CN113760612A - Server debugging method - Google Patents

Abstract

A server debugging method is applied to a server system. The server system comprises a debugging control module with a detection button and a programmable logic device. The server debugging method comprises a debugging mode selection step of enabling the programmable logic device to generate a first detecting mode message when the detecting button is pressed for a first pressing time, enabling the programmable logic device to generate a second detecting mode message when the detecting button is pressed for a second pressing time, and an execution step of executing a power-on timing command after the programmable logic device generates the first detecting mode message and executing an operation command after the programmable logic device generates the second detecting mode message. The programmable logic device can generate and execute the power-on time sequence instruction or the operation instruction according to the time when the detection button is pressed, and the programmable logic device can execute the required detection mode instruction only by pressing the detection button, so that the time is saved and the efficiency is good.

Description

Server debugging method

Technical Field

The present invention relates to a testing method, and more particularly, to a server debugging method.

Background

In recent years, with the vigorous development of servers, the servers have been widely used in daily life and work. Generally, before the server leaves the factory, the server needs to go through a series of tests and verifications, such as testing whether the electronic devices (e.g., CPU, DIMM, or other ICs and hardware devices) inside the server are powered on normally (Power Good) and detecting the voltage value thereof during the Power-on process, so as to ensure the performance and quality of the server. However, in the test verification operation in the development stage, it is usually necessary to have a troublesome external test device to perform the test and to execute the test program command through the CPU, but since the CPU is expensive, the number of the CPUs for test is very limited in the server manufacturing industry, which is not enough to meet the test requirement of the large number of internal servers to be tested, and the embarrassment and inconvenience of the user due to the fact that the CPU is unavailable is often caused. Therefore, how to perform server detection efficiently and facilitate the user to grasp the test status is very demanding for the practitioner to study, investigate and improve.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a server debugging method which is time-saving and has good testing efficiency.

In order to solve the above technical problems, the server debugging method of the present invention is applied to a server system. The server system comprises a substrate management controller, a debugging control module connected with the substrate management controller, a programmable logic device linking the substrate management controller and the debugging control module, and a plurality of electronic devices. The debugging control module is provided with a light-emitting unit which is controlled by the substrate management controller to emit light and a detection button. The programmable logic device has an execution module and a standard data module. The server debugging method comprises a debugging mode selection step, an execution step connected with the debugging mode selection step, a judgment step connected with the execution step and a lighting step connected with the judgment step.

In the debugging mode selecting step, when the detection button of the debugging control module is pressed for a first pressing time, the programmable logic device is enabled to generate a first detection mode message, and when the detection button of the debugging control module is pressed for a second pressing time, the programmable logic device is enabled to generate a second detection mode message.

In the executing step, after the programmable logic device generates the first detection mode message, the executing module of the programmable logic device executes a power-on sequence instruction and controls to power on the electronic equipment, and after the programmable logic device generates the second detection mode message, the executing module of the programmable logic device executes an operation instruction and calculates the voltage value of the operation of the substrate management controller and the electronic equipment.

In the judging step, after the execution module of the programmable logic device executes the power-on sequence instruction and judges that a power supply normal message returned by all the electronic equipment is received, the execution module generates a continuous lighting message and transmits the continuous lighting message to the substrate management controller; when the execution module judges that the normal power supply message returned by all the electronic equipment is not received, the execution module generates a first warning light message and transmits the first warning light message to the substrate management controller, and when the programmable logic device finishes the operation instruction and calculates the voltage value of the operation of the substrate management controller and the electronic equipment and the execution module judges that the voltage value completely accords with the content of a voltage preset table of the standard data module, the execution module generates the continuous light-on message and transmits the continuous light-on message to the substrate management controller; when the execution module judges that the voltage values do not completely accord with the content of the voltage preset table, the execution module generates a second warning light message and transmits the second warning light message to the substrate management controller.

In the step of lighting, when the baseboard management controller receives the continuous lighting message, the lighting unit of the debugging control module is controlled to continuously light, when the baseboard management controller receives the first warning light message, the lighting unit of the debugging control module is controlled to send a first frequency flashing light, and when the baseboard management controller receives the second warning light message, the lighting unit of the debugging control module is controlled to send a second frequency flashing light.

Compared with the prior art, the invention has the advantages that the programmable logic device can generate the first detection mode message according to the time when the detection button is pressed and execute the power-on timing sequence command or generate the second detection mode message and execute the design of the operation command in the error detection mode selection step and the execution step, the programmable logic device can quickly execute the required detection mode only by pressing the detection button, the test efficiency is good, in addition, the application of the continuous light-on message, the first warning light message or the second warning light message is realized when the execution module of the programmable logic device generates the application of the continuous light-on message, the first warning light message or the second warning light message according to the judgment result in the judgment step, and in the light-on step, the substrate management controller controls the light-emitting unit of the error detection control module to continuously light on and emit the first frequency flashing light according to the received light-on message, or the second frequency flashing light is sent out, so that a user can know the test result through the light-on information sent out by the light-emitting unit, the time is effectively saved, and the detection efficiency is improved.

[ description of the drawings ]

Other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments with reference to the accompanying drawings, in which:

FIG. 1 is a block diagram illustrating an embodiment of a server debug method applied to a server system according to the present invention; and

FIG. 2 is a flowchart illustrating an embodiment of a server debug method according to the present invention.

[ detailed description ] embodiments

Before the present invention is described in detail, it should be noted that in the following description, similar components are denoted by the same reference numerals.

Referring to fig. 1, the server debugging method of the present invention is applied to a server system 1. The server system 1 includes a baseboard management controller 11, a debug control module 12 connected to the baseboard management controller 11, a programmable logic device (CPLD) 13 linking the baseboard management controller 11 and the debug control module 12, and a plurality of electronic devices (not shown). The debugging control module 12 has a light emitting unit 121 controlled by the bmc 11 to emit light, and a detection button 122. The programmable logic device 13 has an execution module 14 and a standard data module 15. In this embodiment, the electronic device (not shown) is an IC, a DIMM, or other hardware device, but not limited thereto. The server debugging method comprises a debugging mode selection step 3, an execution step 4 which is connected with the debugging mode selection step 3, a judgment step 5 which is connected with the execution step 4, and a lighting step 6 which is connected with the judgment step 5.

First, in the debug mode selecting step 3, when the detection button 122 of the debug control module 12 is pressed for a first pressing time, the programmable logic device 13 is enabled to generate a first detection mode message, when the detection button 122 of the debug control module 12 is pressed for a second pressing time, the programmable logic device 13 is enabled to generate a second detection mode message, and when the detection button 122 of the debug control module 12 is pressed for a third pressing time, the programmable logic device 13 is enabled to generate a third detection mode message. In this embodiment, the first pressing time is shorter than the second pressing time, and the second pressing time is shorter than the third pressing time, but not limited thereto. In addition, in the embodiment, when the detection button 122 is pressed for a time period longer than the first pressing time and shorter than the second pressing time, the programmable logic device 13 also generates the first detection mode message; when the detection button 122 is pressed for a time greater than the second pressing time and less than the third pressing time, the programmable logic device 13 also generates the second detection mode message; when the detection button 122 is pressed for a time longer than the third pressing time, the programmable logic device 13 also generates the third detection mode message; when, for example, the first pressing time is 3 seconds, the second pressing time is 8 seconds, and the third pressing time is 15 seconds, the programmable logic device 13 generates the first detection mode message when the detection button 122 is pressed for 3 seconds or the detection button 122 is pressed for more than 3 seconds and less than 8 seconds; the programmable logic 13 generates the second detection mode message when the detection button 122 is pressed for 8 seconds or the detection button 122 is pressed for more than 8 seconds and less than 15 seconds; the programmable logic 13 generates the third detection mode message when the detection button 122 is pressed for 15 seconds or more.

It should be noted that, in the present embodiment, the programmable logic device 13 further has a detection pin (not shown) linked to the debug control module 12. In the debug mode selecting step 3, when the detection button 122 of the debug control module 12 is pressed, the level of the detection pin of the programmable logic device 13 is lowered, and the programmable logic device 13 calculates the time when the detection pin is at the low level to calculate the time when the detection button 122 is pressed. When the programmable logic device 13 calculates the first pressing time, the first detection mode message is generated, when the programmable logic device 13 calculates the second pressing time, the second detection mode message is generated, and when the programmable logic device 13 calculates the third pressing time, the third detection mode message is generated. That is, when the level of the detection pin is pulled low and is at a low level, the programmable logic device 13 counts the time that the detection pin is at the low level through an internal counter to calculate the time that the detection button 122 is pressed.

Then, in the executing step 4, after the programmable logic device 13 generates the first detection mode message, the executing module 14 of the programmable logic device 13 executes a power-on sequence instruction and controls to power on the electronic device (not shown); when the programmable logic device 13 generates the second detection mode message, the execution module 14 of the programmable logic device 13 executes an operation instruction and calculates the voltage value of the operation of the bmc 11 and the electronic device; after the programmable logic device 13 generates the third detection mode message, the execution module 14 of the programmable logic device 13 executes a detection command and detects signal states of the bmc 11 and the electronic device. Briefly, in the error detection mode selecting step 3, the user can select the detection mode to be performed through the time when the detection button 122 is pressed, and the programmable logic device 13 generates the corresponding first detection mode message, the second detection mode message or the third detection mode message according to the time when the detection button 122 is pressed, and then, in the executing step 4, after the programmable logic device 13 generates the first detection mode message, the executing module 14 executes the power-on timing command and controls to power on the electronic device; when the programmable logic device 13 generates the second detection mode message, the execution module 14 executes the operation command and calculates the voltage value of the operations of the bmc 11 and the electronic device, and when the programmable logic device 13 generates the third detection mode message, the execution module 14 executes the detection command and detects the signal states of the bmc 11 and the electronic device. In this embodiment, the detecting button 122 is pressed at three different pressing times of the first, second and third pressing times to enable the programmable logic device 13 to generate the corresponding first, second and third detecting mode messages, and the executing module 14 to execute the power-on timing command, the operation command and the detecting command, but not limited thereto, a fourth pressing time can be designed according to actual test requirements, when the detecting button 122 is pressed at the fourth pressing time, the programmable logic device 13 generates a fourth detecting mode message, and the executing module 14 executes a skip test command, and when the executing module 14 executes the skip test command, a PFR test action is directly skipped to perform a subsequent more important test verification operation.

It should be noted that, in the embodiment, the programmable logic device 13 further has an Analog to digital Converter (ADC) module 16, and in the executing step 4, after the programmable logic device 13 generates the second detection mode message, the executing module 14 of the programmable logic device 13 executes the operation instruction and calculates the voltage value of the operations of the substrate management controller 11 and the electronic device through the ADC module 16. That is, when the execution module 14 executes the operation command, the voltage value of the bmc 11 and the electronic device are converted through the internal circuit of the adc module 16.

Then, in the determining step 5, after the execution module 14 of the programmable logic device 13 completes the execution of the power-on timing command, and determines that a power source normal message returned by each electronic device has been received, the execution module 14 generates a continuous lighting message and transmits the message to the substrate management controller 11; when the execution module 14 determines that the power supply normal message returned by all the electronic devices is not received, the execution module 14 generates a first warning light message and transmits the first warning light message to the substrate management controller 11. When the execution module 14 of the programmable logic device 13 finishes executing the operation instruction and calculates the voltage values of the operations of the baseboard management controller 11 and the electronic device, and the execution module 14 determines that all the voltage values conform to the content of a voltage preset table 151 of the standard data module 15, the execution module 14 generates the continuous lighting message and transmits the continuous lighting message to the baseboard management controller 11; when the execution module 14 determines that the voltage values do not all conform to the content of the voltage preset table 151, the execution module 14 generates a second warning light message and transmits the second warning light message to the bmc 11. When the execution module 14 of the programmable logic device 13 finishes executing the detection instruction and detects the signal states of the baseboard management controller 11 and the electronic device, and the execution module 14 determines that the signal states all conform to the content of a signal state preset table 152 of the standard data module 15, the execution module 14 generates the continuous lighting message and transmits the continuous lighting message to the baseboard management controller 11; when the execution module 14 determines that the signal states do not all conform to the content of the signal state default table 152, the execution module 14 generates a third warning light message and transmits the third warning light message to the bmc 11. In short, the execution module 14 of the programmable logic device 13 will further determine the power-on result of each electronic device after executing the power-on timing command, and the execution module 14 of the programmable logic device 13 will further determine the result of the voltage values of the baseboard management controller 11 and each electronic device after executing the operation command, or the execution module 14 of the programmable logic device 13 will further determine the result of the signal states of the baseboard management controller 11 and each electronic device after executing the detection command. It should be noted that, in the embodiment, the detection Button 122 is a system ID Button (Identification LED Button) type, and a function of performing a test operation is newly added under the existing ID Button architecture, and the design of executing the power-on timing command when the first detection mode message is generated and the power-on timing command is executed, executing the operation command when the second detection mode message is generated and the detection command when the third detection mode message is generated and the detection command is executed is performed by pressing the detection Button 122, and the execution module 14 of the programmable logic device 13 is a type of hardware logic circuit inside the programmable logic device 13 and is integrated with a program language to be executed, so as to execute the required test operation, and the test program command can be executed without specially connecting a test device or a CPU, thereby effectively solving the problem that the test cannot be performed because no CPU is available in the past, and greatly improving the test convenience and facilitating the user to perform the test, time and labor are saved, and the testing efficiency is effectively improved.

In more detail, after the execution module 14 of the programmable logic device 13 executes the Power-on timing command, under a normal condition, each electronic device will send back a corresponding Power Good message (Power Good) to the programmable logic device 13, so when the execution module 14 determines that all the Power Good messages sent back by each electronic device have been received, it represents that the electronic devices are powered on normally, and at this time, the execution module 14 generates the continuous lighting message and sends the message to the substrate management controller 11; however, when the execution module 14 determines that the normal Power messages returned by all the electronic devices are not received, it represents that at least one electronic device has a problem in the Power-on process and cannot return the corresponding Power Good message (Power Good) to the execution module 14 of the programmable logic device 13, and at this time, the execution module 14 generates the first warning light message and transmits the first warning light message to the substrate management controller 11.

When the execution module 14 of the programmable logic device 13 executes the operation instruction, the execution module 14 will calculate the voltage values of the operations of the substrate management controller 11 and each electronic device through the analog-to-digital conversion operation module 16(ADC), under normal conditions, each voltage value should conform to the corresponding content in the voltage preset table 151 of the standard data module 15, and when the execution module 14 determines that all the voltage values conform to the content in the voltage preset table 151 of the standard data module 15, the execution module 14 generates the continuous lighting message and transmits the continuous lighting message to the substrate management controller 11; when the execution module 14 determines that the voltage values do not all conform to the content of the voltage preset table 151, the voltage value representing the operation of at least one electronic device or the bmc 11 has a problem, and at this time, the plc 13 generates the second warning light message and transmits the second warning light message to the bmc 11. In this embodiment, the voltage default table 151 of the standard data module 15 has a plurality of voltage ranges respectively corresponding to the bmc 11 and the electronic devices. In the determining step 5, after the executing module 14 of the programmable logic device 13 executes the operation instruction and the analog-to-digital conversion operation module 16 calculates the voltage values of the operations of the baseboard management controller 11 and the electronic device, and the executing module 14 determines whether each voltage value is in the corresponding voltage range, when each voltage value is in the voltage range corresponding to the voltage preset table 151, the executing module 14 generates the continuous lighting message and transmits the continuous lighting message to the baseboard management controller 11; when the execution module 14 determines that any voltage value does not meet the voltage range corresponding to the voltage default table 151, the execution module 14 generates the second warning light message and transmits the second warning light message to the bmc 11. In addition, in the present embodiment, the electronic device is a DIMM or other IC, but not limited thereto, and may also be a hardware device such as a bus (e.g., I C, SMBus), so as to detect and determine whether the voltage value of the bus matches the voltage value between VIL and VIH.

After the execution module 14 of the programmable logic device 13 executes the detection instruction, the execution module 14 will detect the signal states of the substrate management controller 11 and the electronic device, under normal conditions, the signal states of the substrate management controller 11 and the electronic device both need to conform to the corresponding contents in the signal state preset table 152 of the standard data module 15, and when the execution module 14 determines that the signal states all conform to the contents of the signal state preset table 152 of the standard data module 15, the execution module 14 generates the continuous lighting message and transmits the continuous lighting message to the substrate management controller 11; when the execution module 14 determines that the signal states do not all conform to the content of the signal state default table 152, which indicates that there is a problem with the signal state of at least one electronic device or the baseboard management controller 11, at this time, the execution module 14 generates the third warning light message and transmits the third warning light message to the baseboard management controller 11. In this embodiment, in the executing step 4, the executing module 14 of the programmable logic device 13 executes the detecting instruction and detects a logic value combination corresponding to the signal states of the bmc 11 and the electronic devices, for example, the executing module 14 detects that the logic value combination corresponding to the signal state of the bmc 11 is (110) and the logic value combination corresponding to one of the electronic devices is (101), and in the determining step 5, the executing module 14 determines whether the logic value combination corresponding to each signal state meets the content of the signal state preset table 152 of the standard data module 15. In the embodiment, the signal status default table 152 is an HW strap table and records a plurality of default logic value combinations respectively corresponding to the signal statuses of the bmc 11 and the electronic device, but not limited thereto.

Finally, in the lighting step 6, when the bmc 11 receives the continuous lighting message, the lighting unit 121 of the debug control module 12 is controlled to continuously light, when the bmc 11 receives the first warning light message, the lighting unit 121 of the debug control module 12 is controlled to emit a first warning light, when the bmc 11 receives the second warning light message, the lighting unit 121 of the debug control module 12 is controlled to emit a second warning light, and when the bmc 11 receives the third warning light message, the lighting unit 121 of the debug control module 12 is controlled to emit a third warning light. In this embodiment, the first warning light is a first frequency flashing light, the second warning light is a second frequency flashing light, and the third warning light is a third frequency flashing light, but not limited thereto, and the first warning light, the second warning light and the third warning light may be different color signals or light-on warning types, as long as the first warning light, the second warning light and the third warning light are different from each other and can be distinguished. In addition, in this embodiment, the first frequency flashing light is a 2Hz flashing light, the second frequency flashing light is a 4Hz flashing light, and the third frequency flashing light is an 8Hz flashing light, but not limited thereto, the frequency flashing light corresponding to the substrate management controller 11 or each electronic device may also be designed according to actual requirements, for example: the baseboard management controller 11 will emit flashing lights that flash alternately at 2Hz and 8Hz, respectively, when the processing unit (not shown) is abnormal, will emit flashing lights that flash alternately at 4Hz and 8Hz, respectively.

By the error detection mode selecting step 3 and the executing step 4, the programmable logic device 13 can execute the power-on timing command when generating the first detection mode message according to the time when the detection button 122 is pressed, execute the design of the operation command when generating the second detection mode message or execute the design of the detection command when generating the third detection mode message, so long as the detection button 122 is pressed to enable the programmable logic device 13 to quickly execute the required detection mode, thereby saving time and labor and achieving good test efficiency, and in the judging step 5, when the execution module 14 of the programmable logic device 13 generates the application of the continuously lighting message, the first warning lamp message, the second warning lamp message or the third warning lamp message according to the judging result, and in the lighting step 66, the substrate management controller 11 controls the lighting unit 121 of the error detection control module 12 to continuously light according to the received lighting message, Or the first frequency flashing lamp, the second frequency flashing lamp or the third frequency flashing lamp is sent out, so that a user can conveniently know the test result through the lighting message sent out by the light-emitting unit 121, the time is effectively saved, and the detection efficiency is improved.

It should be noted that, in the embodiment, in the server system 1, the programmable logic device 13 is connected to the bmc 11 through an Integrated Circuit bus (I-C) (not shown) for data transmission, and in the determining step 5, after the execution module 14 of the programmable logic device 13 completes the execution of the power-on timing command and determines whether to receive the power-on normal message returned by the electronic device, the execution module 14 stores the determination result as a first determination message. After the execution module 14 of the programmable logic device 13 calculates the voltage value of the operations of the bmc 11 and the electronic device and the execution module 14 determines whether the voltage value matches the content of the preset voltage table 151, the execution module 14 stores the determination result as a second determination information. After the execution module 14 of the programmable logic device 13 detects the signal states of the baseboard management controller 11 and the electronic device and the execution module 14 determines whether the signal states conform to the content of the signal state preset table 152, the execution module 14 stores the determination result into a third determination information, and the execution module 14 of the programmable logic device 13 integrates the first determination information, the second determination information and the third determination information into a test result data table, and transmits the test result data table to the baseboard management controller 11 through the integrated circuit bus, and transmits the test result data table to a computer (not shown) connected to the baseboard management controller 11 for storage, so that a remote Console (Console) computer can obtain the test result data.

In summary, in the server debugging method of the present invention, by the debugging mode selecting step 3 and the executing step 4, the programmable logic device 13 can execute the power-on timing command and execute the operation command when generating the first detecting mode message and executing the power-on timing command or generating the second detecting mode message according to the time when the detecting button 122 is pressed, so that the programmable logic device 13 can quickly execute the required detecting mode by pressing the detecting button 122, which is very time-saving and labor-saving and improves the testing efficiency.

However, the above description is only an example of the present invention, and the scope of the present invention should not be limited thereby, and all the simple equivalent changes and modifications made according to the claims and the contents of the patent specification should be included in the scope of the present invention.

Claims (9)

1. A server debugging method is applied to a server system, the server system comprises a substrate management controller, a debugging control module connected with the substrate management controller, a programmable logic device linked with the substrate management controller and the debugging control module, and a plurality of electronic devices, the debugging control module is provided with a light-emitting unit controlled by the substrate management controller to emit light, and a detection button, the programmable logic device is provided with an execution module and a standard data module, and the server debugging method is characterized by comprising the following steps:

a debugging mode selecting step, when the detecting button of the debugging control module is pressed for a first pressing time, the programmable logic device is enabled to generate a first detecting mode message, and when the detecting button of the debugging control module is pressed for a second pressing time, the programmable logic device is enabled to generate a second detecting mode message;

an execution step, after the programmable logic device generates the first detection mode message, an execution module of the programmable logic device executes a power-on sequence instruction and controls to power on the electronic equipment, and after the programmable logic device generates the second detection mode message, the execution module of the programmable logic device executes an operation instruction and calculates the voltage value of the operation of the substrate management controller and the electronic equipment;

a judging step, when the execution module of the programmable logic device finishes the power-on sequence instruction and judges that a power supply normal message returned by all the electronic equipment is received, the execution module of the programmable logic device generates a continuous lighting message and transmits the continuous lighting message to the substrate management controller; when the execution module of the programmable logic device judges that the normal power supply message returned by all the electronic equipment is not received, the execution module of the programmable logic device generates a first warning light message and transmits the first warning light message to the substrate management controller, and when the execution module finishes executing the operation instruction and calculates the voltage value of the operation of the substrate management controller and the electronic equipment and judges that the voltage value completely accords with the content of a voltage preset table of the standard data module, the execution module generates the continuous light-on message and transmits the continuous light-on message to the substrate management controller; when the execution module judges that the voltage values do not completely accord with the content of the voltage preset table, the execution module generates a second warning light message and transmits the second warning light message to the substrate management controller; and

and a lamp lighting step, when the substrate management controller receives the continuous lamp lighting message, controlling the light-emitting unit of the debugging control module to continuously light, when the substrate management controller receives the first warning lamp message, controlling the light-emitting unit of the debugging control module to emit a first warning lamp, and when the substrate management controller receives the second warning lamp message, controlling the light-emitting unit of the debugging control module to emit a second warning lamp.

2. The server debugging method of claim 1, wherein the programmable logic device further comprises an analog-to-digital conversion module, and wherein in the executing step, after the programmable logic device generates the second detection mode message, the executing module of the programmable logic device executes the operation command and calculates the voltage values of the baseboard management controller and the electronic device through the analog-to-digital conversion module.

3. The server debugging method of claim 1, further comprising the step of causing the programmable logic device to generate a third detection mode message when the detection button of the debugging control module is pressed for a third pressing time, wherein the step of executing further comprises the step of executing an execution module of the programmable logic device to execute a detection command and detect signal states of the baseboard management controller and the electronic device after the programmable logic device generates the third detection mode message, and the step of determining further comprises the step of determining that the signal states all conform to contents of a signal state preset table of the standard data module when the execution module of the programmable logic device finishes executing the detection command and detects the signal states of the baseboard management controller and the electronic device, the execution module generates the continuous lighting message and transmits the message to the substrate management controller; when the execution module judges that the signal states do not completely accord with the content of the signal state preset table, the execution module generates a third warning lamp message and transmits the third warning lamp message to the substrate management controller.

4. The server debugging method of claim 3, wherein in the executing step, the executing module of the programmable logic device detects a logic value combination corresponding to the signal states of the BMC and each of the electronic devices, and in the determining step, the executing module determines whether the logic value combination corresponding to each of the signal states meets the content of the signal state default table of the standard data module.

5. The server debugging method of claim 3, wherein in the step of turning on the light, the first warning light is a first frequency flashing light, the second warning light is a second frequency flashing light, and the third warning light is a third frequency flashing light.

6. The server debugging method of claim 5, wherein the voltage preset table of the standard data module has a plurality of voltage ranges respectively corresponding to the baseboard management controller and the electronic device, and in the determining step, after the execution module of the programmable logic device executes the operation command and the analog-to-digital conversion operation module calculates the voltage values for the operation of the baseboard management controller and the electronic device, and the execution module determines whether each voltage value is within the voltage range corresponding thereto, when each voltage value is within the voltage range corresponding to the voltage preset table, the execution module generates the continuous lighting message and transmits the continuous lighting message to the baseboard management controller; when the execution module judges that any voltage value does not accord with the voltage range corresponding to the voltage preset table, the execution module generates the second warning light message and transmits the second warning light message to the substrate management controller.

7. The server debug method as claimed in claim 5, wherein the programmable logic device further has a detection pin linked to the debug control module, wherein in the debug mode selection step, when the detection button of the debug control module is pressed, the level of the detection pin of the programmable logic device is lowered, and the programmable logic device calculates the time when the detection pin is at the low level to calculate the time when the detection button is pressed, when the programmable logic device calculates the first pressing time, the first detection mode message is generated, when the programmable logic device calculates the second pressing time, the second detection mode message is generated, and when the programmable logic device calculates the third pressing time, the third detection mode message is generated.

8. The server debug method according to claim 7, wherein in the debug mode selection step, the first press time is shorter than the second press time, and the second press time is shorter than the third press time.

9. The server error detection method as claimed in claim 5, wherein in the server system, the plc is connected to the bmc through an ic bus for data transmission, and in the determining step, after the execution module of the plc completes the power-on timing command and determines whether to receive the normal power message returned by the electronic device, the execution module stores the determination result as a first determination message, after the execution module calculates the voltage value of the bmc and the electronic device and determines whether the voltage value matches the content of the preset voltage table, the execution module stores the determination result as a second determination message, and after the execution module detects the signal status of the bmc and the electronic device and determines whether the signal status matches the content of the preset signal status table After that, the execution module stores the judgment result into a third judgment message, and the execution module integrates the first judgment message, the second judgment message and the third judgment message into a test result data table, and transmits the test result data table to the substrate management controller through the integrated circuit bus, and transmits the test result data table to a computer connected with the substrate management controller for storage.

Images