JP2020119173A - Information processing device, control method for information processing device, and control program for information processing device - Google Patents

Abstract

To embody continued operation of an information processing device in a simplified configuration, even when a failure occurs in an external device performing operation status management and power supply control to the information processing device.SOLUTION: Provided is an information processing device 30, in which an external device 40 is an execution subject for executing operation status management 41 and power supply control 42, and that is able to execute user applications, comprising: a detection section 31 for detecting a failure 43 occurred in the external device 40 by accessing to the external device 40; and an execution section 32 for, when the failure 43 is detected, executing the operation status management 41 and the power supply control 42 on behalf of the external device 40.SELECTED DRAWING: Figure 3

Description

The present invention relates to a technique for managing an operating state of an information processing device and controlling a power supply.

2. Description of the Related Art In recent information processing apparatuses, various technologies related to power supply control are used in order to realize power saving and to appropriately cope with an abnormality in an operating state.

As a technique related to such a technique, Patent Document 1 discloses a computer system in which a power management function is incorporated in an OS (Operating System). This system is provided with a register in which the OS sets a sleep state instruction in order to shift the system to a sleep state. Then, this system sets the register to a value indicating the sleep state, and then controls the system to be in the sleep state in the system management mode of the CPU (Central Processing Unit).

Further, Patent Document 2 discloses a computer system including a power supply device that supplies power to the system, and a power supply control unit that controls the entire power supply of the system by a program and turns on/off the power supply. ing. This system detects an abnormality of the power supply control means and issues a signal instructing the processing of turning off the power supply. Then, this system receives the signal and performs a power-off process for the power supply device.

JP, 11-085335, A JP 2002-318642 A

"UM10204 I2C-bus specification and user manual", [Online], [Search on January 15, 2019], Internet <URL: https://www.nxp.com/docs/en/user-guide/UM10204.pdf > "Intelligent Platform Management Interface Specification", [Online], [January 15, 2019 Search], Internet <URL: https://www.intel.com/content/www/us/en/servers/ipmi/ipmi- intelligent-platform-mgt-interface-spec-2nd-gen-v2-0-spec-update.html>

A large-scale information processing device such as a server device includes a dedicated system management device such as a BMC (Baseboard Management Controller). Then, the BMC monitors the operating state of the information processing apparatus and controls the power supply according to the monitoring result. Such an information processing apparatus is required to have a configuration (technology) that enables the operation of the information processing apparatus to continue even if a failure occurs in the BMC.

As an example of such a configuration, a configuration in which another system management device is provided outside the information processing device, a configuration in which the BMC is duplicated, or a configuration in which the processor and the like included in the BMC are duplicated can be considered. However, such a configuration has a problem that the cost increases as the hardware increases. That is, it is an object to realize a simple configuration so that the operation of the information processing device can be continued even if a system management device such as a BMC fails. Patent Documents 1 and 2 do not mention such a problem. A main object of the present invention is to provide an information processing device and the like that solve this problem.

An information processing apparatus according to an aspect of the present invention is an information processing apparatus that is an execution target in which an external apparatus executes operating state management and power control, and is capable of executing a user application. By performing a detecting means for detecting a failure occurring in the external device, and an executing means for executing the management of the operating state and the power supply control in place of the external device when the failure is detected. And

In another aspect of achieving the above object, in a method of controlling an information processing device according to an aspect of the present invention, an external device is an execution target for executing operating state management and power control, and is capable of executing a user application. By accessing the external device by the information processing device, a failure occurring in the external device is detected, and when the failure is detected, the operating state management and the operation are performed on behalf of the external device. Execute power control.

Further, in a further aspect of achieving the above object, a control program of an information processing apparatus according to an aspect of the present invention is an execution target for an external apparatus to perform operation state management and power control, and executes a user application. A detection process for detecting a failure that has occurred in the external device by accessing the external device to a possible information processing device, and when the failure is detected, the operation is performed on behalf of the external device. Execution processing for executing the state management and the power supply control is executed.

Furthermore, the present invention can also be realized by a computer-readable, non-volatile recording medium in which a control program (computer program) for the information processing apparatus is stored.

According to the present invention, even if a failure occurs in an external device that manages the operating state of the information processing device and controls the power supply, the operation of the information processing device can be continued with a simple configuration. Realize.

It is a block diagram which shows the structure of the server apparatus 1 which concerns on the 1st Embodiment of this invention. It is a flow chart which shows operation of main part system device 10 concerning a 1st embodiment of the invention in this application. It is a block diagram which shows the structure of the information processing apparatus 30 which concerns on the 2nd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<First Embodiment>
FIG. 1 is a block diagram showing the configuration of a server device 1 according to the first embodiment of the present invention. The server device 1 roughly includes a main body device 10 (information processing device) and a BMC 20 (external device). The system device 10 is an information processing device having a function of providing a service to a user by executing an OS 123 described below and executing a user application 124 in an environment in which the OS 123 is executed. The BMC 20 is a system management device that manages the operating state of the main system device 10 and controls the power supply.

The system device 10 includes one or more CPUs 11, memories 12, I/O (Input/Output) bridges 13, one or more I/O devices 14, voltage monitoring devices 151, temperature monitoring devices 152, power supply control devices 153, and The switching unit 16 is provided.

The I/O device 14 is, for example, an interface card or the like that controls the input/output of information between the peripheral device (not shown) such as a storage device, a keyboard, a mouse, and a monitor and the main device 10.

The I/O bridge 13 has a function of controlling communication performed by the CPU 11 with respect to the memory 12, the I/O device 14, the switching unit 16, and the BMC 20 (input/output control function regarding the CPU 11).

The CPU 11, the memory 12, the I/O device 14, the voltage monitoring device 151, the temperature monitoring device 152, and the power supply control device 153 are communicably connected via the interface 102. As the interface 102, for example, an I2C (Inter-Integrated Circuit) (registered trademark) bus, which is a standard interface shown in Non-Patent Document 1, can be used.

Here, the operation of the BMC 20 when the BMC 20 is operating normally will be described.

The BMC 20 can communicate with the voltage monitoring device 151, the temperature monitoring device 152, and the power supply control device 153 in the main system device 10 via the interface 103 connected to the interface 102 by the switching unit 16 described later. As the interface 103, for example, the above-mentioned I2C bus or the like can be used.

The voltage monitoring device 151 is a device (sensor) capable of measuring (monitoring) the power supply voltage at a predetermined location in the main body system device 10, and transmits the measurement result of the power supply voltage to the BMC 20. The temperature monitoring device 152 is a device (sensor) capable of measuring (monitoring) the temperature of a predetermined location in the main body system device 10, and transmits the temperature measurement result to the BMC 20. The power supply control device 153 is a device that controls ON/OFF of the power supply of the main body device 10.

The BMC 20 controls the power supply to the main body system device 10 via the power supply control device 153 according to the measurement result of the power supply voltage received from the voltage monitoring device 151 and the measurement result of the temperature received from the temperature monitoring device 152. ..

The BMC 20, for example, turns off the power of the main system device 10 when the measurement result of the power supply voltage or the measurement result of the temperature indicates an abnormality (exceeds the reference value).

The memory 12 stores a BIOS (Basic Input Output System) 120, an OS 123, a user application 124, and a failure flag 125. The memory 12 includes a main memory that stores the OS 123 and the user application 124, a non-volatile memory that stores the BIOS 120, and the like. As the OS 123, for example, Unix (registered trademark), Linux (registered trademark), Windows (registered trademark) and the like are generally known.

The BIOS 120 is firmware (software) that is executed by at least one of the CPUs 11. When the main system device 10 is started, the BIOS 120 performs initial settings regarding the operating environment of the main system device 10 and executes a POST (Power On Self Test). To control. The BIOS 120 also has a function of controlling input/output of information between hardware such as the CPU 11 included in the main body system device 10 and the OS 123.

Next, it is confirmed whether or not a failure has occurred in the BMC 20, and the operation of the main system device 10 when the failure has occurred in the BMC 20 will be described.

When a failure occurs in the BMC 20, the main body device 10 according to the present embodiment substitutes the above-described operation of the BMC 20 by causing the CPU 11 to execute the BIOS 120. The function of detecting a failure that has occurred in the BMC 20 and substituting the operation of the BMC 20 when the failure occurs is realized by the detection unit 121 and the execution unit 122 included in the BIOS 120. That is, the detection unit 121 and the execution unit 122 are functions realized by the CPU 11 executing the BIOS 120 (processing executed by the CPU 11). Then, in the following description of the present embodiment, for convenience of description, the detection unit 121 and the execution unit 122 will be described as the execution subjects of each operation.

In a state where the system device 10 is normally operated, the CPU 11 executes the OS 123 and the user application 124 in the environment in which the OS 123 is executed. Then, the CPU 11 executes the BIOS 120 triggered by the input of an interrupt signal from the outside at a predetermined timing (eg, periodically).

This interrupt signal is generated by the timer 130 (time measuring unit) provided in the I/O bridge 13. The timer 130 counts down after setting a predetermined initial value, and when the value becomes “0”, inputs an interrupt signal to the CPU 11 and resets the initial value. The timer 130 repeatedly executes such an operation. That is, the timer 130 repeatedly executes the activation of the detection unit 121 at a predetermined timing by generating an interrupt signal at a predetermined timing.

The detection unit 121 detects a failure that has occurred in the BMC 20 by accessing the BMC 20 via the interface 101 that communicatively connects the I/O bridge 13 and the BMC 20.

As the interface 101, for example, IPMI (Intelligent Platform Management Interface) (registered trademark), which is a standard interface shown in Non-Patent Document 2, can be used. More specifically, the interface 101 includes KCS (Keyboard Controller Style), SMIC (System Management Interface Chip), BT (Block Transfer), and SSIF (System management bus System Interface), which are defined in the IPMI specifications, for example. Either can be used.

The detection unit 121 issues, for example, a “Get Device ID” command to the BMC 20. The “Get Device ID” command is a command expected to be returned from the BMC 20 when the BMC 20 is operating normally, and is a command specified in the IPMI specifications. Therefore, the detection unit 121 detects a failure of the BMC 20 when the BMC 20 does not receive a reply to the issued “Get Device ID” command.

When detecting the failure of the BMC 20, the detection unit 121 sets the failure flag 125 stored in the memory 12 to “1”. That is, the failure flag 125 is a flag indicating whether or not a failure has occurred in the BMC 20. If the detection unit 121 has already detected the failure of the BMC 20 by referring to the failure flag 125 before issuing the above-mentioned “Get Device ID” command to the BMC 20, then the “Get Device ID” is detected. It is possible to omit issuing the command.

When the detecting unit 121 detects a failure that has occurred in the BMC 20, the executing unit 122 executes the above-described operation state management and power supply control for the main body system device 10, instead of the BMC 20. That is, the execution unit 122 includes the program code that enables the management of the operating state of the main body system device 10 performed by the BMC 20 and the power supply control as a substitute.

The execution unit 122 controls the switching unit 16 by inputting the switching signal 105 to the switching unit 16 via the I/O bridge 13 when performing the management of the operating state and the power supply control for the main body system device 10 on behalf of the main body device 10. To do. The switching unit 16 has a function of switching the interface connected to the interface 102 from the interface 103 to the interface 104 in response to the input of the switching signal 105. However, the switching unit 16 maintains the state in which the interface 102 and the interface 103 are connected until the failure of the BMC 20 is detected after the operation of the server device 1 is started. Further, when the failure flag 125 is already set to "1", the switching unit 16 has already performed the above-described switching operation, and thus the execution unit 122 can omit the above-described control of the switching unit 16. ..

The execution unit 122 communicates with the voltage monitoring device 151, the temperature monitoring device 152, and the power supply control device 153 via the interface 104 connected to the interface 102 by the switching unit 16. As the interface 104, the above-described I2C bus or the like can be used similarly to the interfaces 102 and 103.

The executing unit 122 replaces the BMC 20 with the main body system via the power supply control device 153 according to the measurement result of the power supply voltage received from the voltage monitoring device 151 and the measurement result of the temperature received from the temperature monitoring device 152. Power supply control for the device 10 is performed.

For example, when the measurement result of the power supply voltage or the measurement result of the temperature indicates abnormality (exceeds the reference value), the execution unit 122 turns off the power of the main body system device 10 instead of the BMC 20.

Next, the operation (processing) of the main body system device 10 according to the present embodiment will be described in detail with reference to the flowchart in FIG.

The timer 130 in the I/O bridge 13 counts down (step S101). When the value of the timer 130 is not "0" (No in step S102), the process returns to step S101. When the value of the timer 130 is "0" (Yes in step S102), the timer 130 inputs an interrupt signal to the CPU 11 and resets the initial value of the timer 130 to start the countdown (step S103). ..

The CPU 11 receives the interrupt from the timer 130 and starts executing the BIOS 120 (step S104). The detection unit 121 included in the BIOS 120 confirms the failure flag 125 (step S105).

When the value of the failure flag 125 is "1" (Yes in step S106), the process proceeds to step S111. When the value of the failure flag 125 is not "1" (that is, "0") (No in step S106), the detection unit 121 issues a "Get Device ID" command to the BMC 20 (step S107).

When the reply to the "Get Device ID" command is received from the BMC 20 (Yes in step S108), the process returns to step S101. When the reply to the “Get Device ID” command is not received from the BMC 20 (No in step S108), the detection unit 121 sets “1” in the failure flag 125 (step S109).

The execution unit 122 switches the interface connected to the interface 102 from the interface 103 to the interface 104 by controlling the switching unit 16 (step S110). The execution unit 122 acquires the measurement result regarding the voltage and the temperature from the voltage monitoring device 151 and the temperature monitoring device 152 via the interface 104 and the interface 102 (step S111).

When the obtained measurement result indicates normality (is within the reference value) (No in step S112), the process returns to step S101. When the obtained measurement result indicates abnormality (exceeds the reference value) (Yes in step S112), the execution unit 122 controls the power supply of the main body system device 10 according to the content of the abnormality (step S113), and executes the process. Returns to step S101.

The main body system device 10 (information processing device) according to the present embodiment operates the information processing device even when a failure occurs in the system management device that manages the operating state of the information processing device and controls the power supply. It is possible to realize that it can be continued with a simple configuration. The reason is that, when a failure occurs in the BMC 20, the main system device 10 that executes the OS 123 and the user application 124 executes the management of the operating state and the power supply control for itself, instead of the BMC 20.

The effects achieved by the main body system device 10 according to the present embodiment will be described in detail below.

A large-scale information processing device such as a server device includes a dedicated system management device such as a BMC. Then, the BMC monitors the operating state of the information processing apparatus and controls the power supply according to the monitoring result. In such an information processing apparatus, in order to allow the operation of the information processing apparatus to continue even if a failure occurs in the BMC, for example, a configuration in which another system management apparatus is provided outside the information processing apparatus Alternatively, a configuration in which the BMC is duplicated or a configuration in which the processor and the like included in the BMC are duplicated may be used. However, such a configuration has a problem that the cost increases as the hardware increases. That is, it is an object to realize a simple configuration so that the operation of the information processing device can be continued even if a system management device such as a BMC fails.

With respect to such a problem, the main body system device 10 (information processing device) according to the present embodiment includes a detection unit 121 and an execution unit 122, and operates as described above with reference to FIGS. 1 and 2, for example. .. That is, the main body system device 10 is an execution target for the BMC 20 (external device) to manage the operating state and control the power supply, and is an information processing device capable of executing the user application 124. The detection unit 121 detects a failure that has occurred in the BMC 20 by accessing the BMC 20. Then, when the failure is detected, the execution unit 122 executes the management of the operating state and the power supply control instead of the BMC 20.

That is, in the main body device 10 according to the present embodiment, the device itself can manage the operating state and control the power supply in place of the BMC 20, so that, for example, the BMC 20 is duplicated or the BMC 20 is made highly functional ( It is not necessary to duplicate the processor or the like included in the BMC 20). As a result, the main body system device 10 according to the present embodiment is capable of continuing the operation of the self-device even if a failure occurs in the BMC 20 that manages the operating state of the self-device and controls the power supply. Can be realized with a simple configuration.

Further, the switching unit 16 according to the present embodiment includes interfaces 102 and 103 (first interface) that communicatively connect the BMC 20 and a device group (voltage monitoring device 151, temperature monitoring device 152, power supply control device 153). The switching between the execution unit 122 and the interfaces 102 and 104 (second interface) that communicatively connect the device group is executed under the control of the execution unit 122. The interfaces 102 to 104 can adopt the I2C bus which is a standard interface. Therefore, the main body system device 10 according to the present embodiment can easily realize the above-described function of substituting the operation of the BMC 20.

Further, the detection unit 121 according to the present embodiment issues a “Get Device ID” command defined in the IPMI specifications to the BMC 20 via the interface 101 that conforms to the IPMI, which is a standard interface, thereby causing a failure in the BMC 20. To detect. Therefore, the main body device 10 according to the present embodiment can easily realize the function of detecting a failure in the BMC 20.

Further, the devices that measure the operating state of the main body device 10 included in the main body device 10 according to the present embodiment are not limited to the voltage monitoring device 151 and the temperature monitoring device 152. The system device 10 may include a device capable of measuring a state other than voltage or temperature (for example, current, vibration due to an earthquake, etc.) that affects power supply control.

In addition, the timer 130 (timer unit) according to the present embodiment generates an interrupt signal that activates the detection unit 121 at a predetermined timing (eg, periodically), and the detection unit 121 uses the interrupt signal as a trigger. Check to see if any failures have occurred. As a result, the main body system device 10 according to the present embodiment can reliably substitute the operation performed by the BMC 20 even while the OS 123 and the user application 124 are being executed.

In addition, as a method of supplying the BIOS 120 that realizes the detection unit 121 and the execution unit 122 according to the present embodiment to the main system device 10, a general procedure can be adopted at present. Examples of the procedure include a method of installing in the apparatus via various recording media such as a CD-ROM (Compact Disc Read Only Memory) and a method of downloading from the outside via a communication line such as the Internet. .. In such a case, the invention of the present application can be considered to be configured by the code configuring the computer program or the recording medium storing the code.

Further, the configuration that realizes the detection unit 121 and the execution unit 122 according to the present embodiment is not limited to the BIOS 120 executed by the CPU 11. The detection unit 121 and the execution unit 122 may be realized by software executed by the CPU 11 other than the BIOS 120, for example. Alternatively, the detection unit 121 and the execution unit 122 may be incorporated in a virtualized main body system device.

<Second Embodiment>
FIG. 3 is a block diagram showing the configuration of the information processing device 30 according to the second embodiment of the present invention.

The information processing device 30 is an execution target for the external device 40 to execute the operation state management 41 and the power supply control 42, and is an information processing device capable of executing a user application.

The information processing device 30 includes a detection unit 31 and an execution unit 32.

The detection unit 31 detects the failure 43 occurring in the external device 40 by accessing the external device 40.

When the failure 43 is detected, the execution unit 32 executes the operating state management 41 and the power supply control 42 instead of the external device 40.

The information processing device 30 according to the present embodiment enables the operation of the information processing device to be continued even if an external device that manages the operating state of the information processing device and controls the power supply fails. This can be realized with a simple configuration. The reason is that, when a failure occurs in the external device 40, the information processing device 30 that executes the user application executes, in place of the external device 40, management 41 of the operating state regarding the information processing device 30 and power control 42. Because.

The present invention has been described above with the above-described embodiment as an exemplary example. However, the present invention is not limited to the above embodiment. That is, the present invention can apply various modes that can be understood by those skilled in the art within the scope of the present invention.

1 server device 10 main system device 11 CPU
12 memory 120 BIOS
121 Detection Unit 122 Execution Unit 123 OS
124 User Application 125 Failure Flag 13 I/O Bridge 130 Timer 14 I/O Device 151 Voltage Monitoring Device 152 Temperature Monitoring Device 153 Power Supply Control Device 16 Switching Unit 101 Interface 102 Interface 103 Interface 104 Interface 105 Switching Signal 20 BMC
30 Information Processing Device 31 Detection Unit 32 Execution Unit 40 External Device 41 Management of Operating State 42 Power Control 43 Failure

Claims (10)

An external device is an information processing device that is an execution target that executes operating state management and power control, and is capable of executing a user application,
Detecting means for detecting a failure occurring in the external device by accessing the external device;
Executing means for executing the management of the operating state and the power control on behalf of the external device when the failure is detected;
An information processing apparatus including. A first interface that communicatively connects the external device to a device that measures the operating state and a device that controls the power source; a device that measures the execution unit and the operating state and a device that controls the power source; Further comprising a switching means for switching the connection state of the second interface for communicatively connecting
The execution unit controls the switching unit to switch the connection state from the first interface to the second interface when the failure is detected.
The information processing apparatus according to claim 1. Further comprising a timing means having a timing function,
The detection means confirms whether or not the failure has occurred by accessing the external device at a predetermined timing indicated by the timing means.
The information processing device according to claim 1. The time measuring means generates an interrupt signal for activating the detecting means at the predetermined timing.
The information processing device according to claim 3. The detection means issues a command expected to be returned from the external device to the external device when the external device is operating normally, and then does not receive a reply from the external device to the command. In case of detecting the failure,
The information processing apparatus according to any one of claims 1 to 4. The detection means issues the command to the external device via an interface compliant with IPMI (Intelligent Platform Management Interface),
The information processing device according to claim 5. The first and second interfaces are based on an I2C (Inter-Integrated Circuit) bus,
The information processing apparatus according to claim 2. The external device is an execution target for executing the operation state management and the power control, and by the information processing device capable of executing the user application,
By accessing the external device, a failure occurring in the external device is detected,
Executing the management of the operating state and the power control on behalf of the external device when the failure is detected,
Control method of information processing apparatus. An external device is an execution target that executes operating state management and power control, and an information processing device that can execute a user application,
By performing a access to the external device, a detection process for detecting a failure occurring in the external device,
An execution process for executing the management of the operating state and the power control on behalf of the external device when the failure is detected;
A control program of an information processing device for executing the. The detection process and the execution process are realized by a BIOS (Basic Input Output System),
The control program of the information processing apparatus according to claim 9.

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