Virtio: An I/O virtualization framework for Linux | 原文
2021/4/25 7:27:18
本文主要是介绍Virtio: An I/O virtualization framework for Linux | 原文,对大家解决编程问题具有一定的参考价值,需要的程序猿们随着小编来一起学习吧!
《Virtio: An I/O virtualization framework for Linux》
《KVM Virtio: An I/O virtualization framework for Linux(Linux虚拟IO框架)》
《Virtio: An I/O virtualization framework for Linux | 原文》
目录
Full virtualization vs. paravirtualization
An abstraction for Linux guests
Virtio architecture
Concept hierarchy
Virtio buffers
Core API
Example virtio drivers
Going further
Paravirtualized I/O with KVM and lguest
By M. Jones
Published January 29, 2010
In a nutshell, virtio
is an abstraction layer over devices in a paravirtualized hypervisor. virtio
was developed by Rusty Russell in support of his own virtualization solution called lguest
. This article begins with an introduction to paravirtualization and emulated devices, and then explores the details of virtio
. The focus is on the virtio
framework from the 2.6.30 kernel release.
Linux is the hypervisor playground. As my article on Linux as a hypervisor showed, Linux offers a variety of hypervisor solutions with different attributes and advantages. Examples include the Kernel-based Virtual Machine (KVM), lguest
, and User-mode Linux. Having these different hypervisor solutions on Linux can tax the operating system based on their independent needs. One of the taxes is virtualization of devices. Rather than have a variety of device emulation mechanisms (for network, block, and other drivers), virtio
provides a common front end for these device emulations to standardize the interface and increase the reuse of code across the platforms.
Full virtualization vs. paravirtualization
Let’s start with a quick discussion of two distinct types of virtualization schemes: full virtualization and paravirtualization. In full virtualization, the guest operating system runs on top of a hypervisor that sits on the bare metal. The guest is unaware that it is being virtualized and requires no changes to work in this configuration. Conversely, in paravirtualization, the guest operating system is not only aware that it is running on a hypervisor but includes code to make guest-to-hypervisor transitions more efficient (see Figure 1).
In the full virtualization scheme, the hypervisor must emulate device hardware, which is emulating at the lowest level of the conversation (for example, to a network driver). Although the emulation is clean at this abstraction, it’s also the most inefficient and highly complicated. In the paravirtualization scheme, the guest and the hypervisor can work cooperatively to make this emulation efficient. The downside to the paravirtualization approach is that the operating system is aware that it’s being virtualized and requires modifications to work.
Hardware continues to change with virtualization. New processors incorporate advanced instructions to make guest operating systems and hypervisor transitions more efficient. And hardware continues to change for input/output (I/O) virtualization, as well (see resources on the right to learn about Peripheral Controller Interconnect [PCI] passthrough and single- and multi-root I/O virtualization).
But in traditional full virtualization environments, the hypervisor must trap these requests, and then emulate the behaviors of real hardware. Although doing so provides the greatest flexibility (namely, running an unmodified operating system), it does introduce inefficiency (see the left side of Figure 1). The right side of Figure 1 shows the paravirtualization case. Here, the guest operating system is aware that it’s running on a hypervisor and includes drivers that act as the front end. The hypervisor implements the back-end drivers for the particular device emulation. These front-end and back-end drivers are where virtio
comes in, providing a standardized interface for the development of emulated device access to propagate code reuse and increase efficiency.
Virtio alternatives
virtio
is not entirely alone in this space. Xen provides paravirtualized device drivers, and VMware provides what are called Guest Tools.
An abstraction for Linux guests
From the previous section, you can see that virtio
is an abstraction for a set of common emulated devices in a paravirtualized hypervisor. This design allows the hypervisor to export a common set of emulated devices and make them available through a common application programming interface (API). Figure 2 illustrates why this is important. With paravirtualized hypervisors, the guests implement a common set of interfaces, with the particular device emulation behind a set of back-end drivers. The back-end drivers need not be common as long as they implement the required behaviors of the front end.
Note that in reality (though not required), the device emulation occurs in user space using QEMU, so the back-end drivers communicate into the user space of the hypervisor to facilitate I/O through QEMU. QEMU is a system emulator that, in addition to providing a guest operating system virtualization platform, provides emulation of an entire system (PCI host controller, disk, network, video hardware, USB controller, and other hardware elements).
The virtio
API relies on a simple buffer abstraction to encapsulate the command and data needs of the guest. Let’s look at the internals of the virtio
API and its components.
Virtio architecture
In addition to the front-end drivers (implemented in the guest operating system) and the back-end drivers (implemented in the hypervisor), virtio
defines two layers to support guest-to-hypervisor communication. At the top level (called virtio) is the virtual queue interface that conceptually attaches front-end drivers to back-end drivers. Drivers can use zero or more queues, depending on their need. For example, the virtio
network driver uses two virtual queues (one for receive and one for transmit), where the virtio
block driver uses only one. Virtual queues, being virtual, are actually implemented as rings to traverse the guest-to-hypervisor transition. But this could be implemented any way, as long as both the guest and hypervisor implement it in the same way.
As shown in Figure 3, five front-end drivers are listed for block devices (such as disks), network devices, PCI emulation, a balloon driver (for dynamically managing guest memory usage), and a console driver. Each front-end driver has a corresponding back-end driver in the hypervisor.
Concept hierarchy
From the perspective of the guest, an object hierarchy is defined as shown in Figure 4. At the top is the virtio_driver
, which represents the front-end driver in the guest. Devices that match this driver are encapsulated by the virtio_device
(a representation of the device in the guest). This refers to the virtio_config_ops
structure (which defines the operations for configuring the virtio
device). The virtio_device
is referred to by the virtqueue
(which includes a reference to the virtio_device
to which it serves). Finally, each virtqueue
object references the virtqueue_ops
object, which defines the underlying queue operations for dealing with the hypervisor driver. Although the queue operations are the core of the virtio
API, I provide a brief discussion of discovery, and then explore the virtqueue_ops
operations in more detail.
The process begins with the creation of a virtio_driver
and subsequent registration via register_virtio_driver
. The virtio_driver
structure defines the upper-level device driver, list of device IDs that the driver supports, a features table (dependent upon the device type), and a list of callback functions. When the hypervisor identifies the presence of a new device that matches a device ID in the device list, the probe
function is called (provided in the virtio_driver
object) to pass up the virtio_device
object. This object is cached with the management data for the device (in a driver-dependent way). Depending on the driver type, the virtio_config_ops
functions may be invoked to get or set options specific to the device (for example, getting the Read/Write status of the disk for a virtio_blk
device or setting the block size of the block device).
Note that the virtio_device
includes no reference to the virtqueue
(but the virtqueue
does reference the virtio_device
). To identify the virtqueue
s that associate with this virtio_device
, you use the virtio_config_ops
object with the find_vq
function. This object returns the virtual queues associated with this virtio_device
instance. The find_vq
function also permits the specification of a callback function for the virtqueue
(see the virtqueue
structure in Figure 4), which is used to notify the guest of response buffers from the hypervisor.
The virtqueue
is a simple structure that identifies an optional callback function (which is called when the hypervisor consumes the buffers), a reference to the virtio_device
, a reference to the virtqueue
operations, and a special priv
reference that refers to the underlying implementation to use. Although the callback
is optional, it’s possible to enable or disable callbacks dynamically.
But the core of this hierarchy is the virtqueue_ops
, which defines how commands and data are moved between the guest and the hypervisor. Let’s first explore the object that is added or removed from the virtqueue
.
Virtio buffers
Guest (front-end) drivers communicate with hypervisor (back-end) drivers through buffers. For an I/O, the guest provides one or more buffers representing the request. For example, you could provide three buffers, with the first representing a Read request and the subsequent two buffers representing the response data. Internally, this configuration is represented as a scatter-gather list (with each entry in the list representing an address and a length).
Core API
Linking the guest driver and hypervisor driver occurs through the virtio_device
and most commonly through virtqueue
s. The virtqueue
supports its own API consisting of five functions. You use the first function, add_buf
, to provide a request to the hypervisor. This request is in the form of the scatter-gather list discussed previously. To add_buf
, the guest provides the virtqueue
to which the request is to be enqueued, the scatter-gather list (an array of addresses and lengths), the number of buffers that serve as out entries (destined for the underlying hypervisor), and the number of in entries (for which the hypervisor will store data and return to the guest). When a request has been made to the hypervisor through add_buf
, the guest can notify the hypervisor of the new request using the kick
function. For best performance, the guest should load as many buffers as possible onto the virtqueue
before notifying through kick
.
Responses from the hypervisor occur through the get_buf
function. The guest can poll simply by calling this function or wait for notification through the provided virtqueue callback
function. When the guest learns that buffers are available, the call to get_buf
returns the completed buffers.
The final two functions in the virtqueue
API are enable_cb
and disable_cb
. You can use these functions to enable and disable the callback process (via the callback
function initialized in the virtqueue
through the find_vq
function). Note that the callback function and the hypervisor are in separate address spaces, so the call occurs through an indirect hypervisor call (such as kvm_hypercall
).
The format, order, and contents of the buffers are meaningful only to the front-end and back-end drivers. The internal transport (rings in the current implementation) move only buffers and have no knowledge of their internal representation.
Example virtio drivers
You can find the source to the various front-end drivers within the ./drivers subdirectory of the Linux kernel. The virtio
network driver can be found in ./drivers/net/virtio_net.c, and the virtio
block driver can be found in ./drivers/block/virtio_blk.c. The subdirectory ./drivers/virtio provides the implementation of the virtio
interfaces (virtio
device, driver, virtqueue
, and ring). virtio
has also been used in High-Performance Computing (HPC) research to develop inter-virtual machine (VM) communications through shared memory passing. Specifically, this was implemented through a virtualized PCI interface using the virtio
PCI driver. You can learn more about this work in the resources section on the right.
You can exercise this paravirtualization infrastructure today in the Linux kernel. All you need is a kernel to act as the hypervisor, a guest kernel, and QEMU for device emulation. You can use either KVM (a module that exists in the host kernel) or with Rusty Russell’s lguest
(a modified Linux guest kernel). Both of these virtualization solutions support virtio
(along with QEMU for system emulation and libvirt
for virtualization management).
The result of Rusty’s work is a simpler code base for paravirtualized drivers and faster emulation of virtual devices. But even more important, virtio
has been found to provide better performance (2-3 times for network I/O) than current commercial solutions. This performance boost comes at a cost, but it’s well worth it if Linux is your hypervisor and guest.
Going further
Although you may never develop front-end or back-end drivers for virtio
, it implements an interesting architecture and is worth understanding in more detail. virtio
opens up new opportunities for efficiency in paravirtualized I/O environments while building from previous work in Xen. Linux continues to prove itself as a production hypervisor and a research platform for new virtualization technologies. virtio
is yet another example of the strengths and openness of Linux as a hypervisor.
这篇关于Virtio: An I/O virtualization framework for Linux | 原文的文章就介绍到这儿,希望我们推荐的文章对大家有所帮助,也希望大家多多支持为之网!
- 2024-12-18git仓库有更新,jenkins 自动触发拉代码怎么配置的?-icode9专业技术文章分享
- 2024-12-18Jenkins webhook 方式怎么配置指定的分支?-icode9专业技术文章分享
- 2024-12-13Linux C++项目实战入门教程
- 2024-12-13Linux C++编程项目实战入门教程
- 2024-12-11Linux部署Scrapy教程:新手入门指南
- 2024-12-11怎么将在本地创建的 Maven 仓库迁移到 Linux 服务器上?-icode9专业技术文章分享
- 2024-12-10Linux常用命令
- 2024-12-06谁看谁服! Linux 创始人对于进程和线程的理解是…
- 2024-12-04操作系统教程:新手入门及初级技巧详解
- 2024-12-04操作系统入门:新手必学指南