JP2014067197A - Blade server and control system of blade server - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption during standby time in a blade server.SOLUTION: A blade server includes: a plurality of server blades; BMCs (Base Management Controllers) that are mounted on the server blades; a CMM (Chassis Management Module) that controls the BMCs; a standby voltage supply line that supplies a standby voltage to the BMCs; and switches that are provided between the BMCs and the standby voltage supply line.

Description

  The present invention relates to a blade server, and more particularly to power control of a blade server.

  In recent years, the use of blade server systems has become popular. There are various merits of using a blade server system, but power saving is one of the important merits. One of the reasons that power saving is possible is that a power source and a cooling fan can be shared by a plurality of modules. There have also been many attempts to further reduce power consumption by controlling the operation of the cooling fan for each location or putting unused modules into sleep mode to dynamically manage the entire system.

  Patent Document 1 discloses such a power saving technique. FIG. 6 is a block diagram showing a blade server system 100 of this technology. The CPU blade 110, the management server 120, and the client 130 are connected by an IP network 140, respectively. The individual blades are referred to as CPU blades 110 so as not to confuse the individual blades with the system.

  The blade server system 100, the CPU blade 110, the management server 120, and the client 130 are computers, each having an information processing function, a storage function, and a communication function. The blade server system 100 has a plurality of CPU blades 110. In the example of the figure, the case of eight is shown.

  Each CPU blade 110 includes a BMC 111 (Baseboard Management Controller) and a NIC 112 (Network Interface Card). The BMC 111 performs on / off control of the CPU blade 110, collection of event logs, communication with the outside when the main power is off, and the like.

  The NIC 112 is an expansion card for connecting the CPU blade 110 to the IP network 140.

  A power supply PSU 150 (Power Supply Unit) generates a main voltage from the commercial power supply 151 and supplies the main voltage to the CPU blade 110 through the main voltage supply line 152. The PSU 150 generates a standby voltage and supplies the standby voltage to the BMC 111 and the NIC 112 through the standby voltage supply line 153. Here, a standby voltage is always supplied to the BMC 111 and the NIC 112, and communication via the IP network 140 is possible even when the CPU blade 110 is off.

  FIG. 6 is a flowchart showing the operation of the system in this prior art. A processing request from the client 130 is executed by the following process.

  1) First, authentication information and a processing request are transmitted from the client 130 to the management server 120. 2) Next, the management server 120 receives the processing request. 3) Next, the management server 120 authenticates the client 130. 4) When the authentication is successful, a power-on request is transmitted to the corresponding CPU blade 110. If authentication fails, error information is transmitted and the startup is terminated. 5) Next, the BMC 111 of the corresponding CPU blade 110 starts up the main power supply and starts up the CPU blade 110. If the startup fails, retry. 6) Next, the startup success information is transmitted to the client 130. 7) Next, the process is executed. 8) When the processing is completed, the BMC 111 lowers the CPU blade 110 and lowers the main power supply.

  When the operation as described above is performed, the main voltage is supplied to the CPU blade 110 only while the processing request from the client 130 is being executed. Therefore, power consumption is significantly larger than when all the blades are always activated. Can be reduced.

JP 2008-186238 A

  However, the prior art has a problem that power consumption during standby increases as the number of CPU blades 110 increases. This is because the standby voltage is always supplied to all BMCs 111 and NICs 112. In recent years, in order to realize power saving in a cloud system or the like, it has become common to perform control to turn off the power of the CPU blade 110 when it is quiet, such as at night. However, it has been considered that standby power for controlling the hardware when the main unit is turned off cannot be turned off.

  For this reason, even if the power consumption of each BMC 111 and NIC 112 is small, the total sum increases as the number of CPU blades 110 increases. As a result, it was necessary to prepare a large-capacity power source.

  The present invention has been made in view of the above problems, and an object thereof is to provide means for reducing power consumption during standby.

  In order to achieve the above object, in the present invention, a plurality of server blades, a BMC (Base Management Controller) mounted on the server blade, a CMM (Chassis Management Module) for controlling the BMC, and a standby voltage to the BMC. And a switch provided between the BMC and the standby voltage supply line.

  The effect of the present invention is that power consumption during standby can be reduced.

It is a block diagram which shows 1st Embodiment. It is a flowchart which shows an example of operation | movement of 1st Embodiment. It is a flowchart which shows the 2nd example of operation | movement of 1st Embodiment. It is a flowchart which shows the 3rd example of operation | movement of 1st Embodiment. It is a flowchart which shows operation | movement of 3rd Embodiment. It is a block diagram which shows a prior art. It is a flowchart which shows operation | movement of a prior art.

Next, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram showing a blade server system 1 in the first embodiment of the present invention. The blade server system 1 includes a chassis 20 on which a CPU blade 10 is mounted, a CMM 30 (Chassis Management Module), a management server 40, a management LAN 50, an IP network 60, and a PSU 70 that is a power source. FIG. 1 shows an example in which eight CPU blades 10 (1)-(8) are mounted on the chassis 20.

  The CPU blade 10 is a computer and includes components such as a CPU, a memory, and a hard disk and a communication function. Further, the CPU blade 10 includes a BMC 11 (Base Management Controller) for managing itself and a NIC 12 (Network Interface Card) that is an interface with the IP network 50. The BMC 11 is connected to the management LAN 50, and the NIC 12 is connected to the IP network. The CMM 30 has a power on / off request function for each CPU blade 10, a function for monitoring an inquiry from the management server to the CPU blade 10, and a power control function for the BMC 11. Further, the CMM 30 holds information regarding the addresses and states of the CPU blade 10 and the BMC 11. One CMM 14 may be provided for the chassis 20, but a plurality of CMMs 14 may be provided to provide redundancy.

  The PSU 70 is supplied with the commercial power supply 71 and generates a main voltage and a standby voltage. The main voltage is supplied to each CPU blade 10 through the main voltage supply line 72, and the standby voltage is supplied to the CMM 30, BMC 11, and NIC 12 through the standby voltage supply line 73, respectively. Note that the wiring for supplying the standby voltage to the NIC 12 is not shown in order to avoid making the figure complicated. The PSU 70 is often configured with a plurality of units in order to provide redundancy, but in this figure, it is described as one PSU as a logical power supply apparatus.

  The BMC 11 performs on / off control of the CPU blade 10, monitoring of hardware such as a cooling fan, collection of event logs, communication with the outside when the CPU blade 10 is off, and the like. The standby voltage is supplied from the standby voltage supply line 73 to the BMC 11.

  As a feature of the present embodiment, a standby power control switch 13 is provided between the BMC 11 and the standby voltage supply line 73. The standby power control switch 13 is turned on / off by the CMM 30. The standby power control switch 13 can be formed by a known circuit using a FET (Field Effect Transistor) or a relay.

  The chassis 20 accommodates the CPU blade 10, and in addition to the CPU blade 10, a cooling fan (not shown), a backplane 21 and the like are mounted.

  The backplane 21 is a circuit board on which a slot into which a plurality of server blades 12 are inserted, a feeder line, a connection port of a communication line, and the like are mounted. Further, a storage unit such as a ROM is provided, and configuration information such as a slot ID, a chassis number, and a group number is stored. The backplane 21 may be provided with a slot into which the CMM 30 is inserted.

  The slot ID is a unique ID within the chassis 20 and can be used to identify the blade 11 inserted into the slot. The chassis number is a number for identifying the chassis 12 when there are a plurality of chassis 12. The group number is a number for identifying the CMM 30.

Next, the operation of the blade server system 1 in the present embodiment will be described. FIG. 2 is a flowchart showing the operation of the blade server system 1 when the CMM 30 receives an inquiry to the n-th BMC 11 [n] and can reply with information held by the CMM 30. The operation at this time is as follows.
1) First, the CMM 30 receives an inquiry from the management server 40 or the like.
2) Next, the information held by the CMM 30 is returned as an answer to the inquiry source. Here, the CMM 30 monitors not only the communication to itself but also the communication to the subordinate BMC 11 [n] address. Information about the BMC 11 is also held. Therefore, the CMM 30 can return an answer to the inquiry without starting the BMC 11.

FIG. 3 is a flowchart showing the operation of the blade server system 1 when it is necessary to start up the BMC 11 in order to answer an inquiry. The operation in this case is as follows.
1) First, the CMM 30 receives an inquiry.
2) Next, the CMM 30 once holds the contents of the inquiry and the address of the BMC 11 [n].
3) Next, the CMM 30 determines whether the startup of the BMC 11 can be completed within a predetermined time. If it is determined that the startup of the BMC 11 is not completed within the specified time, a message indicating that the power is being started is transmitted to the request source. If it is determined that start-up can be completed within the specified time, message transmission is skipped.
4) Next, the standby power control switch 13 [n] is turned on.
5) Next, BMC 11 [n] starts up.
6) When BMC 11 [n] rises, CMM 30 receives necessary information from BMC 11 [n].
7) Next, the CMM 30 transmits an answer to the request source.
8) Next, the CMM 30 lowers the BMC 11 [n].
9) Next, the CMM 30 turns off the standby power control switch 13 and ends the process. Note that the power-off timing can be optimized according to the application scene, such as maintaining the on state for a certain period of time.

FIG. 4 is a flowchart showing the operation of the blade server system 1 when the CPU blade 10 [n] is activated to perform processing. The operation in this case is as follows.
1) First, the CMM 30 receives a processing request for the CPU blade 10 [n] from the management server 40 or the like.
2) Next, the CMM 30 once holds the requested content and the address of the BMC 11 [n].
3) Next, the CMM 30 determines whether the startup of the CPU blade 10 can be completed within a predetermined time. If it is determined that the startup of the CPU blade 10 is not completed within the specified time, a message indicating that the CPU blade 10 is starting up is transmitted to the request source. If it is determined that start-up can be completed within the specified time, message transmission is skipped.
4) Next, the standby power control switch 13 is turned on.
5) Next, BMC 11 [n] starts up. Standby power is also supplied to the NIC 12, and the CPU blade 10 is connected to the IP network 60.
6) When BMC 11 [n] starts up, BMC 11 [n] starts up CPU blade 10 [n].
7) Next, the CPU blade 10 [n] executes the process.
8) Next, the CPU blade 10 [n] is kept on for a certain time. When there is a next processing request within the time, the CPU blade 10 [n] executes the processing.
9) If there is no next processing request within a predetermined time, the BMC 11 [n] lowers the CPU blade 10 [n].
10) Next, the CMM 30 lowers the BMC 11 [n].
11) Next, the CMM 30 turns off the standby power control switch 13 and ends the process.

  Although the description so far has been performed using a wired connection, there is no problem even if the communication between the CMM 30 and the management server 40 and the communication between the CPU blade 10 and the IP network 60 are performed wirelessly.

As described above, according to the present embodiment, power is not supplied to the BMC 11 and the NIC 12 except when necessary. For this reason, the power consumption when the CPU blade 10 is in the standby state can be greatly reduced.
(Second Embodiment)
Next, a second embodiment of the present invention will be described. As described in the first embodiment, the non-operating CPU blade 10 including the BMC 11 is completely stopped in the present invention. For this reason, when a request that cannot be processed by only the operating CPU blade 10 is received, a standby time for starting up the CPU blade 10 is required. In order to eliminate this waiting time, in the second embodiment, a predetermined number of spare blades to be kept on are prepared in addition to the operating CPU blade 10. Although at least one spare CPU blade 10 is provided, it can be added in accordance with the operation status. The setting may be performed by software processing using the management server 40.
(Third embodiment)
The blade server system 1 in the present embodiment is characterized by being compatible with Wake on LAN (WOL). WOL is a function for turning on a computer via a LAN. In the blade server system 1 of the present invention, the power control of each CPU blade 10 is managed by the CMM 30, but there are models of other CPU blades that perform power control by the WOL. In the present embodiment, compatibility with these models is guaranteed.

  As an example, let us consider a case where some CPU blades 10 include a WOL compatible NIC 12. At this time, the CMM 30 acquires the MAC address of the NIC 12 corresponding to the WOL as hardware configuration information via the BMC 11. The CMM 30 monitors the MAC address of the subordinate WOL compatible CPU blade 10 when the power is off or in a standby state. In this state, when the CMM 30 receives a magic packet that is a WOL request, the CMM 30 executes control to turn on the power of the CPU blade 10 as a WOL compatible operation.

FIG. 5 is a flowchart showing the startup operation of the CPU blade 10 by WOL.
1) First, the CMM 30 receives a WOL request addressed to the CPU blade [n].
2) The CMM 30 once holds the address of the CPU blade 10.
3) Next, the CMM 30 determines whether the startup of the CPU blade 10 can be completed within a predetermined time. If it is determined that the startup of the CPU blade 10 is not completed within the specified time, a message indicating that the CPU blade 10 is starting up is transmitted to the request source. If it is determined that start-up can be completed within the specified time, message transmission is skipped.
4) Next, the standby power control switch 13 is turned on.
5) Next, BMC 11 [n] starts up. The standby power is also supplied to the NIC 12.
6) When BMC 11 [n] starts up, BMC 11 [n] starts up CPU blade 10 [n].

  As described above, according to the present embodiment, it is possible to cope with the conventional compatible WOL without always supplying a standby voltage to the NIC 12, thereby reducing power consumption.

1 blade server system 10 CPU blade 11 BMC
12 NIC
13 Standby power control switch 20 Chassis 21 Backplane 30 CMM
40 Management server 50 Management LAN
60 IP network 70 PSU
71 Commercial power supply 72 Main voltage supply line 73 Standby voltage supply line 100 Blade server system 110 CPU blade 111 BMC
112 NIC
120 Management server 130 Client 140 IP network 150 PSU
151 Commercial power supply 152 Main voltage supply line 153 Standby voltage supply line

Claims (9)

  A plurality of server blades, a BMC (Base Management Controller) mounted on the server blade, a standby voltage supply line for supplying a standby voltage to the BMC, and the BMC and the standby voltage supply line are provided. A blade server system comprising: intermittent means; and a CMM (Chassis Management Module) for controlling the BMC and the intermittent means.   The blade server system according to claim 1, wherein the CMM has a function of controlling the intermittent means to cut off the supply of the standby voltage to the server blade that is not activated.   3. The server blade according to claim 1, wherein the server blade has a NIC (Network Interface Card), and the NIC is connected to the standby voltage supply line through the intermittent means. The blade server system described.   4. The blade server according to claim 1, wherein the CMM includes a storage unit that holds an address of the BMC and information related to the BMC, and a communication unit that communicates with the outside. 5. system.   A part or all of the server blade is compatible with WOL (Wake on LAN), the CMM receives a WOL signal, and the CMM performs power control of the server blade according to the signal. The blade server system according to any one of claims 1 to 4.   A plurality of server blades, a BMC mounted on the server blade, a CMM that controls the BMC, a standby voltage supply line that supplies a standby voltage to the BMC, and between the BMC and the standby voltage supply line A method for controlling a blade server having an intermittent means provided, wherein the CMM controls the intermittent means. The blade server control method according to claim 6, wherein the server blade has a NIC, and the standby voltage is supplied to the NIC via the intermittent means. The blade according to any one of claims 6 to 7, wherein supply of the standby voltage to the BMC mounted on the server blade that has not been activated is interrupted by the control of the interrupting means. Server control method. 9. The blade server control method according to claim 8, wherein a predetermined number of spare server blades are activated under the control of the CMM in addition to the server blade that is executing the processing.

Images