CN109144824B

CN109144824B - Running state display device of double-path server node

Info

Publication number: CN109144824B
Application number: CN201810797884.6A
Authority: CN
Inventors: 程鹏飞; 赵振伟; 闵敏; 杜梦强; 张昌辉
Original assignee: Zhongke Sugon Information Industry Chengdu Co ltd; Dawning Information Industry Beijing Co Ltd
Current assignee: Zhongke Sugon Information Industry Chengdu Co ltd
Priority date: 2018-07-19
Filing date: 2018-07-19
Publication date: 2022-07-08
Anticipated expiration: 2038-07-19
Also published as: CN109144824A

Abstract

The invention discloses a running state display device of a double-path server node, comprising: the first bus of the first baseboard management controller is connected between the 80h port of the BIOS of the first server node and the bus switching circuit, and the first bus is used for transmitting first state information of the first server node; a second bus of the second baseboard management controller is connected between an 80h port of the BIOS of the second server node and the bus switching circuit, and the second bus is used for transmitting second state information of the second server node; the front-end interaction module comprises a selector switch and an indicating device; the bus switching circuit responds to a switching signal of the switch and sends the first state information or the second state information to the indicating device so as to display the running state of the first server node or the second server node. The technical scheme of the invention provides a man-machine interaction device for displaying the state information of double server nodes based on a baseboard management controller.

Description

Running state display device of double-path server node

Technical Field

The invention relates to the technical field of servers, in particular to an operating state display device of a double-path server node.

Background

With the rapid development of the fields of mass data storage, data mining, image and video intelligent analysis and the like, the market demand of the server is gradually expanding. Besides pursuing high-quality services providing efficient and accurate powerful data processing and storage for clients through upgrading of software and hardware of the server, server manufacturers need to pour more human-friendly elements in server products, such as providing friendly human-computer interaction interfaces.

The front panel of the conventional server, which is one of the human-computer interaction interfaces, is only to simply reserve a power key PWR _ BTN/reset key RST _ BTN and basic hardware interfaces such as an indicator light, an ID indicator light, a VGA (Video Graphics Array), and a USB. However, the obvious disadvantage of this scheme is that if software and hardware faults such as a hang machine occur during the starting or running process of the server, the problem cannot be quickly located through an 80h Port of a BIOS (Basic Input Output System).

In addition, in the design scheme of the front panel of the dual-server node, which is widely applied in the server market at present, basic interfaces of the two server nodes, such as PWR _ BTN, RST _ BTN, VGA, USB, and the like, are usually integrated on the same PCB substrate through hardware circuits. However, the main problem of the above solution is that 2 sets of hardware circuits including buttons, VGA, USB, etc. are required, and the limited front panel occupies more space, and the economic cost is relatively high. Moreover, only a VGA interface is provided, which causes certain trouble to the server debugging and operation and maintenance stages, and when software and hardware faults such as hang machine occur in the server starting and operation processes, the information can be simply analyzed through the VGA, the complexity of the bottom layer drive design needs to be increased, and the operation state of the server cannot be effectively monitored and timely fed back to the research, development and operation and maintenance engineers. Especially when the VGA black screen problem is met, the operation and maintenance engineer puts the tie under the policy.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a running state display device of a two-way server node, which is a front panel implementation scheme for decoding an 80h port code of a BIOS based on a BMC (baseboard management controller), and realizes a multiplexing technology of a BIOS80h port of the two-way server node.

The technical scheme of the invention is realized as follows:

according to an aspect of the present invention, there is provided an operation state display apparatus of a two-way server node, including: a switching module including a bus switching circuit; the first server node comprises a first substrate management controller, the second server node comprises a second substrate management controller, a first bus of the first substrate management controller is connected between an 80h port of the BIOS of the first server node and the bus switching circuit, and the first bus is used for transmitting first state information of the first server node; a second bus of the second baseboard management controller is connected between an 80h port of the BIOS of the second server node and the bus switching circuit, and the second bus is used for transmitting second state information of the second server node; the front-end interaction module comprises a selector switch and an indicating device;

the bus switching circuit responds to a switching signal of the switch and sends the first state information or the second state information to the indicating device so as to display the running state of the first server node or the second server node.

According to the embodiment of the invention, the first state information includes information obtained by decoding, by the first baseboard management controller, a monitoring signal output by an 80h port of the BIOS of the first server node; the second state information includes information obtained by decoding, by the second baseboard management controller, the monitoring signal output by the 80h port of the BIOS of the second server node.

According to an embodiment of the present invention, the first state information further includes information obtained by the first baseboard management controller decoding a monitoring signal output by a programmable device on the first server node motherboard; the second state information further includes information obtained by decoding, by the second baseboard management controller, a monitoring signal output by the programmable device on the second server node motherboard.

According to an embodiment of the present invention, the switching module further comprises: the USB switching circuit is connected to the first server node and the second server node; the USB switching circuit responds to a switching signal of the switch and interconnects the USB of the first server node or the USB of the second server node with the human-computer interaction equipment, and the human-computer interaction equipment comprises a mouse and a keyboard; the VGA switching circuit is connected to the first server node and the second server node; the VGA switching circuit responds to a switching signal of the switch and sends VGA information of the first server node or VGA information of the second server node to the indicating device for displaying.

According to an embodiment of the present invention, the front-end interaction module further includes: and the driving circuit is used for transmitting the first state information and the second state information to the indicating device.

According to an embodiment of the present invention, the front-end interaction module further includes: and the driving reset circuit is connected with the selector switch and responds to the switching signal to enable the driving circuit to clear the data cache.

According to the embodiment of the invention, the front-end interaction module further comprises a power key used for executing the on-off operation on the first server node or the second server node according to the switching signal.

According to an embodiment of the present invention, the front-end interaction module further includes a reset key, configured to perform a reset operation on the first server node or the second server node according to the switching signal.

Through the technical scheme, the invention provides a man-machine interaction design scheme of double server nodes for displaying the state information of a BIOS80h port based on BMC, the 80h port state information is displayed on an indicating device of a front panel, and the data interaction of 2 server nodes 80h ports is realized through a hardware switching circuit.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic diagram illustrating a connection between an operation status display device and a first server node and a second server node according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an operation state display device according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments that can be derived by one of ordinary skill in the art from the embodiments given herein are intended to be within the scope of the present invention.

Referring to fig. 1 and 2, the present invention provides an operation status display apparatus 30 for a two-way server node, wherein the operation status display apparatus 30 is connected to a first server node 10 and a second server node 20.

The operation state display device 30 includes: a switching module 32 including a bus switching circuit 324; the first server node 10 includes a first Baseboard Management Controller (BMC), the second server node 20 includes a second BMC, a first bus of the first BMC is connected between the 80h port of the BIOS of the first server node 10 and the bus switching circuit 324, and the first bus is used to transmit first state information of the first server node 10; the second bus of the second BMC is connected between the 80h port of the BIOS of the second server node 20 and the bus switching circuit 324, and the second bus is used for transmitting the second status information of the second server node 20. The front end interaction module 34 comprises a switch 341 and an indication device 342. The indicator 342 may be an indicator light or a nixie tube. The bus switching circuit 324 is configured to send the first status information or the second status information to the indication device 342 in response to the switching signal SW of the switch 341, so as to display the operation status of the first server node 10 or the second server node 20.

Based on the technical scheme, the invention provides a man-machine interaction (namely, a front panel) design scheme of double server nodes for displaying the state information of the BIOS80h port based on BMC, the 80h port state information is displayed on an indicating device 342 of the front panel, and the data interaction of 2 server nodes 80h ports is realized through a hardware switching circuit.

It should be noted that the operation state display device of the dual-server node provided by the present invention is a human-computer interaction device of the dual-server node, and in the following description, the operation state display device may be referred to as a front panel.

The first state information includes information obtained by decoding the monitoring signal output by the 80h port of the BIOS of the first server node 10 by the first BMC. The second status information includes information obtained by decoding the monitoring signal output from the 80h port of the BIOS of the second server node 20 by the second BMC.

In addition, the first status information may further include information obtained by decoding, by the first BMC, a monitoring signal output by the programmable device on the motherboard of the first server node 10. Correspondingly, the second status information further includes information obtained by decoding, by the second BMC, the monitoring signal output by the programmable device on the motherboard of the second server node 20. The programmable device can be a CPLD or ARM chip. That is to say, the first and second BMCs of the first and

second server nodes

10 and 20 are also responsible for performing software decoding on the received monitoring signal provided by the chip such as the onboard CPLD/ARM, so as to obtain the information monitored by the onboard CPLD/ARM on the server node motherboard. Specifically, the obtained information can be timely fed back to research, development and operation engineers by debugging the flashing frequency and high-low setting of the LED lamp or displaying special characters by a nixie tube.

As shown in fig. 2, the switching module 32 may further include a USB switching circuit 322 and a VGA switching circuit 321. The USB switching circuit 322 is connected to the first server node 10 and the second server node 20; the USB switching circuit 322 interconnects the USB of the first server node 10 or the USB of the second server node 20 with a human machine interface device, which may include a mouse and a keyboard, in response to the switching signal SW of the switch 341. A VGA switching circuit 321 connected to the first server node 10 and the second server node 20; the VGA switching circuit 321 responds to the switching signal SW of the switch 341 to transmit the VGA information of the first server node 10 or the VGA information of the second server node 20 to the indication device 342 for display. The front-end interaction module 34 may further include a VGA/USB circuit 346, which is configured to send the USB information and the VGA information to the indication device 342 for displaying.

The front-end interaction module 34 further includes: driver circuit 343, the first state information and the second state information are sent to indicator device 342 via driver circuit 343. Wherein, the front-end interaction module 34 further includes: and a driving reset circuit connected to the switch 341, and the driving reset circuit enables the driving circuit 343 to clear the data buffer in response to the switching signal SW.

The front-end interaction module 34 further includes a power button 344 for performing a power-on/off operation on the first server node 10 or the second server node 20 according to the switching signal SW. The front-end interaction module 34 further comprises a reset button 345 for performing a reset operation on the first server node 10 or the second server node 20 according to the switching signal SW. The signals from the power button 344 and the reset button 345 pass through the power/reset switching circuit 325, and the corresponding node is turned on/off and reset according to the switching signal SW of the switch 341.

An embodiment of the operation state display device of the two-way server node according to the present invention is described below with reference to fig. 1 and 2.

The server board node 10 and the server board node 20 are communicatively connected to the front panel 30. The PWR _ BTN circuit, the RST circuit, the VGA interface circuit, the USB circuit, and the I2C bus circuit on the 2

server motherboard nodes

10 and 20, wherein the I2C bus circuit is responsible for communication between the BMC and the indicating device 342(LED lamp or nixie tube) of the front panel 30, and feeds back the BIOS80h port code or system status information to the research and development or operation and maintenance engineer in time to monitor the system operating status in real time.

The front panel 30 includes a KVM circuit 321 (i.e. a switch module), and the KVM circuit 321 is used for switching between USB/VGA between different nodes. An I2C bus switching circuit 324, an 80h port driving circuit 343, a power button 344, a reset button 345, a switch 341, a USB/VGA interface, and an LED lamp or nixie tube.

Signals such as PWR, RST and I2C from the 2

nodes

10, 20 are interconnected with the front panel 30, and the gating of the 2

nodes

10, 20 is performed by switching the switch 341 on the front panel 30. For example, the switch SW to the left side, the gating signal controls the USB KVM circuit 322, the VGA KVM circuit 321, and the I2C switch circuit 324, so that the first node 10 is gated, and the hardware power-on/off and reset operations are performed by operating the power button 344 and the reset button 345 of the front panel 30. In addition, the power button 344 and the reset button 345 can be provided with LED indicator lamps to indicate the working state of the system. Meanwhile, the RST circuit interconnected with the switch 341 realizes the data cache clearing processing in the 80h port driving circuit 343 in a hardware reset mode, and avoids the mutual data coverage among 2 nodes. Conversely, when the switch 341 is toggled to the right, the second node 20 is gated.

In this embodiment, the BMC circuit in 2 nodes is responsible for performing software decoding on the received code of the BIOS80h port and the monitoring signal provided by chips such as an onboard CPLD/ARM, and the like, besides normal monitoring and remote management of the motherboard, and is further responsible for transmitting the decoded software to the 80h port driving circuit 343 through the I2C bus switching circuit 324 to drive the LED lamp to light up or the LED nixie tube to display, so as to provide a friendly man-machine interface and feed back the relevant information of the system to the research and development or operation and maintenance engineer in real time.

In summary, by means of the above technical solution of the present invention, the BMC decodes the 80h port code of the BIOS and the alarm information of the CPLD/ARM, and drives the LED lamp or the nixie tube through the driving circuit 343 to display in real time, thereby providing a good man-machine interface, and facilitating research, development, debugging, and operation and maintenance. The switch 341 can perform hardware reset on the 80h port driving circuit 343 in the switching process, thereby implementing the buffer emptying function of the driving circuit 343. Displaying the relevant information of the 80h port on the front panel is achieved. The switching switch 341 gates the VGA/USB, I2C and other circuits of 2 nodes, so that 2 nodes multiplex 1 set of front panel comprising a power supply key, a reset key, a VGA/USB circuit and an LED lamp or a nixie tube, and the design of the front panel is simplified.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the present invention, which is intended to cover any modifications, equivalents, improvements, etc. within the spirit and scope of the present invention.

Claims

1. An operation state display device of a two-way server node, comprising:

a switching module including a bus switching circuit; the first server node comprises a first baseboard management controller, the second server node comprises a second baseboard management controller, a first bus of the first baseboard management controller is connected between an 80h port of the BIOS of the first server node and the bus switching circuit, and the first bus is used for transmitting first state information of the first server node; a second bus of the second baseboard management controller is connected between an 80h port of the BIOS of the second server node and the bus switching circuit, and the second bus is used for transmitting second state information of the second server node;

the front-end interaction module comprises a selector switch and an indicating device;

wherein the bus switching circuit responds to a switching signal of the switch and sends the first state information or the second state information to the indicating device to display the running state of the first server node or the second server node,

the first state information comprises information obtained by decoding a monitoring signal output by an 80h port of a BIOS (basic input/output system) of a first server node by the first baseboard management controller; the second status information includes information obtained by the second baseboard management controller decoding a monitoring signal output by an 80h port of the BIOS of the second server node,

the first state information further includes information obtained by decoding, by the first baseboard management controller, a monitoring signal output by a programmable device on a first server node mainboard; the second state information further includes information obtained by decoding, by the second baseboard management controller, a monitoring signal output by a programmable device on the second server node motherboard,

and transmitting the first state information or the second state information to an 80h port driving circuit of the front-end interaction module through an I2C bus switching circuit of the switching module so as to drive an LED lamp to be lightened or an LED nixie tube to display.

2. The apparatus for displaying the operation status of a two-way server node according to claim 1, wherein the switching module further comprises:

a USB switching circuit connected to the first server node and the second server node; the USB switching circuit responds to a switching signal of the switch and interconnects the USB of the first server node or the USB of the second server node with a human-computer interaction device, and the human-computer interaction device comprises a mouse and a keyboard;

a VGA switching circuit connected to the first server node and the second server node; and the VGA switching circuit responds to the switching signal of the switch and sends the VGA information of the first server node or the VGA information of the second server node to the indicating device for displaying.

3. The apparatus for displaying the operating status of a two-way server node according to claim 1, wherein the front-end interaction module further comprises:

a drive circuit via which the first state information and the second state information are sent to the indication device.

4. The apparatus for displaying the operating status of a two-way server node according to claim 3, wherein the front-end interaction module further comprises:

and the driving reset circuit is connected with the selector switch and responds to the switching signal to enable the driving circuit to clear the data cache.

5. The apparatus for displaying the operating status of two-way server node according to claim 1, wherein the front-end interaction module further comprises a power button for performing a power-on/off operation on the first server node or the second server node according to the switching signal.

6. The apparatus for displaying the operating status of two-way server node according to claim 1, wherein the front-end interaction module further comprises a reset button for performing a reset operation on the first server node or the second server node according to the switching signal.