JP2009070360A - Hard disk-less type computer system for improving start efficiency - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hard disk-less type computer system for improving the start efficiency of a disk-less type computer by solving the delay of data write-in generated due to the delay of network communication. <P>SOLUTION: The hard disk-less type computer system for improving start efficiency is connected to a start server equipped with an operation system magnetic storage device, and provided with a memory unit, and a central processing unit connected to the memory unit, and the central processing unit temporarily stores an operation system kernel program and all data to be written in the operation system magnetic storage device in the memory unit, and transmits the response of write-in end to the operation system kernel program. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a hard diskless computer system capable of improving startup efficiency, and more particularly to a diskless computer system that improves startup efficiency by solving a data write delay caused by network communication delay.

In a conventional desktop personal computer, notebook personal computer or server computer, an operating system, application program and user data are stored in a built-in magnetic storage device. Operation systems and application programs that you are familiar with and data belonging to individual users cannot be used elsewhere.
On the other hand, although the notebook personal computer has the advantage that it can be carried, it is inconvenient to carry the notebook personal computer every time it goes out.

Therefore, as the Internet technology environment is fully developed and matured, the technology accompanying the development of the Internet is also gradually changing the habits and concepts of people's work, life and consumption.
Network magnetic storage is a new data storage technology that utilizes mature Internet communications and a centralized data storage center.
Since the user data is stored in the magnetic storage device of the network server, the user data is not stored in the magnetic storage device of the local computer, but the user can always connect to the network via the network simply by connecting the computer to the Internet. Access to personal data in magnetic storage.
However, network magnetic storage devices are limited in application, for example, the operating systems installed in different computers are not always the same, and the application programs installed in the computers are not all the same. There is.
In this case, there is a problem in reading user data.
For example, by designing a room plan with 3D image creation software and storing the room plan in the network magnetic storage device, the user can connect to the network magnetic storage device via the Internet using his computer, You can access the room plan stored in it.
However, if the user connects to the network magnetic storage device with a shared computer and the 3D image creation program is not installed in the shared computer, the indoor design drawing cannot be opened.
Therefore, although the network magnetic storage device can certainly access the data in the network magnetic storage device via the Internet at any time, the file cannot be edited, and the previous efforts may be wasted.

In many companies, related data such as office work, finance, sales, research and development is distributed and stored in dedicated computers of related employees, so these important data are centrally managed. Often become a blind spot or hole in data security.
Furthermore, when a company distributes a dedicated computer to each employee, an employee of the IT (Information Technology) department must install an operation system and an application program on the dedicated computer before distributing the computer. There are many things that must be done, and when the procedure is time consuming, a large amount of company costs and labor are wasted.

For this reason, a wide area communication network PC activation service (WAN Boot PC Service, WBPC service) has appeared on the market. The WBPC service is mainly a client / server (Client / Server) service structure, which is a wide area network start server (WAN Boot Server, WB server) and a wide area network start personal computer (WAN Boot PC, WBPC). ).
The hardware of the WBPC is almost the same as that of a general personal computer, but the WBPC is different in that it is not necessary to mount a magnetic storage device.
Magnetic storage devices used for WBPC are, for example, SCSI external magnetic storage array, Fiber Channel Storage Area Network (Fibre Channel SAN) magnetic storage device, or Internet. -It is connected to a magnetic storage device in the WB server by a communication protocol of iSCSI (Internet Small Computer System Interface) such as a protocol storage area network (IP SAN) magnetic storage device, etc. Alternatively, it is connected to a magnetic storage device outside the WB server.
Also, the feature of the iSCSI communication protocol is not a conventional file transmission unit, but a magnetic storage device transmission technology in units of blocks, so that the WB server accesses the magnetic storage device. Does not require a file system, and also eliminates the need to open a file.
For this reason, the data access method based on iSCSI has high access efficiency.
Since all of the WBPC operation system, application programs, and user data are stored in the magnetic storage device of the WB server, it is not necessary to mount a local magnetic storage device in the WBPC.

In addition, in order for the WBPC to be able to connect to the WB server by the iSCSI communication protocol, software or hardware for executing the iSCSI communication protocol must be included, and these software or hardware must be connected to the iSCSI device. being called.
The iSCSI device mainly processes magnetic storage device access commands issued by the operation system to the magnetic storage device, converts the commands into general IP network packets according to the iSCSI communication protocol, and transmits these packets via the network. To transmit to the WB server.
After receiving the packet, the WB server converts the packet into a magnetic storage device access command, and then accesses the magnetic storage device in the WB server based on the command.
After the access to the data is completed, the result of the data access is again packaged into an iSCSI packet by the WB server, converted into an IP packet, returned to the iSCSI device of the WBPC via the network, and sent by the iSCSI device. The result of the data access is fed back to the operation system.
Accordingly, the WBPC accesses the corresponding operation system, application program and user data in the WB server via the network.
In other words, the WBPC service allows users to use their personal data by downloading the operation system, application programs, and user data stored in the WB server onto the local WBPC, as long as the network is in place. In addition to being able to do so, the operating system environment becomes familiar to the user.
Therefore, in the WBPC service, the problem of carrying and the danger of data storage are fundamentally solved, the convenience is further improved, and it is not necessary to carry the computer by moving the work place.

In addition, when the IT department employees in the company manage computer facilities and distribute computers, it is possible to save the troublesome work of installing the operation system and application program for each computer. By operating only one WBPC and connecting to a WB server, an operation system and a desired application program can be installed in the WBPC.
The installed operation system and application program are stored in a magnetic storage device on the WB server.
A dedicated magnetic storage device for storing the operation system and application programs is called an operation system magnetic storage device.
As described above, the same operation system and application program can be acquired and used by sharing the operation system magnetic storage device in all WBPCs or WB servers. This makes it possible to use the WBPC service to greatly save the labor and time spent by IT department employees when installing operating systems and application programs.

In addition, data can be saved by the user in a magnetic storage device on the WB server.
When a user first connects to the WB server using WBPC, a virtual personal data magnetic storage device is placed on the magnetic storage device of the WB server so that the corresponding user stores the user data. Created.
This differs from the operation system magnetic storage device in that the personal data magnetic storage device is not shared but is completely for personal use, and all user data is stored centrally in the WB server. Therefore, the safety and stability of data can be improved.

Certainly, the WBPC service has the features of convenience and safety described above, but when starting each WBPC, it is connected to the operation system magnetic storage device on the WB server. By writing the data and receiving a response indicating that the writing has been completed, the WBPC operation system can continue working.
If there is no response, the operation system will stop working until there is a response indicating that writing has been completed.
However, if multiple WBPCs write data to the operation system magnetic storage device at the same time or if network communication is delayed, a long time is spent to complete the data writing operation on the operation system magnetic storage device. End up. In this case, transmission of the write end response to the WBPC is delayed, and the WBPC cannot perform the starting operation.

  Therefore, how to improve the startup efficiency of the WBPC service is a big issue that is expected to be solved.

  Therefore, a main object of the present invention is to provide a hard diskless computer system capable of improving the startup efficiency of a diskless computer by solving a data write delay caused by a delay in network communication and improving the startup efficiency of the diskless computer. It is in.

The main technical means employed to achieve the above object is that the hard diskless computer system is connected to a boot server provided with an operation system magnetic storage device,
A memory unit;
The operation unit kernel program and all data to be written to the operation system magnetic storage device are temporarily stored in the memory unit and a write completion response is sent to the operation system kernel program. And a central processing unit for executing a data cache program for writing the temporarily stored data into the operation system magnetic storage device.

Another main technical means employed to achieve the above object is that the hard diskless computer system is connected to a boot server provided with an operation system magnetic storage device, and
A memory unit;
A central processing unit connected to the memory unit and executing an operating system kernel program;
It is connected to the memory unit and the central processing unit, temporarily stores all data to be written to the operation system magnetic storage device in the memory unit, and transmits a write end response to the operation system kernel program. And a processing unit storing a data cache program for writing the temporarily stored data in the operation system magnetic storage device.

  Using the technical means described above, the operation system does not prevent the operation system from continuing normal operations because data is not written to the operation system magnetic storage device, and the operation system kernel program operates. By assuming that the data to be written to the system magnetic storage device has already been written, the user can continue to operate the operation system.

Please refer to FIG. This is a first embodiment of the hard diskless computer (10) of the present invention, and a central processing unit (21) and an operation system magnetic storage device (22) are provided via the Internet (30). Connected to the activation server (20).
In the central processing unit (21), an iSCSI service for converting / reversing an iSCSI (Internet Small Computer System Interface) packet is stored and connected to the central processing unit (21).
The operating system magnetic storage device (22) serves to store data related to the operating system.
The operation system magnetic storage device (22) is an IDE (Integrated Device Electronics) interface magnetic disk drive, a SCSI (Small Computer System Interface) magnetic disk drive, a SATA (Serial Advanced Technology magnetic disk attached) It may be a storage device array or a storage area network (SAN) magnetic storage device.
In this embodiment, the operation system magnetic storage device (22) is an external magnetic storage device array, and the hard diskless computer (10) includes a memory unit (11) and a central processing unit (12). ing.

The memory unit (11) is a main memory (not shown) originally provided in the hard diskless computer (10), for example, SDRAM (Synchronous Dynamic Random Access Memory) or DDR RAM (Double Data Rate Random Access Memory), etc. Alternatively, a separately mounted flash memory can be used.
In this embodiment, the memory unit (11) is a main memory originally provided in the hard diskless computer (10).

The central processing unit (12) is connected to the memory unit (11), and stores an operation system kernel program, a magnetic storage device command conversion program, an iSCSI initialization service, and a data cache program.
The operating system kernel program can send data write commands,
The magnetic storage device command conversion program sends a write / read command (I / O command) to the operation system magnetic storage device (22) in the central processing unit (12) and includes data to be written in the write command. The central processing unit (12) collectively converts the identification code indicating the write / read command and the operation system magnetic storage device (22) into the magnetic storage device write / read command,
iSCSI initialization service converts / reverses iSCSI packets and magnetic storage device write / read commands,
The data cache program temporarily stores all data to be written to the operation system magnetic storage device (22) in the memory unit (11), and transmits a write end response to the operation system kernel program.
The operating system kernel program assumes that the data has already been written to the operating system magnetic storage device (22), so that the user can continue to operate.
Then, when the network communication is successful, the data is written in the operation system magnetic storage device (22).
Also, if the data cache program receives the write command and the data to be written is the same as the data temporarily stored in the memory unit (11), it is temporarily stored in the memory unit (11). The data stored in is rewritten with the data to be written, and a write completion response is sent to the operation system kernel program.
If the data cache program receives a read command and there is already data to be acquired by the read command in the memory unit (11), the data in the memory unit (11) is read directly.

See also FIG. The detailed flow of the magnetic storage device command conversion program is as follows:
Obtaining a write / read command (100);
Determining whether to send a write / read command to the operating system magnetic storage device (101);
If not sent, the step (102) is terminated.
On the other hand, in the case of sending, it includes a step (103) of collectively converting the write / read command and the identification code indicating the operation system magnetic storage device into the magnetic storage device write / read command.

For the data cache program, refer to FIG. The detailed flow of the data cache program is
Obtaining a magnetic storage device write / read command converted through the magnetic storage device command conversion program (200);
Determining whether the identification code in the magnetic storage device write / read command indicates an operating system magnetic storage device (201);
If not shown, a step (202) of directly converting the magnetic storage device write / read command into an iSCSI packet by the iSCSI initialization service and transmitting the iSCSI packet to the activation server (20) via the Internet (30). When,
In the opposite case, the step (203) of determining whether or not the data of the magnetic storage device write / read command exists in the memory unit;
(1) If the data of the magnetic storage device write / read command does not exist in the memory unit (11), it is determined whether or not the magnetic storage device write / read command is a magnetic storage device write command. Step (204a);
If the command is not a write command, the iSCSI initialization service converts the magnetic storage device write / read command directly into an iSCSI packet, and sends the iSCSI packet to the activation server (20) via the Internet (30) (202). When,
On the other hand, if the command is a write command, the magnetic storage device write command temporarily stores data to be written to the operation system magnetic storage device in the memory unit (205);
A step (206) of sending a response to the end of writing to the operation system kernel program;
(2) If the data of the magnetic storage device write / read command exists in the memory unit (11), it is determined whether or not the magnetic storage device write / read command is a magnetic storage device write command. Step (204b);
If it is a magnetic storage device read command, a step (207) of reading data from the memory unit;
Furthermore, a step (208) of transmitting a read completion response to the operation system program;
If the command is a magnetic storage device write command, the step (209) of rewriting the data temporarily stored in the memory unit with the data to be written;
And (206) transmitting a write end response to the operation system kernel program.

See also FIG. The present invention further has a second embodiment.
Although the second embodiment is substantially the same as the first embodiment, the hard diskless computer (10) stores and executes a magnetic storage device command conversion program, an iSCSI initialization service, and a data cache program. The difference is that a host bus adapter (HBA) (101), which is further provided with a processing unit (102), is provided.

As can be understood from the above, the present invention temporarily stores and writes the data to be written to the magnetic storage device sent from the central processing unit by executing the operation system kernel program, and sends a response of the end of writing. Sent to the operation system kernel program without delay.
For this reason, the operation system kernel program assumes that the data has already been written to the operation system magnetic storage device, so that other operations can be continued.
As a result, the user feels that the write response of the operation system is extremely fast, and thus exceeds the speed of executing the operation system on a general computer with a hard disk.
Therefore, by using the technology of the present invention, even if a large number of hard diskless computers are started simultaneously, the startup procedure is completed quickly, and the startup time is much shorter than any remote startup technology in the industry.

  Although the present invention has already been disclosed in the above embodiments, the present invention is not limited to the contents mentioned in the above embodiments, and modifications and changes made without departing from the technical idea and scope of the present invention. Any addition is included in the protection scope of the present invention.

  To summarize the above, the present invention brings about a significant increase in effect and satisfies the requirements of the invention.

It is a functional block diagram of the 1st example concerning the present invention. It is a flowchart of the magnetic memory device command conversion program in the first embodiment according to the present invention. It is a flowchart of the data cache program in 1st Example based on this invention. It is a functional block diagram of the 2nd example concerning the present invention.

Explanation of symbols

(10) Hard diskless computer (11) Memory unit (12) Central processing unit (20) Startup server (21) Central processing unit (22) Operation system Magnetic storage device (30) Internet

Claims (16)

A hard diskless computer system,
The operation system is connected to a boot server provided with a magnetic storage device, and
A memory unit;
The operation unit kernel program and all data to be written to the operation system magnetic storage device are temporarily stored in the memory unit and a write completion response is sent to the operation system kernel program. And a central processing unit that executes a data cache program for writing the temporarily stored data in the operation system magnetic storage device,
A hard diskless computer system that can improve startup efficiency.   A magnetic storage device command conversion program is further stored in the central processing unit, and the magnetic storage device command conversion program sends a write / read command to the operation system magnetic storage device at the central processing unit and writes When the command includes data to be written, the central processing unit collectively converts the write / read command and the identification code indicating the operation system magnetic storage device into a magnetic storage device write / read command, 2. The hard diskless computer system capable of improving boot efficiency according to claim 1, wherein the data cache program is executed by the central processing unit. The magnetic storage device command conversion program is
Obtaining a write / read command;
Determining whether to send the write / read command to the operating system magnetic storage;
If not sent, the process ends; if sent in reverse, the write / read command and the operation system magnetic storage device identification code are collectively converted into a magnetic storage device write / read command; Including,
A hard diskless computer system capable of improving the startup efficiency according to claim 2. In the central processing unit, an iSCSI service for converting / reversing an iSCSI (Internet Small Computer System Interface) packet is stored.
Obtaining a magnetic storage device write / read command converted via the magnetic storage device command conversion program;
Determining whether the identification code in the magnetic storage device write / read command indicates an operating system magnetic storage device;
If not, the iSCSI initialization service converts the magnetic storage device write / read command directly into an iSCSI packet, and if indicated, the magnetic storage device write / read command is converted to a magnetic storage device. Determining whether it is a write command;
If not, the iSCSI initialization service converts the magnetic storage device write / read command directly into an iSCSI packet, and vice versa, the magnetic storage device write command is an operation system magnetic storage device. Temporarily storing data to be written into the memory unit, and sending a write end response to the operation system kernel program.
A hard diskless computer system capable of improving the startup efficiency according to claim 2 or 3.   When the data cache program further receives a read command, the data cache program first checks whether there is data to be read in the memory unit. If there is, the data cache program directly reads the data in the memory unit and ends reading. The hard diskless type computer system capable of improving the booting efficiency according to claim 1, wherein the response is transmitted to the operation system kernel program.   When the data cache program further receives a read command, the data cache program first checks whether there is data to be read in the memory unit. If there is, the data cache program directly reads the data in the memory unit and ends reading. 4. The hard diskless computer system capable of improving the booting efficiency according to claim 2, wherein the response is transmitted to an operation system kernel program. 5. In the central processing unit, an iSCSI service for converting / reversing an iSCSI packet is stored, and the data cache program is:
Obtaining a magnetic storage device write / read command converted via the magnetic storage device command conversion program;
Determining whether the identification code in the magnetic storage device write / read command indicates an operating system magnetic storage device;
If not shown, the iSCSI initialization service converts the magnetic storage device write / read command directly into an iSCSI packet, and vice versa, the magnetic storage device write / read command data is stored in the memory. Determining whether it exists in the unit;
(1) If the data of the magnetic storage device write / read command does not exist in the memory unit, the step of determining whether or not the magnetic storage device write / read command is a magnetic storage device write command When,
If it is not a write command, the magnetic storage device write / read command is directly converted into an iSCSI packet by the iSCSI initialization service;
On the other hand, if it is a write command, the magnetic storage device write command temporarily stores data to be written to the operation system magnetic storage device in the memory unit, and further sends a write completion response to the operation system kernel program. Steps,
(2) A step of determining whether or not the magnetic storage device write / read command is a magnetic storage device write command if data of the magnetic storage device write / read command exists in the memory unit. When,
If it is a magnetic storage device read command, reading data from the memory unit, and further sending a read end response to the operation system program;
If the command is a magnetic storage device write command, the step of rewriting the data temporarily stored in the memory unit with the data to be written, and further sending a write completion response to the operation system kernel program. Characterized by the
A hard diskless computer system capable of improving the startup efficiency according to claim 6.   2. The hard diskless computer system capable of improving start-up efficiency according to claim 1, wherein the memory unit is a main memory originally provided in the hard diskless computer or a flash memory separately mounted. A hard diskless computer system connected to an activation server provided with an operation system magnetic storage device,
A memory unit;
A central processing unit connected to the memory unit and executing an operating system kernel program;
It is connected to the memory unit and the central processing unit, temporarily stores all data to be written to the operation system magnetic storage device in the memory unit, and transmits a write end response to the operation system kernel program. And a processing unit storing a data cache program for writing the temporarily stored data in the operation system magnetic storage device.
A hard diskless computer system that can improve startup efficiency.   A magnetic storage device command conversion program is further stored in the processing unit, and the magnetic storage device command conversion program sends a write / read command to the operation system magnetic storage device at the central processing unit and a write command. When the data to be written is included, the processing unit collectively converts the write / read command and the identification code indicating the operation system magnetic storage device into a magnetic storage device write / read command. 10. The hard diskless computer system capable of improving start-up efficiency according to claim 9, wherein the data cache program is executed by a unit. The magnetic storage device command conversion program is
Obtaining a write / read command;
Determining whether to send the write / read command to the operating system magnetic storage;
If not sent, the process ends; if sent in reverse, the write / read command and the operation system magnetic storage device identification code are collectively converted into a magnetic storage device write / read command; Including,
A hard diskless computer system capable of improving the startup efficiency according to claim 10. In the processing unit, an iSCSI service for converting / reversing an iSCSI packet is stored, and the data cache program is:
Obtaining a magnetic storage device write / read command converted via the magnetic storage device command conversion program;
Determining whether the identification code in the magnetic storage device write / read command indicates an operating system magnetic storage device;
If not, the iSCSI initialization service converts the magnetic storage device write / read command directly into an iSCSI packet, and if indicated, the magnetic storage device write / read command is converted to a magnetic storage device. Determining whether it is a write command;
If the command is not a write command, the iSCSI storage service directly converts the magnetic storage device write / read command into an iSCSI packet, and conversely, if the command is a write command, the magnetic storage device write command is an operation system magnetic command. Temporarily storing data to be written to the storage device in the memory unit, and sending a response to the end of writing to the operation system kernel program.
12. A hard diskless computer system capable of improving the startup efficiency according to claim 10.   When the data cache program further receives a read command, the data cache program first checks whether there is data to be read in the memory unit. If there is, the data cache program directly reads the data in the memory unit and ends reading. The hard diskless computer system capable of improving the booting efficiency according to claim 9, wherein the response is transmitted to the operation system kernel program.   When the data cache program further receives a read command, the data cache program first checks whether there is data to be read in the memory unit. If there is, the data cache program directly reads the data in the memory unit and ends reading. 12. The hard diskless computer system capable of improving the booting efficiency according to claim 10 or 11, wherein the response to the operation system kernel program is transmitted. In the processing unit, an iSCSI service for converting / reversing an iSCSI packet is stored, and the data cache program is:
Obtaining a magnetic storage device write / read command converted via the magnetic storage device command conversion program;
Determining whether the identification code in the magnetic storage device write / read command indicates an operating system magnetic storage device;
If not shown, the iSCSI initialization service converts the magnetic storage device write / read command directly into an iSCSI packet, and vice versa, the magnetic storage device write / read command data is stored in the memory. Determining whether it exists in the unit;
(1) If the data of the magnetic storage device write / read command does not exist in the memory unit, the step of determining whether or not the magnetic storage device write / read command is a magnetic storage device write command When,
If it is not a write command, the magnetic storage device write / read command is directly converted into an iSCSI packet by the iSCSI initialization service;
On the other hand, if it is a write command, the magnetic storage device write command temporarily stores data to be written to the operation system magnetic storage device in the memory unit, and further sends a write completion response to the operation system kernel program. Steps,
(2) A step of determining whether or not the magnetic storage device write / read command is a magnetic storage device write command if data of the magnetic storage device write / read command exists in the memory unit. When,
If it is a magnetic storage device read command, reading data from the memory unit, and further sending a read end response to the operation system program;
If the command is a magnetic storage device write command, the step of rewriting the data temporarily stored in the memory unit with the data to be written, and further sending a write completion response to the operation system kernel program. Characterized by the
15. A hard diskless computer system capable of improving the startup efficiency according to claim 14.   10. The hard diskless computer capable of improving startup efficiency according to claim 9, wherein the memory unit is an SDRAM (Synchronous Dynamic Random Access Memory), a DDR RAM (Double Data Rate Random Access Memory), or a flash memory. system.

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