标签:des style blog http tar ext
BACKGROUND
Virtualization technology enables a single host computer running a virtual machine monitor ("VMM") to present multiple abstractions and/or views of the host, such that the underlying hardware of the host appears as one or more independently operating virtual machines ("VMs"). Each VM may function as a self-contained platform, running its own operating system ("OS") and/or a software application(s). The VMM manages allocation and virtualization of host resources, and performs context switching as necessary to cycle between various virtual machines according to a round-robin or other scheduling algorithms.
Given the complexity and processing requirements of virtualization, this technology has typically been available only on workstations, servers and/or mainframes for use by sophisticated users. As processor technology advances, however, virtualization is being made available in the desktop environment for use by average users.
DETAILED DESCRIPTION
Embodiments of the present invention provide a method, apparatus and system for transparently unifying multiple virtual machines ("VMs") on a host. More specifically, a unification console on a host may be dedicated to providing a user with a unified view of the multiple VMs on the host, regardless of the application the user is running and/or the VM in which the application is running. In one embodiment the unification console could itself be a VM. Reference in the specification to "one embodiment" or "an embodiment" of the present invention means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of the phrases "in one embodiment," "according to one embodiment" or the like appearing in various places throughout the specification are not necessarily all referring to the same embodiment.
As previously described, virtualization is becoming more commonly available in the desktop environment. In this environment, the most likely users are unlikely to be computer professionals (e.g., information technology specialists in corporate environments) but rather less sophisticated users (e.g., home personal computer ("PC") users and/or non-technical, less sophisticated corporate users). The applications that run within the desktop environment and the types of uses for the applications may also differ from corporate applications. For example, one use of virtualization in a home (and the associated advantage of running one or more independent VMs on a host) may be for each family member to be allocated a VM partition with their own customized environment, e.g., a gaming VM partition, a Personal Video Recorder ("PVR") appliance VM, an enterprise Information Technology ("IT") supplied VM for telecommuting, etc. Moreover, it is likely that each user may have several VMs, each possibly dedicated for a specific task such as a dedicated VM for internet browsing, one for gaming applications, etc. Some might be scheduled to run 24×7 (e.g. a personal video recorder ("PVR)), while others are launched and exited frequently. In this environment, the average home PC user may be overwhelmed by the task of understanding and/or managing the VM partitions (e.g., moving files, setting up access permissions, etc.).
FIG. 1 illustrates an example of a typical virtual machine host platform ("Host?100"). As previously described, a virtual-machine monitor ("VMM?130") typically runs on the host platform and presents an abstraction(s) and/or view(s) of the platform (also referred to as "virtual machines" or "VMs") to other software. Although only two VM partitions are illustrated ("VM?110" and "VM?120", hereafter referred to collectively as "VMs"), these VMs are merely illustrative and additional virtual machines may be added to the host. VMM?130?may be implemented in software (e.g., as a standalone program and/or a component of a host operating system), hardware, firmware and/or any combination thereof.
VM?110?and VM?120?may function as self-contained platforms respectively, running their own "guest operating systems" (i.e., operating systems hosted by VMM?130, illustrated as "Guest OS?111" and "Guest OS?121" and hereafter referred to collectively as "Guest OS") and other software (illustrated as "Guest Software?112" and "Guest Software?122" and hereafter referred to collectively as "Guest Software"). Each Guest OS and/or Guest Software operates as if it were running on a dedicated computer. That is, each Guest OS and/or Guest Software may expect to control various events and have access to hardware resources on Host?100. The VMM need not just project a representation of the physical platform or give direct access to resources. The VMM may also create new virtual devices (e.g. a network interface card ("NIC")) while possibly using Host?100‘s processor and similar devices (e.g., another NIC) on Host?100?to emulate those virtual devices. The virtual platform presented to a given VM by VMM?130?may be a hybrid of virtual and physical elements. Therefore, within each VM, the Guest OS and/or Guest Software may behave as if they were, in effect, running on the virtual platform hardware, supported by the VMM?130. In reality however, VMM?130?has ultimate control over the events and hardware resources (which may be physical or virtual as created by VMM?130), and allocates resources to the VMs according to its own policies. Recursive or layered VM schemes may also be possible, e.g., VM?110?may host another virtual host (which may appear to have behaviors like physical Host?100?or some other virtual host platform, or a hybrid platform.) These types of recursive schemes are well known to those of ordinary skill in the art and further description thereof is omitted herein in order not to unnecessarily obscure embodiments of the present invention.
In order to access applications running on the various VMs on a VM host, a user typically has to know which VM the application is running in and manually switch to the appropriate VM. Thus, for example, if the user desires to play a video game (e.g., Guest Software?112?running on VM?110), the user has to manually select VM?110, find the application and launch the game. Thereafter, if the user desires to access another application (e.g., Guest Software?122?running on VM?120), the user has to determine which VM the application is running in and manually switch to that VM in order to run the application. Although switching between VMs may not be especially cumbersome (e.g., a keystroke to switch from one VM to another), keeping track of what applications are running on each VM may prove to be difficult, especially if the host is configured to run more than two VMs (as is likely). For a home PC user, keeping track of the various partitions that are running on his or her PC and/or the applications running in each partition may prove to be highly complex. The typical home PC user may not be technically savvy enough to understand the underlying view of the VM host and as a result, may have difficulties and/or shy away from fully utilizing a host running multiple VMs.
Embodiments of the present invention provide a method, apparatus and system for transparently unifying multiple VMs on a host. More specifically, according to an embodiment of the present invention, users may interact with Guest Software on a VM host via a unified graphical user interface (the user interface hereafter referred to as "Unified Desktop Interface?200"). As illustrated in FIG. 2, the user may be presented with Unified Desktop Interface?200, which is a logical representation of the views of all or a subset of the various VMs on Host?100?such that the user can see and/or launch applications in one or more VMs from this view. In various embodiments, the view presented to the user may resemble a typical desktop, but unknown to the user, the desktop may in fact represent applications contained in various VMs on the host. In one embodiment, the user‘s view of Unified Desktop Interface?200?may include all applications available to the user. Thus, for example, if the user has access to all the VMs on Host?100, then the various applications in each partition may be visible and accessible to the user in Unified Desktop Interface?200. Alternatively, the user may only have permission to access a subset of VMs on the host, in which case the applications visible and accessible to the user may include only those contained in the authorized VMs. As illustrated, Mail Program?210, Audio Visual Program?220?and various other applications (shown collectively as "Other Applications?230") are presented to the user in this interface without any indication of which VM these applications reside in. In fact, from the user‘s perspective, there may appear to be little to no difference between a non-virtualized environment and the virtualized environment of Host?100?(in which each application is contained in its own VM).
Unified Desktop Interface?200?illustrated in FIG. 2 is merely an example of an interface that the user may see, in which there is no indication that the host is virtualized. In an alternate embodiment, Unified Desktop Interface?200?may include a view of all the VMs as well as all the applications running in each VM. In yet another embodiment, in a layered VM environment, a unified desktop interface may exist across all VM layers. Alternatively, in a layered VM environment, a unified desktop interface may be provided with each VMM, thus enabling one unified desktop interface to be embedded in the unified desktop environment of a parent VM layer.
Various other unified desktop interfaces may be implemented without departing from the spirit of embodiments of the present invention. Most importantly, by presenting a unified view to the user, embodiments of the present invention significantly improve the usability of multiple VMs simultaneously, because the user‘s experience may resemble that of a typical desktop PC user, namely one in which the user simply selects an application (i.e., Guest Software) on Host?100?to execute, without needing to be aware of the virtual partitions on the PC and/or how to manage or exchange the Guest Software files within these partitions. Thus, for example, if the user selects Mail Program?210, as expected, the user may then be presented with the graphical output ("Mail Program Output?310") from Mail Program?210, as illustrated in FIG. 3. The user may view this output within Unified Desktop Interface?200?and the underlying interaction with the various VMs on Host?100?may remain invisible to the user, i.e., the user does not know that Mail Program?210?is actually executing in one of the VMs on Host?100.
Although invisible to the user, various elements on Host?100?enable the user to view and/or interact with all the VMs on Host?100?via Unified Desktop Interface?200. More specifically, in various embodiments of the present invention, a "unification console" (described in further detail below) enables the unified interface by transparently redirecting the input and/or output from the user and the VMs such that the user does not have to know which VM an application resides in and/or is running in. For the purposes of this specification, input and/or output shall include any form of input and/or output that Host?100?may recognize. Thus, although "input" hereafter implies that it is a keystroke, a mouse click or mouse movement provided by the user, it may in fact include any other input scheme that Host?100?is capable of receiving. Similarly, although "output" is described hereafter as primarily being visual output, embodiments of the present invention are not so limited. Output may therefore other types of output such as audio output.
In one embodiment, a dedicated VM on Host?100?may be designated to run the unification console with access to all the VMs on Host?100. FIG. 4 illustrates conceptually how the unification console ("Unification Console?400") functions to present Unified Desktop Interface?200?to the user. Although Unification Console?400?is illustrated as a separate component from the VMM ("Enhanced VMM?430"), embodiments of the invention are not so limited. Instead, in one embodiment, Enhanced VMM?430?may include all the functionality of Unification Console?400?while in an alternate embodiment, Unification Console?400?may be a component that works in conjunction with Enhanced VMM?430?(e.g., in an embodiment, Unification Console?400?may comprise an enhanced VM capable of accessing all the other VMs on Host?100). In various embodiments, input and/or output from the user and/or the VMs (e.g., VM?110?and VM?120) may be received by Enhanced VMM?430?and passed on to Unification Console?400?for processing. Further details of this processing are described below. It will be readily apparent to those of ordinary skill in the art that Unification Console?400?may be implemented in software, hardware, firmware and/or any combination thereof. Additionally, Enhanced VMM?430?may include various enhancements over existing VMMs, either to include the functionality of Unification Console?400?and/or to interact with Unification Console?400. It will be readily apparent to those of ordinary skill in the art that Enhanced VMM?430?may also be implemented in software (e.g., as a standalone program and/or a component of a host operating system), hardware, firmware and/or any combination thereof.
As illustrated in FIG. 4, in one embodiment, when a user selects an application on Host?100?(e.g., Mail Program?210) via the unified interface (e.g., Unified Desktop Interface?200?in FIG. 2), the user selection may be intercepted by Enhanced VMM?430?and passed onto Unification Console?400. Unification Console?400?may then, in conjunction with Enhanced VMM?430, determine how and where to deliver the user selection. Similarly, Unification Console?400?and/or Enhanced VMM?430?may handle the redirection of output (e.g., graphical output) from Mail Program?210?such that the user views the output on the unified interface (e.g., Unified Desktop Interface?200?in FIG. 2). Although FIG. 4 shows only VM?110, VM?120?may also be running on Host?100. Details of VM?120?have not been included herein in order to avoid obscuring how VM?110?functions according to an embodiment of the present invention. It will be readily apparent to those of ordinary skill in the art, however, that VM?120?may function similarly, alone or concurrently with VM?110. Details of how Unification Console?400?performs the routing, redirection and/or delivery of input and/or output for VM?110?is discussed in further detail below.
Unification Console?400?may intercept, route, redirect and/or deliver input/output in various ways without departing from the spirit of embodiments of the present invention. Thus, for example, in one embodiment, information about each user and/or each VM on the host may be stored as "descriptors" (shown collectively as "Descriptors?450"). A descriptor, for the purposes of this specification, shall include a registry or other such listing (e.g. database) which describes various parameters (e.g., associated metadata containing configuration and/or resource information and permission/Access Control List ("ACL") information) for the user (and other users) about the computing environment, such as user identity and permissions, applications, virtual machines, and Unification Console?400‘s configuration
Thus, for example, when a user logs in to Host?100, a default descriptor may be automatically loaded. The default descriptor may, for example, describe the default VMs for the user as well as other management policies and rules (e.g. filters and transformations) for Unification Console?400. In an alternative embodiment, the user may be prompted to select a descriptor from Descriptors?250?or build a new descriptor for use during the user‘s current session. In one embodiment, Descriptors?250?may be an enhanced startup group, with additional metadata to provide information to Unification Console?400. The concept of startup groups is well known to those of ordinary skill in the art and further description thereof is omitted herein. In one embodiment of the present invention, Descriptors?250?may be provided by an IT organization to all corporate users. Alternatively (or in addition), the user may edit Descriptors?250?at any time, to customize the descriptors for various sessions. Descriptors?250?may be used by Unification Console?400at startup of Host?100, when the user logs into Host?100?and/or during the user‘s interaction with various applications on Host?100.
Descriptors?250?thus provide Unification Console?400?with the information necessary to perform automatic content management on Host?100. Descriptors?250?may, for example, contain information about automation scripts to apply to certain incoming and/or outgoing data. Descriptors?250?may also include information about certain data types, VMs, and/or data sources that should not be filtered, modified, and/or monitored by the Unification Console?400. A set of rules, patterns and/or policies may be defined on Host?10?to dictate how Unification Console?400?may utilize Descriptors?250(e.g., the order and priority of descriptor evaluation and/or how to resolve conflicts). In one embodiment, various ones of Descriptors?250?may be controlled by users, while others of Descriptors?250?may be controlled by the system (e.g. a "root" or "super user" account). As previously described, Descriptors?250?may be governed through ACLs (permissions) and/or other metadata similar to that for file systems.
Descriptors?250?may be manipulated in various ways, e.g., copied, deleted, enabled, disabled, edited, etc. The effect and scope of a given Descriptor250?may vary as required. For example, Descriptors?250?may be applicable to individual users, to one or more groups or users or to the entire system, i.e., all VMs and/or users on Host?100. Additionally, Descriptors?250?may comprise a collection of descriptors (i.e., a collection of registries or other such listings), and upon applying the information from a first descriptor, Unification Console?400?may determine that the information from a second descriptor should also be applied. In other words, in one embodiment, upon applying a first descriptor, the conditions on Host?100?may change such that a second descriptor may also be applicable. This process may continue until multiple descriptors are applied, as appropriate. Additionally, in various embodiments, when Unification Console?400?acts based on information in Descriptors?250, it may retain/log various details from the action. For example, when saving a file, Unification Console?400?may update a log file, a database, and/or file metadata with information about the action (e.g. file source, descriptor rules, etc). This type of information may be useful to Unification Console?400?for tuning performance and/or to the user (e.g., if a user is searching for a video file from a specific user, etc.)
Thus, for example, as previously illustrated in FIG. 2, if a user logs into Host?100?and has access to VM?110, the user may see the user-clickable icon representing Mail Program?210?on Unified Desktop Interface?200. In one embodiment, when the user clicks on the icon, as illustrated in FIG. 4, Enhanced VMM?430?may intercept the selection and pass the information on to Unification Console?400. Unification Console?400, in conjunction with Enhanced VMM?430?(e.g., via a communication channel such as a shared memory setup for that purpose set up by Enhanced VMM?430, illustrated conceptually as?401?and?402?and described in further detail below), may determine that VM?110?is already instantiated and thus simply redirect the users input to VM?110. In an alternate embodiment, VM?110?may not be instantiated yet and if so, Unification Console?400?may then, in conjunction with Enhanced VMM, instruct VM?110?to start executing. If VM?110?is already running, Unification Console?400?may examine VM?110?to determine whether Mail Program?210?is already running within the VM. If Mail Program?210?is not running, Unification Console?400, in conjunction with Enhanced VMM?430, may cause Mail Program?210?to launch in VM?110. In either embodiment, the user need not be aware of where Mail Program?210?resides and/or whether the VM is executing. Instead, the user may continue to interact with all the applications on Host?100?that he or she is authorized to use via Unified Desktop Interface?200.
Although the user interacts with Mail Program?210?via the unified interface (e.g., Unified Desktop Interface?200?in FIG. 2), the actual processing for Mail Program?210?is being performed within the context of VM?110. As a result, the output from the application will be displayed within the context of VM?110, i.e., in order to view the output, the user would typically have to switch to VM?110. According to an embodiment of the present invention, however, in order for the user to seamlessly view the output of Mail Program?210?without having to know which VM the program is being processed in, Unification Console?400?may redirect and/or duplicate the output from VM?110?to Unified Desktop Interface?200. Thus, in one embodiment, the user may remain within the context of Unification Console?400?but still view the output of the applications running in other VMs. This further enhances the user‘s experience by enabling the user to remain oblivious of the virtualized environment on Host?100.
Unification Console?400?may redirect the output from VM?110?to Unified Desktop Interface?200?in various ways. For example, in one embodiment, the user may interact with the VMs on Host?100?only via Unified Desktop Interface?200. In this embodiment, the graphics adapter (included in Host Hardware?140) may be dedicated to Unification Console?400?and all output from any VM on Host?100?(which is typically handled by virtual adapters on Host?100) may be redirected to Unified Desktop Interface?200. In an alternate embodiment, if the user is likely to switch between VMs as well as view output on Unified Desktop Interface?200, the graphics adapter on Host?100?may be virtualized for each VM on Host?100, including for Unification Console?400. In this embodiment, the output from VM?110?may be duplicated for display in Unified Desktop Interface?200, thus enabling the user to view the output in either VM?110‘s context (e.g., if the user is savvy enough to switch to that context), or within Unified Desktop Interface?200.
Input to and/or output from the VMs may be transformed or filtered by Unification Console?400?(and/or Unified Desktop Interface?200). For example, output such as status or error messages from various applications or VM operations may be monitored by Unification Console?400?in order to take corrective action, but those messages may not be displayed to the user at all or, if displayed, these messages may be shown in a centralized condensed form (e.g. a log file). Additionally, in one embodiment, audio output from VMs without the current user focus may be muted or turned down. Similarly, inputs into the VMs may also be transformed or filtered by Unification Console?400. For example, audio voice data may only be permitted to certain applications and VMs, even if the system microphone is always on. In one embodiment, audio input may be muted to all applications except a child‘s voice morphing program or to a Voice Over IP (VoIP) Internet telephony VM or application. In yet another embodiment, high-resolution video inputs may have resolution downgraded to accommodate the bandwidth or processing or storage limitations afforded a given VM or application. Such restrictions may be documented in the descriptors?450. The above descriptions of transformation and filtering of various input and outputs are merely exemplary and other such filtering or transformations are possible on both without departing from the spirit of embodiments of the present invention.
Regardless of the embodiment, the user‘s input and the output from the appropriate VM may be appropriately routed, redirected, transformed or filtered by Unification Console?400. FIG. 4 includes examples (illustrated by arrows?401?and?402) of how the input and/or output from the users and VM?110may be redirected in various embodiments of the present invention. In one embodiment, since Enhanced VMM?430?is capable of interacting with Unification Console?400?and intercepts input and/or output from the user and VMs on Host?100, Enhanced VMM?430?may handle the routing, redirecting, transforming and/or filtering of the user‘s input and the VM output. This input and VM?110?output are illustrated in FIG. 4 by arrows?401?and?402. In this embodiment, all input from the user and output from VM?110?are intercepted by Enhanced VMM?430?and routed, redirected, transformed or filtered in various ways (e.g., by intercepting Graphics Display Interface ("GDI") messages from VM?110?to the graphics adapter in Host Hardware?140). In an alternate embodiment, however, the input and/or output may be routed, redirected, transformed or filtered via the network stack (that typically runs in an operating system on Host Hardware?140), via a remote desktop protocol (e.g., Microsoft‘s Remote Desktop protocol) and then routed back up the network stack to Unified Console?400. This redirection is illustrated in FIG. 4 by arrows?402. The concept of remote graphical desktops using network stacks is well known to those of ordinary skill in the art and further description thereof is omitted herein.
FIG. 5 is a flowchart illustrating an embodiment of the present invention. Although the following operations may be described as a sequential process, many of the operations may in fact be performed concurrently. In addition, the order of the operations may be re-arranged without departing from the spirit of embodiments of the invention. In?501, a VM host may startup and present a user with a unified user interface. This VM may host the unified user interface and either includes or is able to communicate with a unification console. During the startup, if a descriptor module exists (e.g., previously created by a user or by the OEM/computer vendor) in?502, then the VM host may automatically apply a default descriptor or allow the user to select a descriptor in?503. Descriptors may be hierarchically organized. The descriptor the user chooses or receives may, therefore, describe the unification console look and feel, its required defaults, as well as contain descriptions (or pointers to descriptors) for various VMs and applications. The process of applying such a descriptor is described in further detail below. If, however, a descriptor module has not yet been defined in?502, the user may have the option in?504?of creating a descriptor and the descriptor may be applied to the VM host in?503. This results in launching zero or more VMs and their applications, as described in subsequent steps, or connecting to already launched, persistent VMs (e.g. a VM one containing a PVR application). In505, the user may select an application from the unified user interface, and this user-selection may be intercepted by a VMM and passed on to a unification console on the VM host in?506. In?507, the VMM and the unification console may examine the application corresponding to the user selection. The VMM and unification console may first determine whether the VM in which the application resides in running in?508. If the VM is running, the VMM and unification console may then determine whether the application corresponding to the user-selection is running in?509. If the application is running, the VMM and Unification Console may route the user selection to the application in the VM. If, however, in?508, the VM is not running, then in511, the VMM and unification console may cause the VM to be launched. The VMM and unification console may additionally cause the application to be launched in?512, and the user selection may then be routed (connected) to the application in?510. In one embodiment, instead of launching a VM, a VM may be restored using its hibernation or sleep save image. This restored VM may include applications that are already running. Thereafter, the VMM and unification console may monitor the output from the application in?513, and in?514, redirect and/or copy and/or filter and/or transform output from the application to the unification console, to be presented using the unified desktop interface.
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PatentTips - Transparent unification of virtual machines,布布扣,bubuko.com
PatentTips - Transparent unification of virtual machines
标签:des style blog http tar ext
原文地址:http://www.cnblogs.com/coryxie/p/3795554.html
