JP2007316782A - Host computer having power source linked control function, storage unit, power source linked control method of host computer, and power source linked control method of storage device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce management cost and to reduce manufacture cost of cards by realizing power source control between a higher-order device and a storage by the protocol on the interface used to data access, and by connecting the higher-order device with the storage not using card for exclusive use of conventional power source linked control. <P>SOLUTION: A host computer 1A transfers power supply cutting instruction and the next feeding power beginning time to a storage device 10 when the host computer performs power supply cutting by shut down. The storage device 10 ends postprocessing necessary for power supply cutting when the storage device judges that there is no access from the host computer for a certain time period after receiving power supply cutting instruction from the host computer 1A, and sets the next feeding power beginning time to a timer (a timer of a clock and timer part 14). After completing the setting, the storage device performs feeding power stopping control from a storage device power supply 11. Next, when it becomes next feeding power beginning time set in the timer after stopping power feeding, power feeding from the storage device power supply 11 is started. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention includes a storage apparatus having a storage system power supply for supplying power to the apparatus and having a function of storing data, and a host computer connected to the storage apparatus, and the host computer and the storage The present invention relates to a host computer having a power interlock control function used in a system in which the apparatus performs power interlock control, a storage apparatus, a power interlock control method for the host computer, and a power interlock control method for the storage apparatus.

§1: Description of Conventional Example 1 FIG. 8 is an explanatory diagram of a conventional example. Hereinafter, Conventional Example 1 will be described with reference to FIG.

(a): Description of Configuration Conventionally, there is known a storage apparatus 10 that is connected to and operated by a plurality of servers 1 (in this example, three servers 1-1, 1-2, and 1-3). It was.

  The storage apparatus 10 includes a storage system power supply 11 for supplying power to each unit in the storage apparatus 10, a resident power supply 12 that constantly supplies the minimum power necessary for control in the storage apparatus 10, and the like. A power control unit 13 for controlling the power is provided. In addition, in order to perform power supply interlocking control of the server 1 and the storage device 10, each server 1 and the storage device 10 is provided with a slot for inserting the power control dedicated card 2, and in each of these slots, A power control card 2 is inserted and operated.

  The dedicated power control cards 2 of each server are connected to each other by a power control cable 3 according to a formula. Further, one of the servers (for example, the server 1-1) and the dedicated power control card 2 of the storage device 10 are connected by a power control cable 3.

  The power control unit 13 and the power control dedicated card 2 of the storage apparatus 10 are always supplied with power from the resident power source 12 (minimum power required for control etc.), and the storage system power source 11 is turned off (off). Even in such a case, a command related to power control from the server 1 can be executed.

(b): Explanation of operation During normal operation, the server 1 (servers 1-1, 1-2, 1-3) accesses the storage device 10 to perform data read and write operations. In this case, the storage apparatus 10 is powered on / off (power on / off) under the control of the server 1, and this operation is performed by the power control card 2. That is, the dedicated power control cards 2 of the servers 1-1, 1-2, 1-3 are connected in a manner that depends on the power control cable 3, and therefore when any one of the servers 1 operates, the storage device 10 A power-on control signal is sent to the power control dedicated card 2 to turn on the storage system power supply 11 of the storage apparatus 10.

  When the storage system power supply 11 of the storage 1 is turned off (off), the storage device 10 detects that all the power sources of the server 1 are turned off (off), and the storage system power supply 11 of the storage device 10 is also turned off. Control to turn off (off).

(c): Explanation of functions, features, etc. When it is necessary to control the power supply of the entire system, it is linked with the power on / off of the servers 1-1, 1-2, 1-3 to which the storage apparatus 10 is connected. Therefore, it is necessary to control the storage system power supply 11 of the storage apparatus 10. That is, when the storage device 10 is not used, the storage system power supply 11 of the storage device 10 is turned off (off), and only when the storage device 10 is used by the server, the storage system power supply 11 of the storage device 10 is turned on (on). By doing so, the entire system can be saved.

  Such power savings can reduce management costs and reduce costs. And now there is a demand for power saving measures and cost reduction. However, when the power control is performed using the power control card 2 as described above, a dedicated card is necessary, and this card is expensive. In particular, the card needs to be remade every time the system is upgraded, and the dedicated power control card 2 cannot be cheap.

§2: Description of Conventional Example 2 Hereinafter, Patent Document 1 will be described as Conventional Example 2. Conventional Example 2 describes the following contents.

(a): “In the conventional disk array device, after starting the host computer, the operator must turn on the uninterruptible power supply (UPS) in order to start each disk array device (DF). Solve the problem that the disk array device could not be started in advance. "... See the summary column
(b): “Uninterruptible power supply that receives AC power and supplies AC power to the corresponding disk array device, provided with a LAN card and interface board, and a host computer that controls the start and stop of the disk array device and uninterruptible Enables transmission and reception of signals between the power supply unit and the disk array unit. "... See the summary section

§3: Description of Conventional Example 3 Hereinafter, Patent Document 2 will be described as Conventional Example 3. Conventional Example 3 describes the following contents.

(a): “Provide a remote automatic power control device for computer systems.” See the summary section.
(b): “A peripheral device such as a data storage device is used in a computer system having one or more computers. The computer system may be a fiber channel or serial providing a continuous clock synchronous serial link. Includes an interface architecture such as Storage Architecture (SSA) Data storage devices include data storage components such as power supplies and disk drives in a housing adapted to connect with a computer through wires 1 One or more data communication interfaces are provided on the housing and connected to the data storage component, which includes a substantial power-up state and a substantial power-down state input in response to a power-down signal. And having The detector circuit detects the clock signal loss at each data communication interface and generates a power-down signal in response to it. "... See summary section

§4: Description of Conventional Example 4 Hereinafter, Patent Document 3 will be described as Conventional Example 4. Conventional Example 4 describes the following contents.

(a): “Implement a peripheral device that turns the power on and off in response to the power on and off of the host device.” See the summary column.
(b): “The purpose of the present invention is to detect the ON / OFF state of the host device on the peripheral device connected to the host device when the host device is turned on or off. It is to provide a peripheral device that is remotely controlled to turn on and off its own power supply, which can be turned on and off by the peripheral device itself according to the state. "... see paragraph [0009]
JP 2003-36125 A JP 2000-214964 A Japanese Patent Laid-Open No. 5-204497

  (1): Conventional example 1 requires a dedicated card for power control. However, such a dedicated card is expensive, and operations such as card insertion are cumbersome and troublesome.

  (2): In Conventional Example 1, the management cost can be reduced by power saving, and the cost can be reduced. And now there is a demand for power saving measures and cost reduction. However, when the power is controlled using the card as described above, a dedicated card is expensive. In particular, it is necessary to recreate the card every time the system is upgraded, and a dedicated card cannot be cheap.

  (3): Conventional example 2 performs remote automatic power control of a computer system. However, the configuration requirements of the present invention are not included, and the contents of control are different from the present invention.

  (4): In the conventional example 3, when the power of the host device is turned on or off, the peripheral device connected to the host device detects the power on / off state of the host device and changes to this detected state. Accordingly, there is provided a peripheral device that is remotely controlled to turn on / off the power supply that can turn on and off its own power supply by the peripheral device itself. However, the configuration requirements of the present invention are not included, and the contents of control are different from the present invention.

  The present invention has been made in order to solve the above-mentioned problems, and it is possible to connect a host device and a storage without using a conventional card dedicated to power supply interlocking control, and on an interface used for data access. The purpose is to save power, reduce the management cost, and reduce the cost of card production by realizing power control between the host device and the storage using the protocol.

  In order to achieve the above object, the present invention is configured as follows.

  (1): having a storage system power supply for supplying power to the apparatus and having a function of storing data, and a host computer connected to the storage apparatus, the host computer and the storage In the host computer of the system in which the apparatus performs power supply interlocking control, a setting information storage unit that sets the next power supply start time based on input information from the outside, and internal information when power is shut down by shutdown And a command issuing means for issuing a command including the power-off instruction and the next power supply start time to the storage device. It is characterized by having.

  (2): having a storage system power supply for supplying power to the apparatus and having a function of storing data, and a host computer connected to the storage apparatus, the host computer and the storage In the storage apparatus of the system in which the apparatus performs power supply interlocking control, command receiving means for receiving a command including a power-off instruction and a next power supply start time from the host computer, and a predetermined time after receiving the power-off instruction The monitoring means for monitoring that there is no access from the host computer, and if it is confirmed by the monitoring that there is no access from the host computer for a predetermined time, the host computer side determines that the power supply has been turned off. Necessary to turn off the power after receiving the power-off instruction After finishing the post-processing, the setting means for setting the next power supply start time in the timer, the power supply stop control means for controlling the power supply from the storage system power supply to be stopped after the setting is completed, and after stopping the power supply, A power supply start control means for starting power supply from the storage system power supply when the next power supply start time set in the timer is reached is provided.

  (3): In the storage device of (2), when there are a plurality of host computers connected to the storage device, a power-off instruction and a next power supply start time are received from all the host computers connected to the storage device. And confirming means for confirming that all the host computers are in a power-off state, receiving a power-off instruction and a next power supply start time from all the host computers by the confirming means, and all the host computers. Confirming that the power supply is off, the setting means adopts the earliest time among the power supply start times received from all the host computers as the next power supply start time, and uses this time as the timer. It is characterized by having a function to set to.

  (4): having a storage system power supply for supplying power to the apparatus and having a function of storing data, and a host computer connected to the storage apparatus, the host computer and the storage In the power interlocking control method of the host computer of the system in which the apparatus performs power interlocking control, a setting information procedure for setting the next power supply start time based on input information from the outside, and when performing power shutdown by shutdown, Creates a power-off instruction based on internal information, issues an information acquisition procedure for reading the next power supply start time from the setting information storage unit, and issues a command including the power-off instruction and the next power supply start time to the storage device And a command issuing procedure.

  (5): having a storage system power source for supplying power to the apparatus and having a function of storing data, and a host computer connected to the storage apparatus, the host computer and the storage In the power supply interlocking control method of the storage apparatus of the system in which the apparatus performs power interlocking control, a command receiving procedure for receiving a command including a power off instruction and a next power supply start time from the host computer, and after receiving the power off instruction, When it is confirmed that there is no access from the host computer for a predetermined period of time by the monitoring procedure for monitoring that there is no access from the host computer for a predetermined period of time and the monitoring, the host computer side Receiving the judgment procedure for judging that the power has been turned off and the power-off instruction Thereafter, the post-processing necessary for power-off is terminated, a set procedure for setting the next power feed start time in a timer, a power feed stop control procedure for performing control to stop power feed from the storage system power supply after the set, A power supply start control procedure for starting power supply from the storage system power supply at the next power supply start time set in the timer after power supply is stopped is provided.

(Function)
FIG. 1 is a diagram illustrating the principle of the present invention. The operation of the present invention will be described below with reference to FIG.

(a): Actions of (1) and (4) The main control unit 25 of the host computer 1A sets the next power supply start time in the setting information storage unit 21 based on the input information from the outside. Next, the main control unit 25 of the host computer 1A creates a power-off instruction based on internal information when the power is shut down by shutdown, and reads the next power supply start time from the setting information storage unit 21, It is passed to the driver 22. The device driver 22 (command issuing means) issues a command including the power-off instruction and the next power supply start time to the storage apparatus 10.

  In this way, the power supply control between the host device and the storage can be performed using the protocol on the interface used for data access by connecting the host device and the storage without using the conventional dedicated card for power interlocking control. By realizing it, it is possible to save power, reduce the management cost, and reduce the cost for card production.

(b): Operation of the above (2) and (5) In the storage apparatus 10, the command receiving means (host interface control unit 17) receives a command including a power-off instruction and the next power supply start time from the host computer 1A. The monitoring means (main control unit 16) monitors the absence of access from the host computer for a predetermined time after receiving the power-off instruction.

  As a result, when the determination unit (main control unit 16) confirms that there is no access from the host computer for a predetermined time, the host computer side determines that the power supply has been turned off. Then, after receiving the power-off instruction from the host computer 1A, the setting means (main control unit 16) terminates the post-processing necessary for power-off and sets the next power supply start time in the timer.

  Then, the power supply stop control means (power supply control unit 13) performs control to stop power supply from the storage system power supply 11 after the timer is set. The power supply start control means (power control unit 13) starts power supply from the storage system power supply 11 when the next power supply start time set in the timer comes after the power supply is stopped.

  In this way, without using a dedicated card for power control as in the past, the host device and storage are connected, and the power control between the host device and storage is realized using the protocol on the interface used for data access. By doing so, it is possible to save power, reduce the management cost, and reduce the cost for producing the card.

(c): Operation of (3) When there are a plurality of host computers 1A connected to the storage apparatus 10 of (2), all the confirmation means (main control unit 16) are connected to the storage apparatus 10. The power-off instruction and the next power supply start time are received from the host computer 1A, and it is confirmed whether all the host computers 1A are in the power-off state.

  As a result, when the power-off instruction and the next power supply start time are received from all the host computers 1A and it is confirmed that all the host computers 1A are in the power-off state, all the host computers are used as the next power supply start time. The earliest time among the power supply start times received from 1A is adopted, and this time is set in the timer.

  In this way, without using a dedicated card for power control as in the past, the host device and storage are connected, and the power control between the host device and storage is realized using the protocol on the interface used for data access. By doing so, it is possible to save power, reduce the management cost, and reduce the cost for producing the card.

  (1): According to the first to fifth aspects, the host device is connected to the host device and the storage without using the conventional card dedicated to the power supply interlocking control, and the host device is used with the protocol on the interface used for data access. By realizing the power control between the storage and the storage, it is possible to save power, reduce the management cost, and reduce the cost for producing the card.

§1: Outline Description FIG. 1 is an explanatory diagram of the principle of the present invention. The outline of the present invention will be described below with reference to FIG.

  (1): A storage apparatus 10 having a storage system power supply 11 for supplying power to the apparatus and having a function of storing data, and a host computer 1A (for example, a server) connected to the storage apparatus 10 And a system in which the host computer 1A and the storage apparatus 10 perform power supply interlocking control.

  (2): A setting information storage unit 21 (for example, a memory) that sets the next power supply start time based on input information from the outside (for example, an operator) in the host computer 1A (for example, a server) of the system. And means for generating a power-off instruction based on internal information (for example, OS information) and reading the next power supply start time from the setting information storage unit 21 (main control unit 25). ) And means for issuing a command including the power-off instruction and the next power supply start time to the storage apparatus 10 {device driver 22, storage interface control unit (storage I / F) 23}.

  (3): In the storage apparatus 10 of the system, means for receiving a command including a power-off instruction and a next power supply start time from the host computer 1A {host interface control unit (host I / F) 17A}, and a power-off instruction After receiving, means (main control unit 16) for monitoring that there is no access from the host computer 1A for a predetermined time, and that there is no access from the host computer 1A for a predetermined time by the monitoring The host computer 1A side determines that the power has been turned off (main control unit 16), and after receiving the power-off instruction, terminates the post-processing necessary for power-off and sets the next power supply start time to the timer. Means (main control unit 16) for setting (clock, timer unit 14), and after the set, the storage system power supply 11 Means for controlling power supply from the storage system (power supply control unit 13) and means for starting power supply from the storage system power supply 11 at the next power supply start time set in the timer after stopping the power supply (power supply) A control unit 13).

  (4): In the storage apparatus 10 of (3), when there are a plurality of host computers 1A connected to the storage apparatus 10, the power-off instruction and the next time from all the host computers 1A connected to the storage apparatus 10 All the host computers 1A are received by means (main control section 16) for receiving the power supply start time and confirming that all the host computers 1A are in a power-off state and the confirmation means (main control section 16). When the power-off instruction and the next power supply start time are received from all the computers and it is confirmed that all the host computers 1A are in the power-off state, the means (main control unit 16) A function of adopting the earliest time among power supply start times received from the host computer 1A and setting this time in the timer It is provided.

§2: Explanation of system configuration and functions
(1): Description of System Configuration FIG. 2 is a system configuration diagram. In the following description, an example in which a server is used as the host computer 1A will be described. Therefore, in the following description, a storage apparatus 10 having a storage system power supply 11 for supplying power to the apparatus and having a function of storing data, and a plurality of servers 1-connected to the storage apparatus 10 1, 1-2, 1-3 (for example, server), and a system in which the server 1 and the storage apparatus 10 perform power supply interlocking control is an object.

  That is, the system illustrated in FIG. 2 is a system including a plurality of servers 1-1, 1-2, 1-3 and a storage device 10 that can be accessed by each of these servers 1. The servers 1 and the storage apparatus 10 are connected by interface cables or the like.

  Each server 1 drives and controls a setting information storage unit 21 (for example, a memory) for storing setting information (for example, setting information such as a next power supply start time input by an operator or the like) and the storage device 10. A storage interface control unit (hereinafter referred to as “storage I / F”) 23 that performs interface control between the device driver 22 and the storage device 10, a clock that measures time, and a timer that measures time And a timer unit 24, and a resident power source 26 for supplying the minimum power necessary for the control in the server 1.

  The storage device 10 also includes a server interface control unit (hereinafter referred to as “server I / F”) 17 that performs interface control with the server 1, and a main control unit 16 that performs various controls and processes of the storage device 10. A work memory 15 capable of reading / writing various data, a clock for measuring time, a clock having a timer for measuring time, a timer unit 14, a storage system power supply 11, and a resident power supply 12. A power control unit 13 for controlling each power source is provided.

  With the above configuration, the storage system power supply 11 is supplied with AC other power from an external commercial AC power supply. Further, the resident power supply 12 is configured so that power is supplied from a part of the storage system power supply 11, and the power supply to the resident power supply 12 is not stopped even when the storage system power supply 11 is disconnected (off). Yes. The resident power supply 12 can be powered by a battery. Then, from this resident power supply 12, the server I / F 17, the main control unit 16, the power supply control unit 13, the clock, the timer unit 14, the memory 15, and the like are related to the on / off (on / off) of the storage system power supply 11. Instead, always supply the minimum power required for control.

(2): Description of function
(a): As described above, the storage apparatus 10 has the resident power supply 12, the clock, and the timer unit 14. When the time set in the memory 15 (power supply start time) comes, the control of the power supply control unit 13 The storage apparatus 10 has a function of supplying power by turning on (turning on) the storage system power supply 11.

  (b): The server 1 is provided with a device driver 22 for controlling the storage apparatus 10, and this device driver 22 exists on each connected server 1, and the connected storage apparatus 10 is Control. Note that information necessary for power-off is implemented as an interface (SCSI is generally used) command used for data access.

  (c): In the configuration of the system, the main control unit 25, the device driver 22, and the storage I / F 23 of the server 1 are each configured by a program, and by executing this program, the processing and control described below are performed. Is what you do. Further, the server I / F 17, the main control unit 16, and the power supply control unit 13 of the storage apparatus 10 are each configured by a program, and processing, control, and the like described below are performed by executing this program.

§3: Description of operation Hereinafter, the operation based on the configuration shown in FIG. 2 will be described.

Y: Sequence at power off
(1): Server 1 sequence
(a): The server 1 reads the next power supply start time from the setting information storage unit 21 when the power is shut down due to shutdown. In this case, in the setting information storage unit 21, the main control unit 25 sets information such as the next power supply start time in advance based on information from the outside. Then, as described above, the main control unit 25 reads the next power supply start time from the setting information storage unit 21 at a necessary timing and passes it to the device driver 22. At this time, the main control unit 25 creates a power-off instruction and passes it to the device driver 22.

  (b): The device driver 22 issues, via the storage I / F 23, a command including a power-off instruction to the storage apparatus 10 and a power-on start time of the storage apparatus 10 using the mounted commands.

  (c): Thereafter, the server 1 is powered off by shutdown.

(2): Sequence of storage device 10
(a): Access from the server 1 that has received the power-off instruction is not received for a predetermined time set in the memory 15 in advance.

  (b): Starts the power-off processing of the storage apparatus 10 on the condition that the server 1 is not connected.

  (c): The storage apparatus 10 receives the next power supply start time (received from the server 1) that has already been received after the main control unit 16 performs post-processing when the power is turned off (for example, flushing of data in the cache memory). Time) is set in the memory 15. Then, the main controller 16 notifies the power controller 13 that the power can be turned off.

  (d): The power supply control unit 13 refers to the next power supply start time set in the memory 15, sets the next power supply start time in the timer of the clock and timer unit 14, and then turns on the storage system power supply 11 of the storage apparatus 10. Disconnect.

Y: Sequence at power-on
(1): Sequence of storage device 10 When the next power supply start time set in the timer of the clock and timer unit 14 comes, the power supply control unit 13 of the storage device 10 starts the operation based on the information, and the storage system The power supply 11 is turned on and power supply in the storage apparatus 10 is started.

Y: Explanation of sequence, table data, operation, etc. at power-on in the storage system when multiple servers are connected
(1): Sequence of storage device 10
(a): The storage apparatus 10 stores the list information (see the table data in FIG. 3) of the server 1 to which the storage apparatus 10 is connected in the memory 15.

  (b): Power-off is performed on condition that the power-off instruction and the next power supply start time have been received from all the connected servers 1.

  (c): The main control unit 16 notifies the power supply control unit 13 that the power supply can be turned off, and the next power supply start time is within the next power supply start time received from all the servers 1. Use the earliest time. That is, when a plurality of servers 1 are connected, the earliest time among the next power supply start times received from all the servers 1 is adopted and set to the timer of the clock and timer unit 14.

(2): Table data used by the storage apparatus 10 and description of operation FIG. 3 is an explanatory diagram of table data, FIG. A is an example of a table inside the storage apparatus in use of the server 1-2, and FIG. It is an example of an internal table after receiving an instruction | indication. Hereinafter, the table data and the operation of the storage apparatus 10 will be described with reference to FIG.

  (a): Three servers 1, servers 1-1, 1-2, and 1-3, are connected to the storage apparatus 10 (see FIG. 2). It is assumed that the servers 1-1 and 1-2 have already been turned off due to shutdown.

  At this time, the table inside the storage apparatus 10 in use of the server 1-2 is as shown in FIG. 3A. In this example, the table of FIG. 3A is stored in the memory 15 and includes items of server identification information, power-off, and next power supply start time.

  According to this table, when server identification information = server 1-1, power is turned off = next power supply start time = 2006/03/31 09:00, when server identification information = server 1-2, power is off = no. Next power supply start time = none, server identification information = server 1-3, power off = present, next power supply start time = 2006/03/31, 10:00.

  (b): Next, the server 1-2 is powered off by shutdown, and receives the power-off instruction as 09:30 of the next power supply start time = 2006/03/31. The internal table after receiving the power-off instruction is as shown in FIG. 3B.

  In this case, when the server identification information = server 1-1, the power is turned off = Yes, the next power supply start time = 2006/03/31 09:00, when the server identification information = server 1-2, the power is turned off = Yes, the next power supply In the start time = 09: 30 of 2006/03/31, the server identification information = server 1-3, the power is cut off = the next power supply start time = 10: 00 of 2006/03/31.

  (c): As a result, since the power-off instruction has been received from all the connected servers 1, the timer of the clock and timer unit 14 is the earliest power supply start time next time, 2006/03/31 Is set to 09:00, and the power is turned off. At the set time, the storage system power supply 11 is turned on and power feeding is started under the control of the power supply control unit 13.

§4: Processing when server is powered off FIG. 4 is a flowchart of processing when the server is powered off. Hereinafter, the processing at the time of power-off of the server will be described with reference to FIG. In FIG. 4, S1 to S3 indicate each processing step.

  First, when the power is turned off by shutting down the server 1, the main control unit 25 creates a power-off instruction, reads the next power supply start time from the setting information storage unit 21, and passes it to the device driver 22 (S1). Next, the device driver 22 passes the power-off instruction and the next power supply start time to the storage apparatus 10 via the storage interface control unit (storage I / F) 23 (S2).

  In this case, the device driver 22 of the server 1 issues a command including the power-off instruction to the storage apparatus 10 and the power-on start time of the storage apparatus 10 via the storage I / F 23 with the mounted commands. Thereafter, the server 1 is turned off by shutting down (S3), and the process is terminated.

§5: Processing when the storage apparatus is powered off when there is one connected server FIG. 5 is a processing flowchart when the storage is powered off when there is one connected server. In the following, based on FIG. 5, a process when the storage apparatus is powered off when there is one connected server will be described. In FIG. 5, S11 to S18 indicate each processing step.

  First, the main control unit 16 of the storage apparatus 10 determines whether or not a power-off instruction from the server 1 and a next power supply start time (command) have been received (S11). wait. When receiving the power-off instruction from the server 1 and the next power supply start time (command), the main control unit 16 thereafter determines whether or not there is an access from the server 1 (S12).

  As a result, if there is an access from the server 1, processing is performed according to the access, but if there is no access from the server 1, a predetermined time after receiving a power-off instruction and the next power supply start time is received. It is determined whether or not it has elapsed (determined by measuring the elapsed time with a timer of the clock and timer unit 14) (S13).

  As a result, if the predetermined time has not elapsed, the process proceeds to S12. If the predetermined time has elapsed, communication with the connected server 1 is attempted (S14). Then, it is determined whether or not the communication has failed (S15). If not, the communication contents are followed. However, if it fails, the server 1 determines that the power has been turned off, and starts the power-off processing of the storage device 10 (S16).

  Next, the main control unit 16 finishes the post-processing necessary for power-off (for example, flushing in the cache memory, etc.), sets the next power supply start time to the clock and the timer unit 14, and stops the power supply The main control unit 16 notifies the power supply control unit 13 that it has become possible (S17).

  Next, the power supply control unit 13 that has received the notification that the power supply can be stopped disconnects the storage system power supply 11 (S18), and ends this processing.

§6: Processing when the storage apparatus is powered off when there are a plurality of connected servers FIG. 6 is a flowchart of the processing when the storage is powered off when there are a plurality of connected servers (part 1), FIG. It is a process flowchart (the 2) at the time of the power-off of a storage in case the number of connected servers is two. Hereinafter, based on FIG. 6 and FIG. 7, processing when the storage apparatus is powered off when there are a plurality of connected servers will be described. 6 and 7, S21 to S30 indicate each processing step.

  First, it is determined whether or not a power-off instruction from any one of the servers 1 and the next power supply start time (command) have been received (S21). When receiving the power-off instruction and the next power supply start time (command) from any server 1, the main control unit 16 thereafter determines whether or not there is an access from the server 1 (S22). .

  As a result, if there is an access from the server 1, processing is performed according to the access, but if there is no access from the server 1, it is determined in advance after receiving the power-off instruction and the next power supply start time (command). It is determined whether or not a predetermined time has elapsed (determined by measuring the elapsed time with a timer of the clock and timer unit 14) (S23).

  As a result, if the predetermined time has not elapsed, the process proceeds to S22, and if the predetermined time has elapsed, communication with the server 1 is attempted (S24). Then, it is determined whether or not the communication has failed (S25). If not, the communication contents are followed. However, if it fails, it is determined that the server 1 has been powered off, and the next processing is continued (S26).

  Next, a power-off instruction and a next power supply start time are received from all the connected servers 1, and it is determined whether or not all the servers 1 have been powered off (S27). In addition, the process of S27 performs the determination of said S27 by performing the same process as the process of S21 thru | or S26.

  As a result, if a power-off instruction and a next power supply start time are received from all the connected servers 1 and it is determined that all the servers 1 have not been powered off, the process proceeds to S21.

  However, if the power-off instruction and the next power supply start time are received from all the connected servers 1 and it is determined that all the servers 1 have been turned off, the main control unit 16 turns off the power. Necessary post-processing (for example, flushing in the cache memory, etc.) is terminated, the next power supply start time is set in the timer of the clock and timer unit 14, and the power supply control unit 13 is notified that the power supply can be stopped. Notification is made (S29). Next, the power supply control unit 13 that has received the notification that the power supply can be stopped disconnects the storage system power supply 11 (S30), and ends this processing.

§7: Description of program and recording medium In the server 1 and the storage device 10 (see FIG. 2) having the above-described configuration, in order to realize the processing of the server 1 or the storage device 10 in the storage means (hard disk device not shown). These programs are stored, and the CPU (for example, the main control units 25 and 16) reads out and executes the programs, thereby executing processing performed by the server 1 or the storage device 10.

  However, the present invention is not limited to such an example. For example, the program can be stored in the recording medium of the storage unit as follows, and the program can be executed by the CPU executing the program. It is.

  (a): A program stored in a removable disk created by another device (program data created by another device) is read by a removable disk drive (not shown) and stored in a recording medium of the storage means. .

  (b): Data such as a program transmitted from another device via a communication line is received via a communication control unit (not shown), and the data is recorded on the recording medium of the storage means (for example, a magnetic disk). To store.

(Appendix)
The following configuration is appended to the above description.

(Appendix 1)
A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the host computer of the system for controlling,
A setting information storage unit for setting the next power supply start time based on input information from outside;
When powering off by shutdown, creating a power-off instruction based on internal information, and information acquisition means for reading the next power supply start time from the setting information storage unit;
Command issuing means for issuing a command including the power-off instruction and the next power supply start time to the storage device;
A host computer characterized by comprising:

(Appendix 2)
A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the storage device of the system that performs control,
Command receiving means for receiving a command including a power-off instruction and a next power supply start time from the host computer;
Monitoring means for monitoring the absence of access from the host computer for a predetermined time after receiving the power-off instruction;
When it is confirmed by the monitoring that there is no access from the host computer for a predetermined time, the host computer side determines that the power is turned off;
After receiving the power-off instruction, the setting means for ending the post-processing necessary for power-off and setting the next power supply start time in the timer,
Power supply stop control means for performing control to stop power supply from the storage system power supply after the end of the set;
When the next power supply start time set in the timer is reached after stopping the power supply, power supply start control means for starting power supply from the storage system power supply,
A storage apparatus comprising:

(Appendix 3)
When there are a plurality of host computers connected to the storage device, a power-off instruction and a next power supply start time are received from all the host computers connected to the storage device, and all the host computers are in a power-off state. Confirmation means to confirm that there is,
When the confirmation means receives the power-off instruction and the next power supply start time from all the host computers and confirms that all the host computers are in the power-off state, the setting means sets the next power supply start time as The storage apparatus according to claim 2, further comprising a function of adopting the earliest time among power supply start times received from all host computers and setting the time in the timer.

(Appendix 4)
A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the power supply interlocking control method of the host computer of the system that performs control,
Setting information procedure for setting the next power supply start time based on input information from the outside,
An information acquisition procedure for creating a power-off instruction based on internal information when performing power-off by shutdown, and reading the next power supply start time from the setting information storage unit,
A command issuing procedure for issuing a command including the power-off instruction and the next power supply start time to the storage device;
A power supply interlocking control method for a host computer, comprising:

(Appendix 5)
A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the power supply interlocking control method of the storage device of the system that performs control,
A command receiving procedure for receiving a command including a power-off instruction and a next power supply start time from the host computer;
A monitoring procedure for monitoring the absence of access from the host computer for a predetermined time after receiving the power-off instruction;
When the monitoring confirms that there is no access from the host computer for a predetermined time, a determination procedure for determining that the host computer side has been turned off,
After receiving the power-off instruction, the post-process necessary for power-off is terminated, and the next power supply start time is set in the timer,
After the end of the set, a power supply stop control procedure for performing control to stop power supply from the storage system power supply,
When the next power supply start time set in the timer is reached after stopping the power supply, a power supply start control procedure for starting power supply from the storage system power supply,
A power supply interlocking control method for a storage apparatus, comprising:

(Appendix 6)
A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the host computer of the system performing the control,
A setting information storage unit for setting the next power supply start time based on input information from outside;
When powering off by shutdown, creating a power-off instruction based on internal information, and information acquisition means for reading the next power supply start time from the setting information storage unit;
A program for realizing a function of command issuing means for issuing a command including the power-off instruction and a next power supply start time to the storage device, or a computer-readable recording medium storing the program.

(Appendix 7)
A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the storage device of the system that performs control,
Command receiving means for receiving a command including a power-off instruction and a next power supply start time from the host computer;
Monitoring means for monitoring the absence of access from the host computer for a predetermined time after receiving the power-off instruction;
When it is confirmed by the monitoring that there is no access from the host computer for a predetermined time, the host computer side determines that the power is turned off;
After receiving the power-off instruction, the setting means for ending the post-processing necessary for power-off and setting the next power supply start time in the timer,
Power supply stop control means for performing control to stop power supply from the storage system power supply after the end of the set;
When the next power supply start time set in the timer comes after stopping the power supply, a program for realizing the function of the power supply start control means for starting the power supply from the storage system power supply, or a computer readable recording the program Recording medium.

It is a principle explanatory view of the present invention. It is a system configuration diagram in an embodiment. FIG. 4 is an explanatory diagram of table data in the embodiment, in which FIG. A is an example of a table inside a storage device in use of the server 1-2, and FIG. B is an example of an internal table cell after receiving a power-off instruction. It is a processing flowchart at the time of the power-off of the server in embodiment. 6 is a processing flowchart when the storage is powered off when there is one connected server in the embodiment. FIG. 10 is a process flowchart (part 1) when a storage is powered off when there are a plurality of connected servers in the embodiment; FIG. 10 is a process flowchart (part 2) when the storage is powered off when there are a plurality of connected servers in the embodiment. It is explanatory drawing of a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1-1, 1-2, 1-3 Server 1A Host computer 2 Power supply exclusive card 3 Power supply control cable 10 Storage device 11 Storage system power supply 12 Resident power supply 13 Power supply control part 14 Clock, timer part 15 Memory 16 Main Control unit 17 Server interface control unit (server I / F)
17A Host interface controller (host I / F)
21 Setting Information Storage Unit 22 Device Driver 23 Storage Interface Control Unit (Storage I / F)
24 Clock and timer section 25 Main control section 26 Resident power supply

Claims (5)

A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the host computer of the system for controlling,
A setting information storage unit for setting the next power supply start time based on input information from outside;
When powering off by shutdown, creating a power-off instruction based on internal information, and information acquisition means for reading the next power supply start time from the setting information storage unit;
Command issuing means for issuing a command including the power-off instruction and the next power supply start time to the storage device;
A host computer characterized by comprising: A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the storage device of the system that performs control,
Command receiving means for receiving a command including a power-off instruction and a next power supply start time from the host computer;
Monitoring means for monitoring the absence of access from the host computer for a predetermined time after receiving the power-off instruction;
When it is confirmed by the monitoring that there is no access from the host computer for a predetermined time, the host computer side determines that the power is turned off;
After receiving the power-off instruction, the setting means for ending the post-processing necessary for power-off and setting the next power supply start time in the timer,
Power supply stop control means for performing control to stop power supply from the storage system power supply after the end of the set;
When the next power supply start time set in the timer is reached after stopping the power supply, power supply start control means for starting power supply from the storage system power supply,
A storage apparatus comprising: When there are a plurality of host computers connected to the storage device, a power-off instruction and a next power supply start time are received from all the host computers connected to the storage device, and all the host computers are in a power-off state. Confirmation means to confirm that there is,
When the confirmation means receives the power-off instruction and the next power supply start time from all the host computers and confirms that all the host computers are in the power-off state, the setting means sets the next power supply start time as 3. The storage apparatus according to claim 2, further comprising a function of adopting the earliest time among power supply start times received from all host computers and setting the time in the timer. A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the power supply interlocking control method of the host computer of the system that performs control,
Setting information procedure for setting the next power supply start time based on input information from the outside,
An information acquisition procedure for creating a power-off instruction based on internal information when performing power-off by shutdown, and reading the next power supply start time from the setting information storage unit,
A command issuing procedure for issuing a command including the power-off instruction and the next power supply start time to the storage device;
A power supply interlocking control method for a host computer, comprising: A storage system having a storage system power supply for supplying power to the apparatus and having a function of storing data; and a host computer connected to the storage apparatus, the host computer and the storage apparatus being linked to the power supply In the power supply interlocking control method of the storage device of the system that performs control,
A command receiving procedure for receiving a command including a power-off instruction and a next power supply start time from the host computer;
A monitoring procedure for monitoring the absence of access from the host computer for a predetermined time after receiving the power-off instruction;
When the monitoring confirms that there is no access from the host computer for a predetermined time, a determination procedure for determining that the host computer side has been turned off,
After receiving the power-off instruction, the post-process necessary for power-off is terminated, and the next power supply start time is set in the timer,
After the end of the set, a power supply stop control procedure for performing control to stop power supply from the storage system power supply,
When the next power supply start time set in the timer is reached after stopping the power supply, a power supply start control procedure for starting power supply from the storage system power supply,
A power supply interlocking control method for a storage apparatus, comprising:

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