JP2008269177A - Information processor and control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information processor and an information control method for improving convenience when using a device in a virtualization platform technology for operating a plurality of virtual machines for OS. <P>SOLUTION: In an information processor equipped with a first virtual machine for executing a first operating system and a second virtual machine for executing a second operation system, either the first virtual machine or the second virtual machine is activated to be operable by a user. The first virtual machine is provided with a first device control part for recognizing a device operating only on the first operating system. This information processor is provided with a device detection part for, when a device is newly connected, detecting the connection signal of the device; a setting part for, when the connection signal is detected, activating the first virtual machine even when the second virtual machine is activated; and a device management part for starting the first device control part on the basis of the connection signal. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention includes a first virtual machine that executes a first operating system and a second virtual machine that executes a second operating system, and the user operates either the first virtual machine or the second virtual machine. The present invention relates to an information processing apparatus and a control method for setting a possible active state.

  Conventionally, a virtualization platform technology for executing a plurality of operating systems (hereinafter referred to as OSs) in an information processing apparatus such as a PC or a mobile phone has been proposed. In an information processing apparatus to which such a technique is applied, a plurality of logically divided OS virtual machines are provided, and each of these virtual machines for OS virtually executes a plurality of OSs so that a plurality of virtual machines for OS are virtually divided. An OS can be executed.

In recent years, a virtualization platform technology that can use a device (peripheral device) connected to the information processing apparatus described above in a plurality of OS virtual machines has been proposed (see, for example, Patent Document 1). In an information processing apparatus to which such a technique is applied, a device control unit that executes recognition processing as a device driver is provided in each OS virtual machine. When a new device is connected by the user, the OS virtual machine in the active state executes the device recognition process.
US Patent No: US6,496,847B1 “SYSTEM AND METHOD FOR VIRTUALZING COMPUTER SYSTEMS”

  However, in the above-described information processing apparatus, only the OS virtual machine in the active state executes the device recognition process.

  Therefore, when the newly connected device is, for example, a device dedicated to a specific OS, the device recognition process is not executed unless the virtual machine that executes the specific OS is in an active state. In other words, when a user connects a device to the information processing apparatus described above, the user can determine which OS virtual machine to connect to before the device is connected. I need to know. As described above, the information processing apparatus described above has a problem that it is very inconvenient for users who use various devices.

  Therefore, the present invention has been made in view of the above-described problems, and in the virtualization platform technology for operating a plurality of OS virtual machines, information processing that can improve convenience when using a device. An object is to provide an apparatus and a control method.

  In order to achieve the above object, a first feature of the present invention is that a first virtual machine (first OS virtual machine 110) that executes a first operating system and a second virtual machine (first virtual machine that executes a second operating system). 2OS virtual machine 120), and an information processing apparatus for setting one of the first virtual machine and the second virtual machine to an active state operable by a user, wherein the first virtual machine A first device control unit (virtual device control unit 111) that executes recognition processing of a device that operates only on the first operating system, and the connection of the device when the device is newly connected by a user A device detection unit (device detection unit 102) for detecting a signal, and when the connection signal is detected, the second temporary Even if the machine is in the active state, the first device control is performed based on the setting unit (active OS setting unit 106) that sets the first virtual machine to the active state and the detected connection signal of the device. And a device management unit (device management unit 104) for activating the unit.

  According to such a feature, when a device that operates only on the first operating system is newly connected, the information processing apparatus sets the first virtual machine to the active state even if the second virtual machine is in the active state. At the same time, the first device control unit that executes recognition processing for the connected device is activated. Therefore, in this information processing apparatus, the recognition process is not performed only on the active virtual machine device as in the conventional technique, but the recognition process is performed on the inactive virtual machine device. And the inactive virtual machine can be set to the active state. As described above, according to this feature, in the virtualization platform technology that operates a plurality of virtual machines (OS virtual machines), it is possible to improve convenience when using a device.

  The second feature of the present invention relates to the first feature, wherein the device is a human interface device that operates only on the first operating system, and a switching signal is detected when the human interface device is switched. A human interface device switching unit (human interface device switching unit 132) that performs the first virtual operation even when the second virtual machine is in the active state when the switching signal is detected. The gist of the invention is that the machine is set to an active state, and the device management unit starts the first device control unit based on the detected switching signal. According to such a feature, the information processing apparatus executes recognition processing of a human interface for a virtual machine in an inactive state even when switching a human interface that operates in one virtual machine, thereby improving convenience. Can do.

  A third feature of the present invention relates to the first feature, wherein the second virtual machine executes a second device control unit (virtual device control unit) that executes recognition processing for a device that operates only on the second operating system. 121), and the device operates on the first operating system or the second operating system that is executed in one of the active state of the first virtual machine or the second virtual machine. The device detecting unit detects the connection signal of the interlocking device when the interlocking device is connected, and the device management unit is configured to detect the first virtual machine or the device based on the connection signal. The first device control unit or the second device provided in any one of the active states of the second virtual machine. The gist is to start the vice controller. According to such a feature, in the information processing apparatus, even if the connected device is a device operated by an active virtual machine among a plurality of virtual machines, the information processing apparatus can detect this and execute recognition processing. it can.

  A fourth feature of the present invention relates to the first feature, wherein the device is an unlinked device that operates on both the first operating system and the second operating system, and the device detection unit includes: When the non-link device is connected, the connection signal of the non-link device is detected, and the device management unit detects the first device control unit and the second device control unit based on the connection signal. The gist is to start up. According to this feature, in the information processing apparatus, even if the connected device is a device that operates on a plurality of virtual machines, the information processing apparatus can detect this and execute recognition processing.

  A fifth feature of the present invention relates to the fourth feature, wherein first data (for example, an access request 511) transmitted and received between the first virtual machine and the unlinked device, and the second virtual machine. And an access control unit (direct memory access control unit 203) for transferring second data (for example, access request 521) transmitted / received between the device and the non-linked device by a direct memory access method, The gist of the invention is that when the first virtual machine is in the active state, the transfer ratio of the first data is made larger than the transfer ratio of the second data. According to this feature, in the information processing apparatus, the transfer ratio of the first data transmitted from the active virtual machine is set to be larger than the transfer ratio of the second data transmitted from the inactive virtual machine. Therefore, it is possible to improve the processing efficiency of the active virtual machine used by the user and improve the convenience when the user uses the information processing apparatus.

  According to a sixth aspect of the present invention, there is provided a first virtual machine that executes a first operating system and a second virtual machine that executes a second operating system, wherein the first virtual machine and the second virtual machine A control method in an information processing apparatus for setting either one to an active state operable by a user, wherein the first virtual machine executes a recognition process for a device that operates only on the first operating system. A detection step of detecting a connection signal of the device when the device is newly connected by a user; and when the connection signal is detected, the second virtual machine is in the active state. Even if there is a setting step for setting the first virtual machine to an active state and the detected connection signal And Zui, it is an gist in that it comprises a starting step that starts the first device controller.

  According to the present invention, it is possible to provide an information processing apparatus and a control method capable of improving convenience when using a device in a virtualization platform technology for operating a plurality of OS virtual machines.

Next, embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic.

[Embodiment]
(Configuration of information processing device)
A configuration of the information processing apparatus according to the embodiment of the present invention will be described. The information processing apparatus according to the embodiment of the present invention is assumed to be a terminal apparatus such as a PC, a mobile phone, or a PDA. The information processing apparatus 1 according to the present embodiment includes a first OS virtual machine (first virtual machine) and a second OS virtual machine (second virtual machine) that executes a second operating system. One of the virtual machine for the OS and the virtual machine for the second OS is set to an active state that can be operated by the user, and the operating environment of the first or second operating system (hereinafter referred to as OS) is provided to the user. The first OS and the second OS may be different types of OSs such as Linux and Windows, or may be the same type of OS.

  Specifically, as illustrated in FIG. 1, the information processing apparatus 1 according to the present embodiment includes a plurality of devices 10_1 to 10_n, a hardware unit 300, a virtual machine control unit 200, and a general-purpose interface virtual machine 100. The first OS virtual machine 110 that executes the first operating system, the second OS virtual machine 120 that executes the second operating system, and the human interface virtual machine 130 are provided.

  The devices 10_1 to 10_n include a communication unit 11, a storage unit 12, and a control unit 13, as illustrated in FIG. In the present embodiment, devices 10_1 to 10_n will be described as devices 10 as appropriate. The device 10 is a device connected to the hardware unit 300, and corresponds to, for example, a USB (Universal Serial Bus) device. The communication unit 11 communicates with the hardware unit 300. The storage unit 12 is a storage device such as a memory. The control unit 13 controls various functions in the device 10. For example, when the device 10 is a USB, the communication unit 11 corresponds to a USB target controller, and the control unit 13 corresponds to a USB controller drive.

  In the present embodiment, the plurality of devices 10 include active devices that operate only on one of the first OS and the second OS, the first OS virtual machine 110, and the second OS virtual machine 120. Examples include a linked device that operates on the first OS or the second OS that is executed in any one of the states, and an unlinked device that operates on both the first OS and the second OS. Examples of the occupied device include a user authentication device. Examples of the interlocking device include a human interface device such as a keyboard, a display, and a mouse. Examples of the non-linked device include a storage and a network. Note that it is possible to freely set in advance whether one device 10 corresponds to an occupied device, a linked device, or a non-linked device.

  As shown in FIG. 3, the hardware unit 300 includes a communication unit 301, a central processing unit 302, and a main storage unit 303. The communication unit 301 performs communication with the device 10 and the virtual machine control unit 200. The central processing unit 302 corresponds to an arithmetic processing circuit such as a CPU. The main storage unit 303 corresponds to a main memory.

  The virtual machine control unit 200 controls the general-purpose interface virtual machine 100, the first OS virtual machine 110, the second OS virtual machine 120, and the human interface virtual machine 130. As illustrated in FIG. 4, the virtual machine control unit 200 includes a communication unit 201, a direct memory access policy unit 202, and a direct memory access control unit 203.

  The communication unit 201 communicates with the general-purpose interface virtual machine 100, the first OS virtual machine 110, the second OS virtual machine 120, the human interface virtual machine 130, and the hardware unit 300.

  The direct memory access policy unit 202 includes an access policy table T1 as shown in FIG. In the access policy table T1, the type of the device 10, the ID for identifying the device 10, information indicating whether or not the device is in the active state, the scheduling ratio, and the VM state information indicating the currently active virtual machine are associated with each other. Stored in advance. The scheduling ratio is information indicating a ratio when data is transferred by the direct memory access method. The VM state information is information that is updated by the active OS setting unit 106 described later every time the active state transitions to either the first OS virtual machine 110 or the second OS virtual machine 120. Of the information stored in the access policy table T1, information other than the VM state information is set in advance. Information stored in the access policy table T1 is used by the direct memory access control unit 203 described later.

  The direct memory access control unit 203 receives a direct memory access request (first data) transmitted / received between the first OS virtual machine 110 and the unlinked device, and the second OS virtual machine 120 and the unlinked device. It functions as an access control unit that transfers a direct memory access request (second data) transmitted and received between them by the direct memory access method. Specifically, as shown in FIG. 6, the direct memory access control unit 203 includes an access request queue 510 that stores the access requests 511 to 512 transmitted from the first OS virtual machine 110, and a second OS virtual machine 120. An access request queue 520 that stores the transmitted access requests 521 to 523 and a scheduling unit 600 are provided.

  The scheduling unit 600 refers to the access policy table T1 of the direct memory access policy unit 202, and determines the access request from the first OS virtual machine 110 and the second OS virtual machine 120 according to the stored scheduling ratio. The scheduling for transferring the access request to the device 10 by the direct memory access method is determined. In addition, the scheduling unit 600 instructs the central processing unit 302 to execute the transfer process of the access request based on the determined scheduling. For example, in FIG. 5, when the device 10 is “storage”, the first OS virtual machine 110 is in an active state, and the second OS virtual machine 120 is in an inactive state, access from the first OS virtual machine 110 is performed. Requests and access requests from the second OS virtual machine 120 are scheduled by time sharing at a ratio of “7: 3”, and the access requests 511 to 512 from the active first OS virtual machine 110 are prioritized. To transfer. As described above, in the direct memory access control unit 203, when the first OS virtual machine 110 is in the active state, the access request transfer ratio is made larger than the access request transfer ratio to transfer the access request. It is configured.

  As illustrated in FIG. 7, the first OS virtual machine 110 includes a virtual device control unit 111 and a program unit 112. The virtual device control unit 111 is connected to the device control unit 103 of the later-described general-purpose interface virtual machine 100 and functions as a front-end device driver of the device control unit 103. Further, when the first OS of the first OS virtual machine 110 is executed, the virtual device control unit 111 directly transmits an access request transmitted to the device 10 to the memory access control unit 203. In the present embodiment, the virtual device control unit 111 configures a first device control unit that executes recognition processing for the device 10 that operates only on the first operating system. The program unit 112 stores various software in advance, and activates various software (code and program) such as the first OS. The program unit 112 activates a program corresponding to the type of the device 10 to be connected.

  As illustrated in FIG. 8, the second OS virtual machine 120 includes a virtual device control unit 121 and a program unit 122. The functions of the virtual device control unit 121 and the program unit 122 are substantially the same as the functions of the virtual device control unit 111 and the program unit 112 described above, and thus the description thereof is omitted. In the present embodiment, the virtual device control unit 121 configures a second device control unit that executes recognition processing for a device that operates only on the second operating system.

  As shown in FIG. 9, the general-purpose interface virtual machine 100 includes a communication unit 101, a device detection unit 102, a device control unit 103, a device management unit 104, an OS selection information storage unit 105, and an active OS setting unit 106. With.

  The communication unit 101 communicates between the human interface virtual machine 130, the first OS virtual machine 110, the second OS virtual machine 120, and the virtual machine control unit 200.

  For example, when the connected device 10 is a USB, the device detection unit 102 corresponds to a USB bus driver. Further, the device detection unit 102 detects a connection signal of the device 10 when the device 10 is newly connected by the user. Further, the device detection unit 102 detects a connection signal of the interlocking device when the interlocking device is connected. Further, the device detection unit 102 detects a connection signal of the non-linked device when the non-linked device is connected. Specifically, the device detection unit 102 detects a connection signal transmitted from the hardware unit 300 when the device 10 such as an occupied device, a linked device, or a non-linked device is connected to the hardware unit 300. The device management unit 104 is notified of the identification information of the device 10 included in the connection signal.

  The device control unit 103 functions as a class driver for each type of device 10 to be connected. Further, in response to an instruction from the device management unit 104, the virtual device control units 111 to 121 are activated.

  The OS selection information storage unit 105 includes an OS selection information table T2 as shown in FIG. The OS selection information table T2 includes the type of the device 10 to be connected, the vendor ID that identifies the provider of the device 10, the identification information that identifies the device 10, and the OS virtual machines 110 to 110 that operate the respective devices 10. A VM number for identifying 120 and device control information indicating control contents when the device 10 is connected or switched are stored in advance in association with each other.

  Here, the VM number is preset as “1” for the first OS virtual machine 110 and “2” for the second OS virtual machine 120. The device control information includes “occupied” and “shared”, and “shared” includes “linked” and “not linked”. “Occupied” indicates that the associated device 10 operates only on a single OS virtual machine. “Shared” indicates that the associated device 10 operates in a plurality of OS virtual machines. “Interlocked” indicates that the associated device 10 is operated by an active OS virtual machine. “Non-interlocking” indicates that the associated device 10 is operated by the OS virtual machine corresponding to the VM number regardless of whether it is in an active state.

  The device management unit 104 activates the virtual device control unit 111 of the first OS virtual machine 110 based on the connection signal of the device 10 detected by the device detection unit 102. In addition, when the interlocking device is connected, the device management unit 104 determines which of the active statuses of the first OS virtual machine 110 or the second OS virtual machine 120 based on the connection signal detected by the device detection unit 102. The virtual device control unit 111 or the virtual device control unit 121 provided in either of them is activated. In addition, when an unlinked device is connected, the device management unit 104 activates the virtual device control unit 111 and the virtual device control unit 121 based on the connection signal detected by the device detection unit 102.

  Specifically, when the device management unit 104 is notified of the identification information of the connected device 10 from the device detection unit 102, the device management unit 104 refers to the OS selection information table T2 and “device control information” corresponding to the identification information. The OS virtual machine that executes the recognition process of the connected device 10 is specified based on whether “Occupied”, “Shared (linked)”, or “Shared (not linked)”. In addition, the device management unit 104 instructs the device control unit 103 to activate the virtual device control units 111 to 121 included in the identified OS virtual machine.

  In addition, when the user interface device (hereinafter, appropriately shown as HID) is switched by the user, the device management unit 104 detects the switching signal by the human interface device switching unit 132 described later, based on the switching signal. Then, the virtual device control unit 111 or the virtual device control unit 121 is activated. Specifically, for example, when the second OS virtual machine 120 is currently in an active state, the device management unit 104 detects a switching signal by the HID switching unit 132, and from the HID switching unit 132, the device management unit 104 detects the first inactive state. When the identification information of the HID that operates only by the 1OS virtual machine 110 is notified, the OS selection information table T2 is referred to and the first OS virtual machine is referred to, as in the case where the device detection unit 102 detects the connection signal. The virtual device control unit 111 of 110 is activated.

  In addition, when the virtual device control units 111 to 121 are activated, the device management unit 104 notifies the active OS setting unit 106 to set the switching of the active state when switching the active state of the OS virtual machine. .

  When the second OS virtual machine 120 is in the active state, the active OS setting unit 106 detects the connection signal of the device 10 that operates only in the inactive first OS virtual machine 110 and detects the second OS virtual machine 120. Even if the machine 120 is in the active state, the first OS virtual machine 110 is set to the active state. As for the switching signal, the active OS setting unit 106 can detect whether the second OS virtual machine 120 is in an active state when an HID switching signal that operates only in the inactive first OS virtual machine 110 is detected. The first OS virtual machine 110 is set to an active state.

  Specifically, when the active OS setting unit 106 receives a notification from the device management unit 104 to switch the active state of the OS virtual machine, the active OS setting unit 106 sets switching of the active state. Note that the active OS setting unit 106 updates the VM state information stored in the access policy table T1 when the active state is switched. In the present embodiment, the active OS setting unit 106 configures a setting unit that sets one of the first OS virtual machine 110 and the second OS virtual machine 120 to an active state that can be operated by the user.

  As shown in FIG. 11, the human interface virtual machine 130 includes a communication unit 131, a human interface device switching unit 132 (hereinafter referred to as an HID switching unit 132), and a human interface device management unit 133 (hereinafter referred to as an HID management unit). 133).

  The communication unit 131 communicates between the general-purpose interface virtual machine 100, the first OS virtual machine 110, the second OS virtual machine 120, and the virtual machine control unit 200.

  The HID switching unit 132 detects a switching signal of the switched HID when the HID is switched by the user. For example, when a plurality of displays are connected as HID, the user switches the HID when performing a switching operation to use another display from one display in order to operate an active virtual machine. The unit 132 detects this switching signal. The switching signal includes identification information of another display to be switched to, and the device detection unit 102 notifies the HID management unit 133 of this identification information.

  The HID management unit 133 manages the usage state of the connected human interface device. The HID management unit 133 notifies the device management unit 104 of HID identification information notified from the HID switching unit 132 when the HID switching unit 132 detects a switching signal.

(Operation of Information Processing Device According to Embodiment)
Next, the operation of the information processing apparatus 1 configured as described above will be described. Specifically, the control operation when a new device is connected to the information processing apparatus 1 by the user and the control operation when executing DMA transfer with an unlinked device recognized by a plurality of virtual machines will be described. .

(Control action when a new device is connected)
First, the control operation of the information processing apparatus 1 when a new device 10 is connected to the information processing apparatus 1 will be described with reference to FIG.

  In step S101, the device detection unit 102 detects a connection signal indicating that a new device 10 has been connected. In addition, the device detection unit 102 notifies the device management unit 104 of identification information included in the detected connection signal.

  In step S102, the device management unit 104 refers to the OS selection information table T2 and identifies the type of device from the notified identification information.

  In step S103, the device management unit 104 instructs the device control unit 103 to activate the class driver corresponding to the identified type, and the device control unit 103 activates the class driver.

  In step S104, the device management unit 104 refers to the OS selection information table T2, and determines whether the device control information corresponding to the notified identification information is “occupied” or “shared”.

  In step S <b> 105, if the device management unit 104 determines that it is “occupied”, the device management unit 104 specifies the virtual device control unit 111 or the virtual device control unit 121 based on the “VM number” stored in association therewith. For example, when the virtual device control unit 111 is specified, the device management unit 104 instructs the device control unit 103 to activate the virtual device control unit 111. Upon receiving this instruction, the device control unit 103 activates the virtual device control unit 111 to execute recognition processing for the connected device 10. At this time, the device management unit 104 instructs the active OS setting unit 106 to activate the first OS virtual machine 110 including the virtual device control unit 111.

  In step S <b> 106, if the device management unit 104 determines that it is “shared”, it continues to determine whether it is “linked” or “non-linked”.

  In step S107, if the device management unit 104 determines that it is “linked”, it checks the active OS virtual machine with the active OS setting unit 106, and the active OS virtual machine (for example, the second OS) The device control unit 103 is instructed to start the virtual device control unit (for example, the virtual device control unit 121) of the virtual machine 120). Upon receiving this instruction, the device control unit 103 activates a virtual device control unit (for example, the virtual device control unit 121), and executes recognition processing for the connected device 10.

  In step S <b> 108, if the device management unit 104 determines that it is “non-linked”, the virtual device control units 111 to 121 are activated based on the “VM number” stored in association with each other. The device control unit 103 is instructed. Upon receiving this instruction, the device control unit 103 activates the virtual device control units 111 to 121 and executes recognition processing for the connected device 10.

  In step S109, for example, when receiving an instruction from the device management unit 104 to set the first OS virtual machine 110 to the active state, the active OS setting unit 106 confirms the currently active OS virtual machine and sets the OS It is determined whether the active state of the virtual machine needs to be switched.

  In step S110, for example, when the active OS setting unit 106 determines that the second OS virtual machine 120 is in the active state and needs to be switched, the active OS setting unit 106 sets the first OS virtual machine 110 to the active state. Note that the active OS setting unit 106 does not execute anything when there is no need to switch.

  In step S111, the program units 112 to 122 execute desired software (program or code) in response to activation of the virtual device control units 111 to 121 or switching of the active state.

  When the HID is switched, in step S101 described above, in the human interface virtual machine 130, the HID switching unit 132 detects the switching signal, and the HID management unit 133 detects the HID identification information included in the switching signal. Notify In addition, the HID management unit 133 notifies the device management unit 104 of the identification information, and thereafter, the information processing apparatus 1 executes the processes of steps S102 to S111 described above.

(Control operation when executing DMA transfer with an unlinked device)
Next, the DMA transfer control operation executed in the information processing apparatus 1 after steps S108 to S111 determined by the device management unit 104 as “non-interlocking” will be specifically described with reference to FIG.

  In step S301, when the device management unit 104 determines that it is “non-linked”, the active OS virtual machine is set in the active OS setting unit 106 based on the “VM number” stored in association therewith. Check and identify this. The device management unit 104 is connected to an active OS virtual machine (for example, the first OS virtual machine 110) and an inactive OS virtual machine (for example, the second OS virtual machine 120). The identification information of the device 10 is notified directly to the memory access control unit 203.

  In step S302, in the direct memory access control unit 203 that has received this notification, the scheduling unit 600 refers to the access policy table T1, and based on the notified identification information, determines the scheduling ratio in the active state and the inactive state. Check the scheduling ratio.

  In step S303, the direct memory access control unit 203 receives the direct memory access request transmitted from the program unit 112 or 122. In the direct memory access control unit 203, the access request queue 510 or 520 holds this access request. In addition, the scheduling unit 600 performs scheduling by time sharing according to the confirmed scheduling ratio, and determines a queue to be processed.

  In step S304, when the queue to be processed is an access request transmitted from the program unit 112, the scheduling unit 600 processes the access request 511 in the access request queue 510.

  In step S305, when the queue to be processed is an access request transmitted from the program unit 122, the scheduling unit 600 processes the access request 521 in the access request queue 520.

  In step S306, the scheduling unit 600 continues the processing until there are no access requests held in the access request queues 510 to 520. Even if the access request temporarily disappears, the direct memory access control unit 203 repeatedly executes the above process when it is transmitted again.

(Function and effect)
As described above, in the information processing apparatus according to the present embodiment, for example, when the device 10 (occupied device) that operates only on the first operating system is newly connected, the second OS virtual machine 120 is in the active state. Even so, the first OS virtual machine 110 is set to the active state, and the first device control unit that executes recognition processing for the connected device is activated. Therefore, in the information processing apparatus 1, when the device 10 is newly connected as in the prior art, the recognition process is not performed only by the active OS virtual machine device 10, but in the inactive state. Recognition processing can also be executed for the OS virtual machine device 10. Further, the information processing apparatus can set the OS virtual machine that operates the device 10 to an active state if the OS virtual machine is in an inactive state. The information processing apparatus 1 can also execute related software in the OS virtual machine whose active state is switched.

  In addition, the information processing apparatus 1 according to the present embodiment can execute recognition processing of a human interface for an inactive virtual machine even when switching between HIDs operating on one OS virtual machine. In the information processing apparatus 1 according to the present embodiment, the connected device is the device 10 (interlocking device) that is operated by the active OS virtual machine among the plurality of first and second OS virtual machines. Even if this is detected, the recognition process can be executed. Further, in the information processing apparatus 1 according to the present embodiment, even if the connected device is a device 10 (non-linked device) that operates on a plurality of OS virtual machines, this is detected and recognition processing is executed. be able to. As described above, according to the information processing apparatus 1, in the virtualization platform technology that operates a plurality of virtual machines (OS virtual machines), it is possible to improve convenience when using a device.

  Further, in the information processing apparatus 1 according to the present embodiment, the transfer ratio of the access request transmitted from the active OS virtual machine is higher than the transfer ratio of the access request transmitted from the inactive OS virtual machine. Enlarge. Therefore, it is possible to improve the processing efficiency of the active OS virtual machine used by the user and to improve the convenience when the user uses the information processing apparatus 1.

[Other embodiments]
Although the present invention has been described according to the above-described embodiments, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  For example, in the above-described embodiment, the functions of the device detection unit 102, the device control unit 103, the device management unit 104, the OS selection information storage unit 105, and the active OS setting unit 106 are the virtual machine control unit 200. It may be configured to prepare for. In particular, the OS selection information storage unit 105 may be configured to be included in the first OS virtual machine 110, the second OS virtual machine 120, and the like.

  In the above-described embodiment, the information processing apparatus 1 is configured to include the first OS virtual machine 110 and the second OS virtual machine 120 as the OS virtual machines. However, the present invention is not limited to this.

  As described above, the present invention naturally includes various embodiments not described herein. Therefore, the technical scope of the present invention is defined only by the invention specifying matters according to the scope of claims reasonable from the above description.

1 is a diagram illustrating an overall schematic configuration of an information processing apparatus according to an embodiment. It is a figure which shows the structure of the device which concerns on embodiment. It is a figure which shows the structure of the hardware part which concerns on embodiment. It is a figure which shows the structure of the virtual machine which concerns on embodiment. It is a figure which shows the access policy table which concerns on embodiment. It is a figure which shows the structure of the virtual direct memory access control part which concerns on embodiment. It is a figure which shows the structure of the virtual machine for OS which concerns on embodiment. It is a figure which shows the structure of the virtual machine for OS which concerns on embodiment. It is a figure which shows the structure of the virtual machine for general purpose interfaces which concerns on embodiment. It is a figure which shows the OS selection information table which concerns on embodiment. It is a figure which shows the structure of the virtual machine for human interfaces which concerns on embodiment. It is a flowchart which shows operation | movement of the information processing apparatus which concerns on embodiment. It is a flowchart which shows operation | movement of the information processing apparatus which concerns on embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Information processing apparatus, 10_1 thru | or 10_n ... Device, 11 ... Communication part, 12 ... Memory | storage part, 13 ... Control part, 100 ... Virtual machine for general purpose interfaces, 101 ... Communication part, 102 ... Device detection part, 103 ... Device control 104, device management unit, 105 ... OS selection information storage unit, 106 ... active OS setting unit, 110 ... first OS virtual machine, 111 ... virtual device control unit, 112 ... program unit, 120 ... second OS virtual machine , 121 ... Virtual device control unit, 122 ... Program unit, 130 ... Human interface virtual machine, 131 ... Communication unit, 132 ... Human interface device switching unit, 133 ... Human interface device management unit, 200 ... Virtual machine control unit, 201 ... communication unit, 202 ... direct memory access Policy unit 203 ... Direct memory access control unit 300 ... Hardware unit 301 ... Communication unit 302 ... Central processing unit 303 ... Main storage unit 510 ... Access request queue 510,520 ... Access request queue 510 520 ... access request queue, 511-512 ... access request, 521-523 ... access request, 600 ... scheduling unit, T1 ... access policy table, T2 ... OS selection information table, S101 to S111 ... step, S301 to S306 ... step ,

Claims (6)

A first virtual machine that executes a first operating system and a second virtual machine that executes a second operating system are provided, and one of the first virtual machine and the second virtual machine can be operated by a user An information processing apparatus that sets an active state,
The first virtual machine includes a first device control unit that executes recognition processing of a device that operates only on the first operating system,
A device detection unit that detects a connection signal of the device when the device is newly connected by a user;
A setting unit configured to set the first virtual machine to an active state even when the second virtual machine is in the active state when the connection signal is detected;
An information processing apparatus comprising: a device management unit that activates the first device control unit based on the detected connection signal of the device. The device is a human interface device that operates only on the first operating system;
A human interface device switching unit for detecting a switching signal when the human interface device is switched;
When the switching signal is detected, the setting unit sets the first virtual machine to an active state even if the second virtual machine is in the active state,
The information processing apparatus according to claim 1, wherein the device management unit activates the first device control unit based on the detected switching signal. The second virtual machine includes a second device control unit that executes recognition processing of a device that operates only on the second operating system.
The device is an interlocking device that operates on the first operating system or the second operating system that is executed in one of the active states in the first virtual machine or the second virtual machine,
The device detection unit detects the connection signal of the interlock device when the interlock device is connected,
Based on the connection signal, the device management unit includes the first device control unit or the second device provided in either the first virtual machine or the second virtual machine in the active state. The information processing apparatus according to claim 1, wherein the control unit is activated. The device is an unlinked device that operates on both the first operating system and the second operating system;
The device detection unit detects the connection signal of the non-linked device when the non-linked device is connected,
The information processing apparatus according to claim 1, wherein the device management unit activates the first device control unit and the second device control unit based on the connection signal. The first data transmitted / received between the first virtual machine and the non-linked device and the second data transmitted / received between the second virtual machine and the non-linked device by a direct memory access method. Further comprising an access control unit for forwarding,
5. The access control unit according to claim 4, wherein when the first virtual machine is in the active state, the transfer ratio of the first data is made larger than the transfer ratio of the second data. Information processing device. A first virtual machine that executes a first operating system and a second virtual machine that executes a second operating system are provided, and one of the first virtual machine and the second virtual machine can be operated by a user A control method in an information processing apparatus for setting an active state,
The first virtual machine includes a first device control unit that executes recognition processing of a device that operates only on the first operating system,
A detection step of detecting a connection signal of the device when the device is newly connected by a user;
A setting step for setting the first virtual machine to an active state even when the second virtual machine is in the active state when the connection signal is detected;
And a starting step of starting the first device control unit based on the detected connection signal.

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