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102 lines
5.1 KiB
HTML
102 lines
5.1 KiB
HTML
<html>
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<body>
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<h1 >libvirt architecture</h1>
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<p>Currently libvirt supports 2 kind of virtualization, and its
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internal structure is based on a driver model which simplifies adding new
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engines:</p>
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<ul>
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<li>
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<a href="#Xen">Xen hypervisor</a>
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</li>
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<li>
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<a href="#QEmu">QEmu and KVM based virtualization</a>
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</li>
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<li>
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<a href="#drivers">the driver architecture</a>
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</li>
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</ul>
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<h3>
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<a name="Xen" id="Xen">Libvirt Xen support</a>
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</h3>
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<p>When running in a Xen environment, programs using libvirt have to execute
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in "Domain 0", which is the primary Linux OS loaded on the machine. That OS
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kernel provides most if not all of the actual drivers used by the set of
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domains. It also runs the Xen Store, a database of information shared by the
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hypervisor, the kernels, the drivers and the xen daemon. Xend. The xen daemon
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supervise the control and execution of the sets of domains. The hypervisor,
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drivers, kernels and daemons communicate though a shared system bus
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implemented in the hypervisor. The figure below tries to provide a view of
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this environment:</p>
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<img src="architecture.gif" alt="The Xen architecture" />
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<p>The library can be initialized in 2 ways depending on the level of
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privilege of the embedding program. If it runs with root access,
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virConnectOpen() can be used, it will use three different ways to connect to
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the Xen infrastructure:</p>
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<ul>
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<li>a connection to the Xen Daemon though an HTTP RPC layer</li>
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<li>a read/write connection to the Xen Store</li>
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<li>use Xen Hypervisor calls</li>
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<li>when used as non-root libvirt connect to a proxy daemon running
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as root and providing read-only support</li>
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</ul>
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<p>The library will usually interact with the Xen daemon for any operation
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changing the state of the system, but for performance and accuracy reasons
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may talk directly to the hypervisor when gathering state information at
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least when possible (i.e. when the running program using libvirt has root
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privilege access).</p>
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<p>If it runs without root access virConnectOpenReadOnly() should be used to
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connect to initialize the library. It will then fork a libvirt_proxy
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program running as root and providing read_only access to the API, this is
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then only useful for reporting and monitoring.</p>
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<h3>
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<a name="QEmu" id="QEmu">Libvirt QEmu and KVM support</a>
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</h3>
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<p>The model for QEmu and KVM is completely similar, basically KVM is based
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on QEmu for the process controlling a new domain, only small details differs
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between the two. In both case the libvirt API is provided by a controlling
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process forked by libvirt in the background and which launch and control the
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QEmu or KVM process. That program called libvirt_qemud talks though a specific
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protocol to the library, and connects to the console of the QEmu process in
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order to control and report on its status. Libvirt tries to expose all the
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emulations models of QEmu, the selection is done when creating the new
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domain, by specifying the architecture and machine type targeted.</p>
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<p>The code controlling the QEmu process is available in the
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<code>qemud/</code> directory.</p>
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<h3>
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<a name="drivers" id="drivers">the driver based architecture</a>
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</h3>
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<p>As the previous section explains, libvirt can communicate using different
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channels with the current hypervisor, and should also be able to use
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different kind of hypervisor. To simplify the internal design, code, ease
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maintenance and simplify the support of other virtualization engine the
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internals have been structured as one core component, the libvirt.c module
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acting as a front-end for the library API and a set of hypervisor drivers
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defining a common set of routines. That way the Xen Daemon access, the Xen
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Store one, the Hypervisor hypercall are all isolated in separate C modules
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implementing at least a subset of the common operations defined by the
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drivers present in driver.h:</p>
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<ul>
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<li>xend_internal: implements the driver functions though the Xen
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Daemon</li>
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<li>xs_internal: implements the subset of the driver available though the
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Xen Store</li>
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<li>xen_internal: provide the implementation of the functions possible via
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direct hypervisor access</li>
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<li>proxy_internal: provide read-only Xen access via a proxy, the proxy code
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is in the <code>proxy/</code>directory.</li>
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<li>xm_internal: provide support for Xen defined but not running
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domains.</li>
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<li>qemu_internal: implement the driver functions for QEmu and
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KVM virtualization engines. It also uses a qemud/ specific daemon
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which interacts with the QEmu process to implement libvirt API.</li>
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<li>test: this is a test driver useful for regression tests of the
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front-end part of libvirt.</li>
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</ul>
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<p>Note that a given driver may only implement a subset of those functions,
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(for example saving a Xen domain state to disk and restoring it is only
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possible though the Xen Daemon), in that case the driver entry points for
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unsupported functions are initialized to NULL.</p>
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<p></p>
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</body>
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</html>
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