernet switch hub that is widely used as a LAN as a network. However, embodiments of the present invention need not be limited to Ethernet, and any network, for example, any network such as an optical fiber ring, a SAN switch, and the like may be applied. As illustrated in FIG. 2, when the network system 200 is implemented using the network device 240, the data generating devices 211 and 212 or the data using devices 221 and 222 may use the data storage device 230. There is no need to have a storage interface therein to access it. That is, in the conventional case, when a data generating device or a data using device includes a storage device therein, an interface for accessing the storage device is essentially provided, but a network system according to an embodiment of the present invention. The data generating apparatuses 211 and 212 and the data using apparatuses 221 and 222 provided in the 200 may access the data storage device 230 even though the data generating apparatuses 211 and 2222 have only an interface for communicating with the network device 240. In addition, when a plurality of types of storage devices are used, the conventional data generating device or the data using device should be provided with an interface for each type of storage device separately, but according to an embodiment of the present invention, the network system 200 The data generating devices 211 and 212 or the data using devices 221 and 222 need not be provided with an interface to each of the storage devices even when a plurality of types of storage devices are used.

In the network system 200 of the present invention shown in FIG. 2, each of the data generating apparatuses 211 and 212 or the data using apparatuses 221 and 222 may be classified according to the type of memory provided in the data storing apparatus 230. Generate corresponding commands. For example, when the data storage device 230 includes a DRAM, each of the data generating devices 211 and 212 or the data using devices 221 and 222 generates a command for controlling the DRAM to access the DRAM. When the network device 240 is provided in the network system 200, the data generating devices 211 and 212 or the data using devices 221 and 222 access the data storage device 230 through the network device 240. Encapsulation to send a memory command as a network packet using hardware or software in a network interface (not shown) provided in each of the data generating apparatuses 211 and 212 or the data using apparatuses 221 and 222. Techniques can be used. The data storage device 230 extracts only a memory command from a network packet and processes the memory command to perform a data storage or read operation on the memory.

3 is a block diagram illustrating an embodiment of the network system of FIG. 2 in detail. As shown in FIG. 3, the network system 200 may include one or more data generating devices 211 and 212, one or more data using devices 221 and 222, a data storage device 230, and a network device 240. Equipped. Each data generating device, for example, the first data generating device 211 may include a data generating unit 211_1, a packet generating unit 211_2, and a network interface 211_3. In addition, each data using apparatus, for example, the first data using apparatus 221 may include a network interface 221_1, a packet generating unit 221_2, and a data receiving unit 221_3. In FIG. 3, the packet generation unit 211_2 and the network interface 211_3 of the first data generation unit 211 are illustrated as being separated from each other, but the function of the packet generation unit 211_2 is the network interface 211_3. It may be described as being included in. In addition, it may be described that the function of the packet generator 221_2 of the first data using apparatus 221 is included in the network interface 221_1.

Various data that may be generated from a data generating device such as a camera, an audio microphone, or a computer are converted into a network packet, and the network packet includes an address related to a destination on a network and a memory provided in the data storage device 230. Commands and data to be used on other devices. The network packet generated by the packet generator 211_2 is provided to the network interface 211_3, and the network packet is transmitted to the network device 240 through the network interface 211_3.

The network device 240 checks the address information of the network packet, and in response, transmits the network packet to a corresponding destination on the network. According to an embodiment of the present invention, the address included in the network packet always causes the data storage device 230 to be a destination on the network. Accordingly, the network device 240 transmits the network packet to the data storage device 230 in response to the address. The data storage device 230 extracts a data storage command and processes the data storage command to store data included in a network packet in a memory.

Meanwhile, the packet generator 221_2 of the first data using apparatus 221 converts a data read command into a network packet and transmits it to the network apparatus 240 through the network interface 221_1. The network packet generated by the first data using device 221 also includes an address indicating a destination on the network. The address of the network packet generated by the first data using device 221 also makes the data storage device 230 a destination on the network at all times. The data storage device 230 receives a network packet from the first data using device 221 and extracts a data read command from the received network packet. In addition, in response to the data read command, a read operation is performed on the memory, and the read data is provided to the network device 240. The network device 240 transmits the read data to the first data using device 221 which made a data request.

4A, 4B, and 4C are block diagrams illustrating one embodiment of a network device and a data storage device of the network system of FIG. 2, and one embodiment of a network packet. As shown in FIG. 4A, the data storage device 230 included in the network system 200 includes a network interface 231, a command extractor 232, a memory controller 233, and a memory unit 234. It can be provided. The network interface 231 is connected to the network device 240 to transmit and receive network packets. The command extractor 232 extracts a memory command from the network packet received from the network interface 231 and provides it to the memory controller 233. The memory controller 233 processes the extracted command to generate a signal for controlling the memory unit 234. Accordingly, data is stored in the memory unit 234 or data stored in the memory unit 234 is read. The read data is provided to the network device 240 through the memory controller 233 and the network interface 231, and the network interface 231 may convert the read data into a network packet. The network device 240 transmits the network packet including the read data to the requested data using device.

When a plurality of data using devices 221 and 222 share a single data storage device 230, each of the data using devices 221 and 222 may access a required data block independently of each other. Alternatively, the data using devices 221 and 222 may simultaneously access the same data block of the data storage device 230.

Fig. 4B shows a network packet when Ethernet is used as the network system of the present invention and a SATA HDD is used as the data storage device. As shown in FIG. 4B, the network packet may be generated by encapsulating the SATA of the HDD. The data generating apparatuses 211 and 212 or the data using apparatuses 221 and 222 respectively generate network packets by encapsulating the SATA of the HDD, and transmit them to the network apparatus 240 through each network interface. If it is not possible to encapsulate both the command and data of the data storage device in one network packet, it may be transmitted by dividing it into a plurality of network packets.

The data storage device 230 stores the received data in its own data storage unit. If the data storage device 230 includes a SATA HDD type memory, the data provided to the data storage device 230 is stored in data block units defined in the SATA protocol. That is, if the data generating apparatuses 211 and 212 are provided with the SATA HDD type memory, the network device 240 is stored in the block unit in the same way as the generated data is stored in the SATA HDD block unit. It may be transmitted to the data storage device 230 through. In addition, the data storage device 230 stores the data in the memory as it is in the block unit. If the data storage device 230 includes a DRAM or a flash memory, data storage and reading units may be defined in units of pages.

Meanwhile, as shown in FIG. 4C, the network device 240 may include an address verification unit 241 and a data transmission / reception unit 242. Meanwhile, the network packets shown in FIG. 4C (hereinafter, first network packets 211_4 and 211_5) are packets generated by the data generating device, and other network packets (hereinafter, second network packets 221_4 and 221_5) are data. These packets are generated by the device. As shown, the addresses of the network packets 211_4, 211_5, 221_4, and 221_5 represent the same destination on the network. For example, the addresses Add1 of the network packets 211_4, 211_5, 221_4, and 221_5 are The memory device 230 is shown as its destination. In addition, the commands CMD1 and CMD2 included in the network packets 211_4, 211_5, 221_4, and 221_5 are storage commands for storing data in the memory device 230, and other commands CMD3 and CMD4 are memory. A read command for reading data stored in the device 230. In addition, the first network packets 211_4 and 211_5 may further include data DATA1 and DATA2 that need to be stored in the memory device 230. The address checking unit 241 checks the address Add1 and generates a control signal corresponding thereto, and the data transmitting / receiving unit 242 receives the network packets 211_4, 211_5, 221_4, and 221_5 based on the address checking result. The data is transferred to the storage device 230.

According to the present invention as described above, the data generated by the data generating apparatuses 211 and 212 are not directly transmitted to the data using apparatuses 221 and 222 through a plurality of paths, but the generated data is stored in the data storage apparatus ( 230 may be provided in common to store data at high speed. In addition, the data using devices 221 and 222 do not directly receive data through a plurality of paths, but access the data storage device 230 through the same path, so that the data stored in the data storage device 230 may be stored in a plurality of data paths. It is to be transmitted in real time to the data using apparatus (221, 222). As a result, the network system 200 minimizes the number of data movement paths, thereby storing data at high speed and allowing various devices to use the data. In addition, since the data generated in each of the data generating apparatuses 211 and 212 need not be provided to the plurality of data using apparatuses 221 and 222, the total data movement amount can be minimized by minimizing the number of movements of the data.

5 is a block diagram illustrating an example of a videoconferencing system implemented by the network system of the present invention. As shown in FIG. 5, the video conferencing system 300 may include a plurality of data generating / using devices 310 and 320, a data storage device 330, and a network device 340. Each of the data generation / use devices 310 and 320 includes a device for generating data and a device for using data at the same time. Each of the data generation / use apparatuses 310 and 320 of the videoconferencing system 300 may be configured as a single terminal. For example, the first data generation / use apparatus 310 may include a camera 311 as a data generation apparatus. A monitor 312 as a data usage device may be provided.

In the conventional video conferencing system, image data from a camera generated in one terminal is simultaneously provided to a plurality of other terminals, and thus, multiple data paths for transmitting the image data have to be implemented in the system. . Considering the complexity of the data path and the data transmission capacity, the number of terminals that can be provided in the videoconferencing system has been limited. However, as shown in FIG. 5, in the videoconferencing system 300 according to an embodiment of the present invention, each of the data generation / use apparatuses 310 and 320 transmits and receives data through a common data path. . That is, data generated from the data generation / use devices 310 and 320 are transmitted using the data storage device 330 as a destination through a path common to each other. As an example, the first data generation / use device 310 transmits a network packet to the data storage device 330 through the first data path. The network packet including the data request from the remaining data generating / using devices is transmitted to the data storage device 330 through the first path. Read data from the data storage device 330 is provided to the remaining data generation / use devices through the second data path. The first data path and the second data path may be embodied in physically the same path or may be embodied in different paths.

In the video conferencing system 300 of the present invention implemented as described above, even if the number of participating conference rooms increases, the data transmission path from the camera is the same, so the performance is improved even if the number of conference rooms of the video conference system 300 increases. Data can be delivered efficiently without degradation. That is, the data generated from the camera is stored only in the data storage device 330 without being directly transmitted to the data using device, and the monitor using the data displays the screen only by accessing the data storage device 330. can do. In addition, in the related art, a plurality of data generating apparatuses (eg, cameras) and data using apparatuses should be maintained. However, according to an embodiment of the present invention, the plurality of data generating apparatuses maintain only a connection with a data storage apparatus. Therefore, the number of data movement paths can be minimized, and the data using device can efficiently transfer data without maintaining connection overhead with the data generating device.

6 is a block diagram illustrating an example of a surveillance camera system implemented by a network system of the present invention. As shown in FIG. 6, the surveillance camera system 400 includes a plurality of surveillance cameras 411, 412, 413, a monitor system 420, one or more data storage devices 431, 432, and a network device 440. ) May be provided. The monitor system 420 may be implemented as a DVR (Digital Video Recorder) for processing image data from the surveillance cameras 411, 412, and 413.

In the conventional surveillance camera system, the DVR provided in the system had to be provided with a process for displaying data transmitted from cameras therein and a process for storing the transmitted data in the DVR. Surveillance camera system of this type, there is a limitation in the performance of the data transmission, storage and use process that one DVR system can operate. Accordingly, there is a limit on the number of cameras that can be connected to one DVR system. In addition, as the number of cameras that can be connected to one DVR system is limited, the surveillance camera system must be provided with a plurality of DVR systems, thereby increasing the complexity of the data transmission path between the plurality of cameras and the plurality of DVR systems. Done.

According to the surveillance camera system 400 of an embodiment of the present invention, as shown in FIG. 6, the data generated from the plurality of surveillance cameras 411, 412, and 413 is stored in the data storage device through the network device 440. 431, 432. Data generated from one camera, for example, the first camera 411 may be provided to any one of the data storage devices 431 and 432. When the surveillance camera system 400 is provided with two data storage devices 431 and 432, data from some of the plurality of surveillance cameras 411, 412 and 413 is stored in the data storage devices 431 and 432. The data from the other camera may be provided to the other data storage device. That is, even in the surveillance camera system 400 of the present invention, there may be two or more transmission paths of the generated data to the data storage devices 431 and 432, but the number of the transmission paths is the data storage devices 431 and 432. Since the number of transmission paths is related, the number of transmission paths does not increase significantly. Although not shown in FIG. 6, as described above, each of the plurality of monitoring cameras 411, 412, and 413 may include an interface unit for interfacing with the network device 440. And the converted network packet to the network device 440.

Meanwhile, the monitor system 420 for performing a surveillance operation using the images from the surveillance cameras 411, 412, and 413 performs a surveillance operation by using data stored in the data storage devices 431 and 432. Monitor system 420 includes a process for accessing data storage 431, 432 to receive data. According to the above configuration, since the limitation of the total amount of data generated from the surveillance cameras 411, 412, 413, data storage performance, and display performance does not occur, the number of surveillance cameras, the video storage capacity, and the number of display monitors are not generated. The system can be economically constructed without any limitations. In addition, in storing data, data may be stored in units of blocks or pages according to the type of memory provided in the storage device, and thus, a unit of data to be stored may be selected, thereby easily transmitting and storing data in real time. Simultaneous use is possible.

7 is a flowchart illustrating a method of operating a network system according to an embodiment of the present invention. As shown in FIG. 7, when data is generated in the data generating apparatus (S11), a first network packet is generated using the first command for controlling the memory of the data storage apparatus included in the network system and the data. (S12). The first command relates to a storage command for storing data in a memory, wherein the first network packet further includes an address indicating a transmission destination on the network.

The first network packet generated as described above is provided to the network device, and the network device checks the address of the first network packet and transmits the first network packet to the data storage device (S13). The data storage device extracts a first command from the first network packet, processes the extracted first command, and stores the data in the memory unit (S14).

Meanwhile, in order to use the data stored in the data storage device, the data using device converts the second command into a second network packet and provides the converted second network packet to the network device (S15). The second network packet further includes an address indicating a transmission destination on the network. The network device checks the address of the second network packet and transmits the second network packet to a data storage device (S16). The data storage device extracts a second command from the second network packet and processes the extracted second command to read data stored in the memory unit (S17). The read data is converted into a network packet and provided to a network device, which provides the network packet to a data using device. Through the above process, the data using device receives data stored in the data storage device (S18).

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

200: network system
211, 212: data generator
221, 222: data using device
230: data storage
240: network device

Claims (12)

Receiving a first network packet generated from a plurality of data generating devices and including data and storage commands, and a second network packet generated from a plurality of data using devices and containing a read command, wherein the received first and second A network device for processing network packets; And
A memory unit connected to the network device to receive the first and second network packets via the network device, and to process data storage commands included in the first network packet to receive data from the data generation device; A data storage device configured to read a data stored in the memory unit by processing the data read command included in the second network packet,
Each of the first and second network packets includes an address having information destined for the data storage device on a network;
First network packets from the plurality of data generating devices are transmitted to the data storage device through a common path, and in response to the second network packets from the plurality of data using devices, the memory unit via the common path. Network data characterized in that the stored data is accessed. delete The method of claim 1,
The memory unit of the data storage device includes any one of a DRAM, a flash memory, and a hard disk drive (HDD),
And the storage instruction included in the first network packet from the data generating apparatus has a protocol corresponding to the type of the memory portion of the data storage apparatus. delete The data storage device of claim 1, wherein the data storage device comprises:
A network interface unit for interfacing with the network device;
A command extracting unit for extracting a data storing command or a data reading command from a first or second network packet received through the network interface unit; And
And a memory controller configured to process the extracted command and to store data or read data in the memory unit. The method of claim 1,
The data generating apparatus is a camera for generating image data by capturing an image, and the data using apparatus is a monitor system for monitoring image data from the camera. The method of claim 1,
The data generating device and the data using device implement one terminal, the data generating device of the one terminal is a camera and the data using device is a monitor, and the system is configured to display data from any one terminal at least. A network system, comprising: a video conference system for transmitting to one terminal.
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