CN216927601U - ARM server - Google Patents

Abstract

The disclosure provides an ARM server, relates to the technical field of computers, and particularly relates to the technical field of cloud mobile phones, cloud computing and cloud service. The specific implementation scheme is as follows: an ARM server comprises at least one ARM board card unit, a switching unit of the ARM board card unit, and a communication port of the switching unit, wherein the ARM board card unit comprises at least one ARM core board; at least one ARM core board in the ARM board card unit is in communication connection with a communication port of the exchange unit through the exchange unit of the ARM board card unit; and business data are transmitted between the at least one ARM core board and the communication port. The method and the device have the advantages that the effect of carrying out service processing based on the ARM core board in the ARM server is achieved, and therefore the use cost of the server is reduced.

Description

ARM server

Technical Field

The disclosure relates to the technical field of computers, in particular to a cloud server, cloud computing and cloud service technology field, and especially relates to an ARM server.

Background

With the development of network technology, more and more functions and services are integrated in various websites, and people can acquire various information through different types of websites. How to quickly establish a website becomes a problem which needs to be solved by the chief standing.

Most of the website building servers in the prior industry are built based on an X86 architecture.

Disclosure of Invention

The disclosure provides an ARM server for performing service processing based on an ARM core board.

According to one aspect of the disclosure, an ARM server is provided, which includes at least one ARM board card unit, a switching unit of the ARM board card unit, a communication port of the switching unit, and the ARM board card unit including at least one ARM core board;

at least one ARM core board in the ARM board card unit is in communication connection with a communication port of the exchange unit through the exchange unit of the ARM board card unit; and business data are transmitted between the at least one ARM core board and the communication port.

It should be understood that the statements in this section are not intended to identify key or critical features of the embodiments of the present disclosure, nor are they intended to limit the scope of the present disclosure. Other features of the present disclosure will become apparent from the following description.

Drawings

The drawings are included to provide a better understanding of the present solution and are not to be construed as limiting the present disclosure. Wherein:

fig. 1 is a schematic structural diagram of an ARM server according to an embodiment of the disclosure;

fig. 2 is a schematic structural diagram of an ARM server according to an embodiment of the present disclosure.

Detailed Description

Exemplary embodiments of the present disclosure are described below with reference to the accompanying drawings, in which various details of the embodiments of the disclosure are included to assist understanding, and which are to be considered as merely exemplary. Accordingly, those of ordinary skill in the art will recognize that various changes and modifications of the embodiments described herein can be made without departing from the scope and spirit of the present disclosure. Also, descriptions of well-known functions and constructions are omitted in the following description for clarity and conciseness.

In the research and development process of the applicant, most of the station building servers in the prior art are built based on an X86 architecture, but the servers of the X86 architecture lack the exclusive performance optimization of the station building scene, and many functions which do not belong to the station building scene are integrated into a background console, so that the cost price of the servers of the X86 architecture is high, the calculation is wasted, the energy consumption is high, and partial station building users move to develop small programs. Therefore, the site establishment market needs a product for reducing the site establishment cost.

Fig. 1 is a schematic structural diagram of an ARM server disclosed in the embodiment of the present disclosure, which may be applied to a case of performing service processing based on an ARM core board.

As shown in fig. 1, the ARM server 100 disclosed in this embodiment includes at least one ARM board card unit 101, a switching unit 102 of the ARM board card unit 101, a communication port 103 of the switching unit 102, and the ARM board card unit 101 includes at least one ARM core board 104;

at least one ARM core board 104 in the ARM board card unit 101 is in communication connection with a communication port 103 of the switching unit 102 through the switching unit 102 of the ARM board card unit 101; and business data is transmitted between the at least one ARM core board 104 and the communication port 103.

In one configuration, the ARM server 100 includes a chassis, at least one ARM board card unit 101 is disposed inside the chassis, a switching unit 102 of the ARM board card unit 101, and a communication port 103 of the switching unit 102 is disposed on a surface of the chassis.

The number of ARM board card units 101 may be set according to specific service requirements, and four ARM board card units 101 are used as an example in this embodiment for explanation. The ARM board card unit 101 is an integrated motherboard, and has a function of integrating at least one processing board card, and generally, the ARM board card units 101 can be distinguished by functions, that is, the processing board cards having the same service function are disposed in the same ARM board card unit 101. The arrangement of ARM board card units 101 in the chassis includes, but is not limited to, a vertical parallel arrangement or a horizontal parallel arrangement.

ARM board card unit 101 includes at least one ARM core board 104, wherein the number of ARM core boards 104 in each ARM board card unit 101 may be set according to actual service requirements, and this embodiment is explained by taking an example in which each ARM board card unit 101 includes four ARM core boards 104. The ARM core board 104 is a system chip that integrates an ARM core, a storage device, a register, and pins, and is connected to the ARM board unit 101 through the pins to realize a service processing capability. ARM core board 104 may be disposed in ARM board unit 101 in a detachable manner, and may also be disposed in ARM board unit 101 in an integrated manner, for example, in a welding manner. In other words, when the ARM core board 104 is detachably disposed in the ARM board card unit 101, a technician can adjust the type of the ARM core board 104 in the ARM board card unit 101 in real time according to a change of a service requirement or a calculation requirement, so that the adaptability is stronger; when the ARM core board 104 is arranged in the ARM board card unit 101 in an integrated manner, the ARM board card unit 101 and the ARM core board 104 can be conveniently mass-produced, so that the ARM core board can be rapidly put into actual business.

The switch unit 102 and the ARM board card unit 101 have an association relationship, in this embodiment, an example in which one switch unit 102 is associated with one ARM board card unit 101 is taken as an explanation, and the embodiment does not limit a specific association form, for example, one switch unit 102 is associated with at least two ARM board card units 101; for another example, at least two switch units 102 are associated with one ARM board card unit 101, which are also within the protection scope of the present embodiment. Optionally, the type of the switching unit 102 may be a Media Access Controller (MAC) unit, which includes a hardware Controller and a related communication protocol, and is configured to implement functions including data forwarding, ARM core board configuration, and message data verification.

The switch unit 102 and the communication port 103 have an association relationship, in this embodiment, an example that one switch unit 102 associates one communication port 103 is taken as an explanation, and the embodiment does not limit a specific association form, for example, one switch unit 102 associates at least two communication ports 103; for another example, at least two switching units 102 are associated with one communication port 103, which are also within the protection scope of the present embodiment.

The switching unit 102 is communicatively connected to the ARM core board 104 in the associated ARM board card unit 101, and is communicatively connected to the associated communication port 103. Correspondingly, the ARM core board 104 may be communicatively connected to the communication port 103 through the switching unit 102, and the switching unit 102 is configured to forward service data between the ARM core board 104 and the communication port 103. For example, the external switch sends a service processing request to the communication port 103, the communication port 103 sends the service processing request to the switching unit 102, the switching unit 102 forwards the service processing request to the ARM core board 104, so that the ARM core board 104 performs service processing according to the service processing request by using a software platform defined in advance, and sends a service processing result to the switching unit 102, and the switching unit 102 forwards the service processing result to the communication port 103, so that the communication port 103 sends the service processing result to the external switch, and a user can obtain the service processing result.

This is disclosed through with at least one ARM core plate in the ARM integrated circuit board unit, through the switching unit of ARM integrated circuit board unit, with the communication port communication connection of switching unit, transmit business data between at least one ARM core plate and the communication port, the effect of carrying out business processing based on ARM core plate in the ARM server has been realized, because ARM core plate is for the processing board of X86 framework, can greatly reduced consumption and cost, thereby corresponding use cost who has reduced the server.

On the basis of the above embodiments, this embodiment further provides an implementation manner in which the external switch accesses the ARM core board in the ARM server.

Specifically, a mapping relationship table between a communication port of the ARM server and an ARM core board is prestored in the external switch, and this embodiment is explained by taking an example that the ARM server includes four communication ports, i.e., a communication port 1, a communication port 2, a communication port 3, and a communication port 4, and includes 96 ARM core boards with serial numbers ranging from 0 to 95.

For example, the ARM core board with the number of 0-23 is mapped with the communication port 1, the ARM core board with the number of 24-47 is mapped with the communication port 2, the ARM core board with the number of 48-71 is mapped with the communication port 3, the ARM core board with the number of 72-95 is mapped with the communication port 4, and the mapping relation is stored in the external switch in the form of a mapping relation table. In other words, the external switch connection communication port 1 can access the ARM core boards with the numbers of 0 to 23, the external switch connection communication port 2 can access the ARM core boards with the numbers of 24 to 47, the external switch connection communication port 3 can access the ARM core boards with the numbers of 48 to 71, and the external switch connection communication port 4 can access the ARM core boards with the numbers of 72 to 95.

The external switch acquires an access request aiming at any ARM core board in the ARM server from the client, analyzes the access request to determine the number of the ARM core board, and determines a communication port of the ARM server to be connected according to the number and the mapping relation table. For example, if the number of the ARM core board is 20 obtained through analysis, and the ARM core board with the number of 20 in the mapping relationship table has a mapping relationship with the communication port 1, the communication port 1 is used as a communication port to be connected to the ARM server.

Fig. 2 is a schematic structural diagram of an ARM server disclosed according to an embodiment of the present disclosure, which is further optimized and expanded based on the above technical solution, and can be combined with the above various optional structural forms.

As shown in fig. 2, the ARM server 100 disclosed in this embodiment may include:

on the basis of the above embodiment, the ARM core board 104 in the ARM board card unit 101 is disposed in the ARM board card unit 101 through the board card slot.

In one structural form, a board card slot is preset in the ARM board card unit 101, and a technician can clamp the ARM core board 104 in the board card slot according to actual service requirements, so as to set the ARM core board 104 in the ARM board card unit 101.

Through the integrated circuit board draw-in groove with ARM core plate through ARM integrated circuit board unit, set up in ARM integrated circuit board unit, guaranteed ARM core plate's detachability, improved the flexibility and the application scope of ARM integrated circuit board unit.

On the basis of the above embodiment, the ARM server 100 further includes a management unit 105 and a configuration interface 106; the management unit 105 is in communication connection with the configuration interface 106, and is also in communication connection with the ARM core board 104 through a synchronous serial bus; the ARM core board 104 transmits its own operating environment data to the configuration interface 106 through the management unit 105.

The Management unit 105 may be a BMC (Baseboard Management Controller) unit, and is a dedicated service processor or ARM PC cluster, which monitors the state of the ARM core board 104 by using a sensor, and communicates with an external device through an independent connection line and a configuration interface 106, so as to implement functions including monitoring of operating environment data of the ARM core board 104 and power supply control.

In one form of construction, a management unit 105 is provided within the housing of ARM server 100 and a configuration interface 106 is provided on the housing surface. The management unit 105 is communicatively connected to each ARM core board 104 and to the configuration interface 106, so that the ARM core board 104 can transmit its operating environment data to the configuration interface 106 through the management unit 105. The configuration interface 106 may further transmit the runtime environment data to an external switch to enable a user to monitor the runtime environment data of the ARM core board 104. The operating environment data includes, but is not limited to, temperature, voltage, and power status, among others. The configuration interface 106 may optionally include a Console interface, preferably an RJ45 interface.

The ARM core board transmits the running environment data to the configuration interface through the management unit, so that the real-time monitoring of the running environment data of the ARM core board by a user is realized, and the safety and the stability of the server are improved.

On the basis of the above embodiment, the management unit 105 is further configured to obtain a power supply instruction for the ARM core board 104 from the configuration interface 106, and adjust a power supply state of the ARM core board 104 according to the power supply instruction.

In one configuration, the management unit 105 obtains a power supply instruction issued by a user from the configuration interface 106, and controls a power supply state of the ARM core board 104 in communication connection according to the power supply instruction. For example, when the power supply instruction is a power-on instruction, the ARM core board 104 is controlled to be powered on; for another example, when the power supply command is a power-down command, the ARM core board 104 is controlled to power down. The power supply associated with power-on/power-off may be an internal power supply of the ARM server 100, or an external power supply of the ARM server 100, and the specific structural form of the power supply is not limited in this embodiment.

The power supply instruction of the ARM core board is acquired from the configuration interface through the management unit, and the power supply state of the ARM core board is adjusted according to the power supply instruction, so that the effect that a user controls the ARM core board to be powered on or powered off according to the requirement of the user is achieved, and the flexibility of the server is improved.

On the basis of the above embodiment, the switching unit 102 is further configured to obtain a working parameter configuration instruction for the ARM core board 104 from the communication port 103, and adjust the working parameter of the ARM core board 104 according to the working parameter configuration instruction.

In one structural form, the switching unit 102 obtains a working parameter configuration instruction issued by a user from the communication port 103, and mediates a working parameter of the ARM core board 104 in communication connection according to the working parameter configuration instruction. The operating parameters include, but are not limited to, an operating voltage and/or an operating frequency of the ARM core board 104.

The working parameter configuration instruction of the ARM core board is acquired from the communication port through the switching unit, and the working parameters of the ARM core board are adjusted according to the working parameter configuration instruction, so that the effect that a user adjusts the working parameters of the ARM core board according to the requirement of the user is achieved, and the flexibility of the server is improved.

On the basis of the above embodiment, the switching unit 102 is further configured to check and alarm the message data acquired from the communication port 103.

In one structural form, the switching unit 102 acquires the message data sent by the user from the communication port 103, performs validity check on the message data, continues to forward the message data to the ARM core board 104 if the check is passed, and generates alarm information and transmits the alarm information to the communication port 103 if the check is not passed, so as to feed the alarm information back to the user through the communication port 103.

The message data acquired from the communication port is checked and alarmed through the switching unit, and the legality of the received message data is guaranteed.

On the basis of the above embodiment, at least two switching units 102 in the same group are connected through a high-speed serial computer expansion bus and a HiGig bus in a communication manner; the communication ports 103 of the group switching units 102 belong to the same communication port group.

The high-speed serial computer expansion bus is PCIe bus. The HiGig bus is a line used for direct cascade connection between chips, can be used for in-board connection, and can also realize cross-board connection in a backboard wiring mode, so that mirroring, aggregation and the like of ports between the chips are realized.

In one configuration, the switching unit 102 associated with each communication port 103 in the same communication port group is used as a group switching unit. And the same group of switching units are connected through high-speed serial computer expansion bus and HiGig bus communication. No communication connection is made between the different group switching units.

As shown in fig. 2, the communication ports 103 numbered 4 and 3 are the same communication port group, and the communication ports 103 numbered 2 and 1 are the same communication port group. Correspondingly, the switching units 102 respectively associated with the communication ports 103 with the reference numbers 4 and 3 are used as the same group switching units; the switching units 102 associated with the communication ports 103, numbered 2 and 1, respectively, act as a group switching unit.

The high-speed serial computer expansion bus and the HiGig bus are in communication connection between at least two same-group switching units; the communication ports of the same group of switching units belong to the same communication port group, so that the effect of data communication between the ARM core boards corresponding to the same group of switching units is realized, and the normal operation of the cooperative service processing function between the ARM core boards is ensured.

On the basis of the above embodiment, the switching unit 102 and the ARM core board 104 are communicatively connected through an ethernet cable.

Among them, ethernet is a computer local area network technology. It specifies the contents of the wiring, electrical signals and medium access layer protocols, which comprise the physical layer.

Through exchange unit and ARM nuclear core plate through ethernet line communication connection, improved the data transmission rate between exchange unit and the ARM nuclear core plate.

On the basis of the above embodiment, the communication port 103 is a fiber port.

Among them, the optical fiber port is preferably an SFP + (Small Form-factor plug connectors) port. The optical fiber port in this embodiment may be optionally a 10G optical fiber port.

The communication port is set as the optical fiber port, so that the effect of optical fiber communication between the server and the outside is realized, and the data transmission speed of the server is improved.

On the basis of the above embodiment, the service data includes website construction parameter data.

The website building parameter data includes, but is not limited to, website name, IP address, port number, domain name, home directory path name, access right, and the like.

In one structural form, the external switch sends website construction parameter data to the communication port 103, the communication port 103 sends the website construction parameter data to the switching unit 102, and the switching unit 102 forwards the website construction parameter data to the ARM core board 104, so that the ARM core board 104 performs website construction by using a software platform defined in advance according to the website construction parameter data. The ARM core board 104 supports multiple operating system platform ecology, including but not limited to CentOS, Ubuntu, kylin, android, deep, and the like; the ARM core board 104 also supports a variety of compilers and tool chains, including but not limited to C, Python, PHP, GO, Java, GCC, GDB, and the like; ARM core board 104 also supports a variety of basic software including, but not limited to, MySQL, PostgreSQL, Hadoop, Hive, Nginx, Apache, and Tomcat, among others; ARM core board 104 also supports a variety of middleware including, but not limited to, ActiveMQ, RabbitMQ, Redis, MemCached, and the like; the ARM core board 104 also supports a variety of applications including, but not limited to, Portal, CRM, ERP, and AI, among others.

The business data comprises the website construction parameter data, the website construction effect based on the ARM server is achieved, and compared with a processing board with an X86 framework, the ARM core board can greatly reduce power consumption and cost, so that the use cost of the website construction server is correspondingly reduced. Moreover, when the processing board of the conventional X86 architecture simultaneously runs a plurality of services of different users, security isolation must be performed, but in the present disclosure, since each ARM core board can only interface with a natural feature used by one user at the same time, security isolation of a single ARM core board is not required, and only cluster isolation is required.

On the basis of the above embodiment, if each communication port in the same communication port group in the ARM server is connected to the external switch at the same time, the external switch is controlled to statically aggregate the configuration of the connection ports, so as to avoid the problem of communication loop in the external switch.

The embodiment of the present disclosure further provides an optional working method of the switching unit in the ARM server:

a1, the current exchange unit obtains the service request from the related communication port, and determines the target ARM core board according to the service request.

Specifically, the external switch determines a target communication port from each communication port of the ARM server disclosed in this embodiment according to core board identification information of a target ARM core board to be accessed and a mapping relationship between pre-stored core board identification information and the port, and sends a service request carrying the core board identification information to the target communication port. And the current switching unit in the ARM server, which is associated with the target communication port, acquires the service request from the target communication port, and further analyzes the service request to acquire core board identification information carried by the service request. The current exchange unit matches the core board identification information with core board identification information corresponding to each ARM core board in the ARM server, and determines a target ARM core board according to a matching result. The core board identification information includes, but is not limited to, a number of the ARM core board, and the like.

And B1, the current switching unit transmits the service request to the target ARM core board, so that the target ARM core board generates service data according to the service request.

Specifically, after the current switching unit determines the target ARM core board, it is determined whether the target ARM core board belongs to its associated ARM board unit, and if it is determined that the target ARM core board belongs to its associated ARM board unit, the service request is directly forwarded to the target ARM core board through communication connection between the current switching unit and the target ARM core board. And after the target ARM core board receives the service request, performing service processing according to the service request to generate service data.

If the current switching unit determines that the target ARM core board does not belong to the ARM board card unit associated with the target ARM core board, namely, no communication connection exists between the switching unit and the target ARM core board, whether the target ARM core board belongs to any ARM board card unit associated with any same group of switching units of the current switching unit is continuously determined, and if the target ARM core board is determined to belong to any ARM board card unit associated with any same group of switching units of the current switching unit, the current switching unit sends the service request to the same group of switching units, so that the same group of switching units forwards the service request to the target ARM core board through the communication connection between the same group of switching units and the target ARM core board. And after the target ARM core board receives the service request, performing service processing according to the service request to generate service data.

And if the current switching unit determines that the target ARM core board does not belong to any ARM board card unit associated with any switching unit in the same group of the current switching unit, generating abnormal feedback information, sending the abnormal feedback information to the target communication port, sending the abnormal feedback information to the external switch through the target communication port, determining the communication port again by the external switch, and continuously accessing the target ARM core board based on the updated communication port.

And C1, the current switching unit acquires the service data from the target ARM core board and transmits the user service data to the communication port.

Specifically, after the target ARM core board generates the service data according to the service request, if the target ARM core board belongs to an ARM board card unit associated with the current switching unit, the current switching unit directly obtains the service data from the target ARM core board through communication connection between the current switching unit and the target ARM core board, and forwards the service data to the target communication port, so that the target communication port sends the service data to the external switch.

After the target ARM core board generates service data according to the service request, if the target ARM core board belongs to any ARM board card unit associated with the same group of switching units of the current switching unit, the same group of switching units acquire the service data from the target ARM core board through communication connection with the target ARM core board, the service data are forwarded to the current switching unit, and the current switching unit forwards the service data to the target communication port, so that the target communication port sends the service data to an external switch.

The embodiment of the present disclosure further provides an optional working method of the switching unit in the ARM server:

a2, the current exchange unit obtains the service request from the related communication port, and determines the target ARM core board according to the service request.

And B2, under the condition that the target ARM core board is disconnected from the current switching unit in communication and is connected with the first switching unit in communication, transmitting the service request to the first switching unit, so that the first switching unit transmits the service request to the target ARM core board, and the target ARM core board generates service data according to the service request.

The first switching unit and the current switching unit belong to the same group of switching units, and the communication ports of the same group of switching units belong to the same communication port group.

Specifically, the current switching unit determines whether the current switching unit is in Ethernet communication connection with a target ARM core board, if the current switching unit is determined not to be in Ethernet communication connection with the target ARM core board, whether any one group of switching units of the current switching unit is in Ethernet communication connection with the target ARM core board is continuously determined, if yes, the group of switching units are used as first switching units, and service requests are sent to the first switching units, so that the first switching units forward the service requests to the target ARM core board, and the target ARM core board performs service processing according to the service requests to generate service data.

For example, it is assumed that the ARM board card unit associated with the current switching unit includes an ARM core board with a number of 0 to 23, that is, the current switching unit is in ethernet communication connection with the ARM core board with the number of 0 to 23, and if the number of the target ARM core board is 40, it indicates that the target ARM core board is not in ethernet communication connection with the current switching unit. And an ARM board card unit associated with one group of switching units of the current switching unit comprises an ARM core board with the serial number of 24-47, namely the same group of switching units are in Ethernet communication connection with the target ARM core board, the same group of switching units are used as first switching units, and the current switching unit sends a service request to the first switching units.

C2, the current switching unit obtains the service data from the first switching unit and transmits the service data to the communication port.

Specifically, after the target ARM core board generates the service data, the service data is sent to the first switching unit, and the current switching unit acquires the service data from the first switching unit and transmits the service data to the communication port.

The embodiment of the present disclosure further provides an optional working method of the switching unit in the ARM server:

a3, the current exchange unit obtaining an auxiliary service request from any ARM core board in communication connection, and determining the auxiliary ARM core board according to the auxiliary service request; the second switching unit of the auxiliary ARM core board and the current switching unit of the ARM core board belong to the same group of switching units.

When a certain service request needs the cooperative processing of at least two ARM core boards, the ARM core board receiving the service request generates an auxiliary service request, so that the auxiliary ARM core board performs the service processing in cooperation with the ARM core board according to the auxiliary service request.

Specifically, the current switching unit acquires an auxiliary service request from any ARM core board in communication connection, analyzes the auxiliary service request to determine a core board identifier of the auxiliary ARM core board, matches the core board identifier information with core board identifier information corresponding to each ARM core board in the ARM server, and determines the auxiliary ARM core board according to a matching result.

B3, the current switching unit transmits the auxiliary service request to the second switching unit, so that the second switching unit transmits the auxiliary service request to the auxiliary ARM core board.

Specifically, when the second switching unit in communication connection with the auxiliary ARM core board and the current switching unit in communication connection with the ARM core board belong to the same group of switching units, the current switching unit sends the auxiliary service request to the second switching unit, so that the second switching unit sends the auxiliary service request to the auxiliary ARM core board.

C3, the current switching unit obtains the auxiliary service data from the second switching unit, and transmits the auxiliary service data to the ARM core board; and the auxiliary service data is generated by the auxiliary ARM core board according to the auxiliary service request.

Specifically, after the auxiliary ARM core board generates auxiliary service data according to the auxiliary service request, the auxiliary service data is sent to the second switching unit, and the current switching unit acquires the auxiliary service data from the second switching unit and sends the auxiliary service data to the ARM core board, so as to complete the cooperative service processing between the ARM core board and the auxiliary ARM core board.

The above detailed description should not be construed as limiting the scope of the disclosure. It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and substitutions may be made in accordance with design requirements and other factors. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present disclosure should be included in the scope of protection of the present disclosure.

Claims (10)

1. An ARM server comprises at least one ARM board card unit, a switching unit of the ARM board card unit and a communication port of the switching unit, wherein the ARM board card unit comprises at least one ARM core board;

at least one ARM core board in the ARM board card unit is in communication connection with a communication port of the exchange unit through the exchange unit of the ARM board card unit; and business data are transmitted between the at least one ARM core board and the communication port.

2. The ARM server of claim 1, wherein an ARM core board in the ARM board unit is disposed in the ARM board unit through a board card slot.

3. The ARM server of claim 1, wherein the ARM server further comprises a management unit and a configuration interface;

the management unit is in communication connection with the configuration interface and is also in communication connection with the ARM core board through a synchronous serial bus;

the ARM core board transmits the running environment data to the configuration interface through the management unit.

4. The ARM server of claim 3, wherein the management unit is further configured to obtain a power supply instruction for the ARM core board from the configuration interface, and adjust a power supply state of the ARM core board according to the power supply instruction.

5. The ARM server of claim 1, wherein the switch unit is further configured to obtain an operating parameter configuration instruction for the ARM core board from the communication port, and adjust the operating parameter of the ARM core board according to the operating parameter configuration instruction.

6. The ARM server of claim 1, wherein the switching unit is further configured to check and alarm message data obtained from the communication port.

7. The ARM server of claim 1 wherein at least two switch units in the same group are communicatively coupled via a high speed serial computer expansion bus and a HiGig bus; and the communication ports of the same group of switching units belong to the same communication port group.

8. The ARM server of claim 1, wherein the switch unit and the ARM core board are communicatively connected via an Ethernet line.

9. The ARM server of claim 1, wherein the communication port is a fiber port.

10. The ARM server of claim 1, wherein the traffic data comprises website build parameter data.

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