JP2008269385A - Disk loading system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk loading system for allowing access to both SATA disks from respective expanders even when the SATA disks are used in a disk loading system. <P>SOLUTION: The disk loading system comprises a pair of controllers 30 for controlling data write and read to/from a disk, wherein the controllers 30 are connected to each other by a signal line; a pair of expanders 15 connected to corresponding controllers 30, having two input-output ports and connected to each other by a signal line; a pair of multiplexers 35, with corresponding input-output ports connected to the expanders 15 and the other input-output ports respectively connected to the opposite first and second expanders; and SATA disks 25 connected through the multiplexers 35. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a disk mounting system, and more particularly to a disk mounting system used by connecting a SAS and a SATA disk.

  Both the SAS disk and the SATA disk have a disk circuit board, and data is stored in the disk circuit board. Data is exchanged between the disk circuit board and the SAS disk or SATA disk. That is, the data written to the disk is once held on this disk circuit board, and the data read from the disk is also held on this disk circuit board.

  FIG. 3 is a diagram showing an external configuration of the SAS connector. In the figure, 1 is a drive plug connector, and 2 is a receptacle connector. (A) shows the surface of the drive plug connector, and (b) shows the back surface. (C) shows the front surface of the receptacle connector, and (d) shows the back surface. On the surface of the drive plug connector 1, a 7-pin signal line S1 to S7 and a power supply line P1 to P14 are provided. On the back surface of the drive plug connector 1, 7-pin signal lines S8 to S14 are provided.

  In this configuration, S1 to S7 are primary and S8 to S14 are secondary. In this signal line, RX (reception signal) and TX (transmission signal) are configured to have a differential configuration of 4 for each port, 2 grounds, and 1 ready LED. The power line is composed of 3 wires each having −3.3V, 5.0V and 12V, and 5 wires. Of these, -3.3V is reserved and is not used by all vendors.

  FIG. 4 is an explanatory diagram of the connection of the SAS connector. The same components as those in FIG. 3 are denoted by the same reference numerals. A disk circuit board 3 is connected to the drive plug connector 1, and the drive plug connector 1 is inserted into the receptacle connector 2 in the direction of the arrow to complete the connection.

  FIG. 5 is a diagram showing an external configuration example of the SATA connector. In the figure, 5 is a drive plug connector, and 6 is a receptacle connector. The connection of the SATA connector is the same as that shown in FIG. S1 to S7 are signal lines and have a one-port configuration. In this signal line, RX (reception signal) and TX (transmission signal) are configured in a differential manner, four lines, two grounds, and one ready LED. P1 to P14 are power supply lines, each of which includes −3.3V, 5.0V and 12V, and five grounds. Reference numeral 7 denotes a protrusion provided on the receptacle connector 6, which is provided so that the pin arrangement is not mistaken when the drive plug connector 5 is inserted into the receptacle connector 6.

  FIG. 6 is a diagram showing the connection between the expander and the SAS disk. In the figure, 15 is a pair of expanders. The pair of expanders are denoted by # 1 and # 2, respectively. Reference numeral 16 denotes a SAS disk connected to these expanders 15. A pair of the SAS disks 16 are also provided, which are indicated by # 1 and # 2, respectively.

  The numerals attached to the expander 15 and the SAS disk 16 in the figure indicate connector numbers. Hereinafter, this connector number is indicated by C (number). That is, the expander # 1 has C1-C3 connectors, and the expander # 2 has C4-C6 connectors. The SAS disk # 1 has C7 and C8 connectors, and the SAS disk # 2 has C9 and C10 connectors.

  17 is a signal line connecting the connector C3 of the expander # 1 and the connector C4 of the expander # 2, 18 is a signal line connecting the connector C1 of the expander # 1 and the connector C7 of the SAS disk # 1, and 19 is A signal line connecting the connector C2 of the expander # 1 and the connector C10 of the SAS disk # 2, 20 is a signal line connecting the connector C5 of the expander # 2 and the connector C9 of the SAS disk # 2, and 21 is an expander. This is a signal line that connects between the connector C6 of # 2 and the connector C8 of the SAS disk # 1. The signal lines 19 and 21 are used to connect the expander 15 and the SAS disk 16 with a brush. In the case of the SAS disk 16, since it has two ports, such a plow connection is possible.

  By adopting such a plowing configuration, for example, when the expander # 1 fails, the other expander # 2 can be used to access the SAS disk # 1 from the expander # 2. It becomes possible.

  FIG. 7 shows the connection between the expander and the SATA disk. The same components as those in FIG. 6 are denoted by the same reference numerals. In the figure, 15 is a pair of expanders, and 25 is a pair of SATA disks. The expanders # 1 and # 2 are connected by a signal line 17 via connectors C3 and C4. The connector C1 of the expander # 1 and the connector C7 of the SATA disk # 1 are connected by a signal line 18, and the connector C5 of the expander # 2 and the connector C9 of the SATA disk # 2 are connected by a signal line 20. . As shown in the figure, the SATA disk 25 has only one port, so that it is impossible to make a connection as in the case of the SAS disk shown in FIG.

  In this type of conventional device, the disk management program communicates with each disk controller to determine what kind of disk drive is connected to the disk controller, and based on the results, it is appropriate for the disk drive. A technique for selecting an appropriate protocol is known (see, for example, Patent Document 1).

  It also has a point-to-point controller that manages each of the plurality of arrays, communicates with each other, can be connected to all storage media, and switching means for switching the point-to-point controller. A technique is known in which the switching means is switched when a failure of the point-to-point controller is detected (see, for example, Patent Document 2).

Further, when the controller writes the target data to the HDD, the controller stores the partially extracted data d1 on the management area side, XORs the check code d2 generated by the calculation, and returns the calculation result data d3 to the target data. When the target data is read from the HDD, the embedded data d3 is taken out, an XOR operation is performed to apply the check code d2, and the operation result and the partially extracted data d1 of the management area are obtained. A technique for checking the correctness of addressing by comparing and collating and restoring user data is known (see, for example, Patent Document 3).
JP 2006-195975 (paragraphs 0014 to 0026, FIGS. 1 to 4) Japanese Unexamined Patent Publication No. 2003-196036 (paragraphs 0026 to 0039, FIGS. 1 and 2) Japanese Patent Laying-Open No. 2006-79380 (paragraphs 0048 to 0069, FIGS. 1 and 2)

  Since the SAS connector and the SATA connector described above have different connector shapes as shown in FIGS. 3 to 5, a SATA disk can be mounted on the SAS connector, but a SAS disk is mounted on the SATA connector. Can not do it. In addition, when a SATA disk is mounted on a SAS connector, there is a problem that a duplex system cannot be constructed.

  In general, it is possible to mount a SATA disk in a system that can mount a SAS disk, but it is impossible to mount a SAS disk in a system that can mount a SATA disk. Therefore, in a system configured using an expander, even when the SAS expander is made redundant and the SAS disk is accessed, the SATA disk can be accessed only from the path of one of the expanders. . This is because the SATA disk has one port.

  Therefore, when the SATA disk is mounted, there is a problem that when the expander on the access path to the SATA disk cannot be operated due to a failure or the like, the other expander cannot access the SATA disk. The present invention has been made in view of such problems. Even when a SATA disk is used, both SATA disks can be accessed from each expander, and a failure occurs in the route. In addition, an object is to provide a disk mounting system in which a failure location can be specified even when access to a SATA disk is disabled from both expanders.

(1) The invention described in claim 1 is a pair of controllers (a first controller and a second controller) for controlling writing and reading of data to and from the disk, and each of them is connected by a signal line. A pair of expanders (a first expander and a second expander) connected to the corresponding controller and having two input / output ports, each connected by a signal line; The first and second expanders and one of the corresponding input / output ports are connected, and the other input / output port is a pair of multiplexers connected to the first and second expanders by dragging, and these It is characterized by comprising SATA disks (a first SATA disk and a second SATA disk) connected via a multiplexer.
(2) In the invention according to claim 2, the expander side is provided with a function of accessing an intermediate route, and the multiplexer in the intermediate route is provided with a function of responding to an access from the expander. Features.
(3) In the invention according to claim 3, when an error occurs in access to the first SATA disk from the first expander, the first SATA disk is accessed from the second expander, which is an error. In some cases, it is characterized by detecting which component causes an error by performing a separation process.
(4) The invention according to claim 4 is characterized in that in the separation process, information on a lower apparatus is acquired from an upper apparatus, and an error occurrence location is specified based on the acquired information.

(1) According to the first aspect of the present invention, both SATA disks can be accessed from each expander.
(2) According to the invention described in claim 2, even when a failure occurs in the route for transmitting data, it is possible to obtain information when searching for the location where the failure has occurred.
(3) According to the invention described in claim 3, when an error occurs in accessing the first SATA disk from the first expander, the error occurs in which component by performing the isolation process. Can be detected.
(4) According to the invention described in claim 4, the error occurrence location can be specified by acquiring the information for the lower device from the upper device in the separation process.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram illustrating a configuration example in which a SATA disk can be mounted. In a system in which a SATA disk is mounted, an example in which a multiplexer is used to enable access to a SATA disk from a redundant expander. . 6 and 7 are denoted by the same reference numerals. In the figure, reference numeral 30 denotes a pair of controllers that control writing and reading of data to and from the disk, and is composed of a controller # 1 and a controller # 2. Reference numeral 31 denotes a signal line that connects the controllers 30 and connects the connector C10 of the controller # 1 and the connector C11 of the controller # 2.

  Reference numeral 15 denotes a pair of expanders, which includes an expander # 1 and an expander # 2. Reference numeral 17 denotes a signal line that connects both expanders, and connects between the connector C3 of the expander # 1 and the connector C5 of the expander # 2. A signal line 32 connects the controller # 1 and the expander # 1, and connects the connector C9 of the controller # 1 and the connector C4 of the expander # 1. A signal line 33 connects the controller # 2 and the expander # 2, and connects the connector C12 of the controller # 2 and the connector C8 of the expander # 1.

  Reference numeral 35 denotes a pair of multiplexers, which are composed of a multicast # 1 and a multiplexer # 2. A signal line 18 connects the expander # 1 and the multiplexer # 1, and connects the connector C1 of the expander # 1 and the connector C13 of the multiplexer # 1. A signal line 20 connects the expander # 2 and the multiplexer # 2, and connects the connector C6 of the expander # 2 and the connector C16 of the multiplexer # 2. A signal line 19 connects between the expander # 1 and the multiplexer # 2, and connects between the connector C2 of the expander # 1 and the connector C17 of the multiplexer # 2.

  A signal line 21 connects between the expander # 2 and the multiplexer # 1, and connects between the connector C7 of the expander # 2 and the connector C14 of the multiplexer # 1. Reference numeral 25 denotes a pair of SATA disks, which are composed of a SATA disk # 1 and a SATA disk # 2. A signal line 36 connects between the multiplexer # 1 and the SATA disk # 1, and connects between the connector C15 of the multiplexer # 1 and the connector C19 of the SATA disk # 1.

  A signal line 37 connects between the multiplexer # 2 and the SATA disk # 2, and connects the connector C18 of the multicast # 2 and the connector C20 of the SATA disk # 2. A signal line 19 connects between the expander # 1 and the multiplexer # 2, and connects between the connector C2 of the expander # 1 and the connector C17 of the multiplexer # 2. Reference numeral 40 denotes a SATA unit composed of a SATA disk 25 and a multiplexer 35. The operation of the system configured as described above will be described as follows.

  As shown in the figure, the multiplexer 35 and the SATA disk 25 are connected on a one-to-one basis. On the other hand, the multiplexer 35 and the expander 15 are connected to each other by # 1 and # 2 systems. As a result, both expanders # 1 and # 2 can be connected to # 1 and # 2 SATA disks. As a result, even when one of the expanders 15 breaks down, since there is a path from the other expander 15 to the SATA disk 25, access to the SATA disk can be guaranteed.

  For example, if the expander # 1 is out of order, the expander # 1 cannot access the SATA disk # 1, but the expander # 2 can access the SATA disk # 1. At this time, the multiplexer 25 is switched so as to be connected to the expander # 2 via the SATA disk # 1 and the signal line 21. Then, the controller # 2 can access the SATA disk # 1 to control data writing and reading. That is, according to the configuration shown in FIG. 1, both SATA disks 25 can be accessed from each expander 15.

  By the way, in the system shown in FIG. 1, the same SATA disk can be accessed from the redundant expander 15 (for example, when the SATA disk # 1 is accessed from the expanders # 1 and # 2 in FIG. 1). At this time, if access from the expander # 1 becomes impossible due to a failure or the like, the route is switched to the route from the expander # 2 to access the SATA disk # 1, but this route is also inaccessible. Then, there is a problem that it cannot be determined whether the failure is in the multiplexer # 1 or the SATA disk # 1.

  Therefore, in the present invention, the expander 15 has a function of accessing a halfway route as a means of separation when there is a failure in the route and access to the SATA disk 25 becomes impossible from both expanders 15. The multiplexer 35 on the way is provided with a function of responding to access from the expander 15. By providing such a function, even when a failure occurs in the route for transmitting data, it is possible to obtain information when searching for a location where the failure has occurred. Also, when an error occurs in accessing the first SATA disk from the first expander, the first SATA disk is accessed from the second expander, and if it is an error, a separation process is performed. Thus, it is possible to detect which component has an error.

  FIG. 2 is a flowchart showing an example of the operation (slicing process) of the present invention. In this example, the operation when the expander # 1 accesses the SATA disk # 1 will be described. It is assumed that an error has occurred in access from the expander # 1 to the SATA disk # 1 (S1). Recognizing the occurrence of this error, controller # 1 switches from expander # 2 to SATA disk # 1 access (S2).

  In this state, the controller # 1 checks whether an error occurs (S3). If it is not an error, the controller # 1 determines that the expander # 1 and / or the multiplexer # 1 has failed (S4). If there is an error in step S3, the controller # 1 acquires information on the multiplexer # 1 from the expander # 1 (S5). Such an information acquisition operation can be performed by providing the expander with a function for accessing an intermediate route, and providing a multiplexer on the intermediate route with a function for responding to an access from the expander. . Then, it is checked whether information has been acquired (S6).

  If the information can be acquired, the controller # 1 determines that the multiplexer # 1 is normal. Although the multiplexer # 1 is normal, an error has occurred, so it is determined that the remaining SATA disk # 1 has failed (S7). If the information on the multiplexer # 1 cannot be acquired from the expander # 1 in step S6, the controller # 1 acquires the information on the multiplexer # 1 from the expander # 2 (S8), and acquires the information. It is checked whether or not it was possible (S9).

  As a result, if the information can be acquired, since the multiplexer # 1 is normal, it is determined that the SATA disk # 1 is out of order (S10). If the information cannot be acquired, there is a failure in the components after the multiplexer # 1. That is, it is determined that the multiplexer # 1 has failed and / or the SATA disk # 1 has failed (S11). As described above, according to the present invention, it is possible to identify the location where an error has occurred by acquiring information for the lower device from the upper device in the separation process. In the above description, the case where the controller # 1 is used for the separation process is taken as an example. However, the present invention is not limited to this, and the same separation process can be executed using the controller # 2.

  Next, processing during initialization will be described. At initialization, the following processing is performed. The controller 30 has a determination processing unit for determining whether or not to perform the separation. Further, the controller 30 recognizes whether the disk mounted at the time of initialization is a SAS or a SATA. Further, the controller 30 does not execute the determination process in the case of the SAS disk because the failure determination is easy, and performs the determination process shown in FIG. 2 in the case of the SAS disk.

  As described above, according to the present invention, even when a SATA disk is used, both SATA disks can be accessed from each expander, and there is a failure in the route. Thus, it is possible to provide a disk mounting system in which a failure location can be specified even when access to the server is disabled from both expanders.

It is a figure which shows the structural example which can mount a SATA disk. It is a flowchart which shows an example of operation | movement of this invention. It is a figure which shows the example of an external appearance structure of a SAS connector. It is explanatory drawing of the connection of a SAS connector. It is a figure which shows the external appearance structure of a SATA connector. It is a figure which shows the connection of an expander and a SAS disk. It is a figure which shows the connection of an expander and a SATA disk.

Explanation of symbols

15 expander 17 signal line 18 signal line 19 signal line 20 signal line 21 signal line 25 SATA disk 30 controller 31 signal line 32 signal line 33 signal line

Claims (4)

A pair of controllers (a first controller and a second controller) for controlling writing and reading of data to and from the disk, the two being connected by signal lines;
A pair of expanders (a first expander and a second expander) connected to the corresponding controller and having two input / output ports, each connected by a signal line;
The first and second expanders are connected to one of the corresponding input / output ports, and the other input / output port is a pair of multiplexers connected to the first and second expanders by rake. ,
A disk mounting system composed of SATA disks (first SATA disk and second SATA disk) connected through these multiplexers.   2. The disk mounting according to claim 1, wherein the expander side is provided with a function of accessing an intermediate path, and a multiplexer on the intermediate path is provided with a function of responding to an access from the expander. system.   When an error occurs in accessing the first SATA disk from the first expander, the first expander accesses the first SATA disk from the second expander. 3. The disk mounting system according to claim 2, wherein an error is detected in which component.   4. The disk mounting system according to claim 3, wherein the separation process acquires information on a lower apparatus from an upper apparatus and specifies an error occurrence location based on the acquired information.

Images